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Bibliography on: Symbiosis

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ESP: PubMed Auto Bibliography 14 Sep 2025 at 02:00 Created: 

Symbiosis

Symbiosis refers to an interaction between two or more different organisms living in close physical association, typically to the advantage of both. Symbiotic relationships were once thought to be exceptional situations. Recent studies, however, have shown that every multicellular eukaryote exists in a tight symbiotic relationship with billions of microbes. The associated microbial ecosystems are referred to as microbiome and the combination of a multicellular organism and its microbiota has been described as a holobiont. It seems "we are all lichens now."

Created with PubMed® Query: ( symbiosis[tiab] OR symbiotic[tiab] ) NOT pmcbook NOT ispreviousversion

Citations The Papers (from PubMed®)

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RevDate: 2025-09-13

Bosco C, Raspati GS, Maurin N, et al (2025)

A systematic literature review on resource recovery toward symbiotic circular economy solutions in the water sector.

Journal of environmental management, 393:127298 pii:S0301-4797(25)03274-8 [Epub ahead of print].

Population growth, climate change, and unsustainable water use have prompted the exploration of alternative solutions for sustainable water management. While significant advancements have been made in resource recovery technologies from wastewater, the large-scale implementation of these systems and associated impact on the environment and society are still far from full realization. This paper reviews the scientific state-of-the art on resource recovery in the water sector with respect to the four pillars of symbiotic circular economy solutions, consisting of technological processes, final applications, business models, and stakeholder involvement. A systematic and transparent literature review has been carried out, showing that a variety of technologies for recovering water, materials, energy, and nutrients have been proposed and tested, but widespread application is constrained by multiple barriers. These include the technical limitations of existing recovery processes, financial obstacles, and the difficulties associated with integrating technologies into existing value chains. This work emphasizes the need for additional research on novel approaches to promote alternative business models and bottom-up involvement of stakeholders, from public and private organisations to local communities, in the planning and implementation of resource recovery systems in the water sector.

RevDate: 2025-09-13

Caley A, Marzinelli EM, M Mayer-Pinto (2025)

Limited microbial community responses of marine macroalgae to artificial light at night and moderate warming conditions.

Marine environmental research, 212:107536 pii:S0141-1136(25)00593-8 [Epub ahead of print].

Multiple stressors such as Artificial Light at Night (ALAN) and warming are increasingly common in marine systems and can interact in complex ways. Microbial communities play critical roles in the functioning of coastal habitat-forming species such as seaweeds, however the effects of ALAN on seaweed-associated microbial communities remain unknown. We tested the independent and combined effects of ALAN and warming on microbial communities associated with the habitat-forming seaweeds Ecklonia radiata and Sargassum sp. In Ecklonia, ALAN increased the relative abundance of two potentially light-responsive taxa: Dokdonia sp000212355 and an unidentified ASV from Pseudomonadales, whereas warming had the opposite effect. Warming increased microbial community dispersion in Ecklonia and resulted in non-significant increases in relative abundance of putative pathogenic and agarolytic taxa (microbes capable of degrading algal polysaccharides). However, further analyses using metagenomics are needed to confirm functional roles. In contrast, neither ALAN nor warming affected dominant taxa associated with Sargassum. Contrary to expectations, cyanobacteria relative abundance was unaffected by ALAN in either seaweed host, despite their photosynthetic capacity. We found limited evidence for interactive effects of ALAN and warming, and community composition remained unchanged in both seaweed species. Our findings highlight the importance of considering species-specific microbial responses to ALAN and warming, with implications for coastal management.

RevDate: 2025-09-13

Rondilla RR, R Edrada-Ebel (2025)

Recent biotechnological advances in bioprospecting secondary metabolites from endolichenic fungi for drug discovery applications.

Critical reviews in microbiology [Epub ahead of print].

Endolichenic fungi (ELF) are symbiotic organisms residing in lichens. Since the initial report of its application in natural products and drug discovery, they have emerged as unique valuable sources of compounds with a wide range of structural diversity and biological activities. In this review, we critically examine current strategies to expand ELF metabolite diversity, with emphasis on the One Strain, Many Compounds (OSMAC) approach and metabolomics-guided profiling. We highlight how co-culture systems, epigenetic modifiers, and advanced data acquisition platforms can open new avenues for chemical space exploration. Genomic and transcriptomic studies, though still limited in ELF, reveal untapped biosynthetic potential and point toward integrative omics pipelines. Recent computational and artificial intelligence tools further accelerate genome-metabolome mining, structural elucidation, and prediction of bioactivity. We propose a forward-looking framework that combines OSMAC, integrative omics, and AI to maximize the natural product bioprospecting potential of ELF, while also uncovering their ecological roles within the lichen holobiome.

RevDate: 2025-09-13

Álvarez-Herms J, Burtscher M, Corbi F, et al (2025)

A Narrative Hypothesis: The Important Role of Gut Microbiota in the Modulation of Effort Tolerance in Endurance Athletes.

Nutrients, 17(17): pii:nu17172836.

Background: Regulating sensations of fatigue and discomfort while performing maximal endurance exercise becomes essential for making informed decisions about persistence and/or failure during intense exercise. Athletes with a higher effort capacity have competitive advantages over those with a lower one. The microbiota-brain axis is a considered the sixth sense and a modulator of the host's emotional stability and physical well-being. Objectives: This narrative review aims to explore and evaluate the potential mechanisms involved in regulating perceptions during endurance exercise, with a focus on the possible relationship between the gut microbiota balance and the neural system as an adaptive response to high fatigue chronic exposure. Methods: Electronic databases (PubMed, Web of Science, Google Scholar, and Scopus) were used to identify studies and hypotheses that had documented predefined search terms related to endurance exercise, gut microbiota, the central nervous system, pain, discomfort, fatigue, and tolerance to effort. Results: This narrative review shifts the focus concerning the symbiotic relationship between the gut microbiota, the vagus nerve, the central/enteric nervous system, and the regulation of afferences from different organs and systems to manage discomfort and fatigue perceptions during maximal physical effort. Consequently, the chronicity supporting fatigued exercise and nutritional stimuli could specifically adapt the microbiota-brain connection through chronic efferences and afferences. The present hypothesis could represent a new focus to be considered, analysing individual differences in tolerating fatigue and discomfort in athletes supporting conditions of intense endurance exercise. Conclusions: A growing body of evidence suggests that the gut microbiota has rapid adaptations to afferences from the brain axis, with a possible relationship to the management of fatigue, pain, and discomfort. Therefore, the host-microbiota relationship could determine predisposition to endurance performance by increasing thresholds of sensitive afferences perceived and tolerated. A richer and more diverse GM of athletes in comparison with sedentary subjects can improve the bacteria-producing metabolites connected to brain activity related with fatigue. The increase in fatigue thresholds directly improves exercise performance, and the gut-brain axis may contribute through the equilibrium of metabolites produced for the microbiota.

RevDate: 2025-09-13

Vladimirova ME, Roumiantseva ML, Saksaganskaia AS, et al (2025)

Dark Matter Carried by Sinorhizobium meliloti phiLM21-like Prophages.

International journal of molecular sciences, 26(17): pii:ijms26178704.

A comprehensive comparative analysis was conducted on the nucleotide and amino acid sequences of intact phiLM21-like prophages (phiLM21-LPhs), which currently represent the most prevalent prophages in Sinorhizobium meliloti-a symbiotic partner of Fabaceae plants. Remarkably, the nucleotide sequences of 25 phiLM21-LPhs, identified across 36 geographically dispersed S. meliloti strains, covered no more than 34% of the phiLM21 phage genome. All prophages were integrated into specific isoacceptor tRNA genes and carried a tyrosine-type integrase gene; however, this integration did not exhibit features of tRNA-dependent lysogeny. Only one-fifth of phiLM21-LPhs encoded the minimal set of regulators for lysogenic/lytic cycle transitions, while the remainder contained either uncharacterized regulatory elements or appeared to be undergoing genomic "anchoring" within the host bacterium. The phiLM21-LPhs harbored open reading frames (ORFs) of diverse origins (phage-derived, bacterial, and unknown), yet over half of these ORFs had undeterminable functions, representing genetic "dark matter". The observed diversification of intact phiLM21-like prophages likely stems from recombination events involving both virulent/temperate phages and phylogenetically remote bacterial taxa. The evolutionary and biological significance of the substantial genetic "dark matter" within these prophages in soil saprophytic bacteria remains an unresolved question.

RevDate: 2025-09-13

Hao S, Hua Z, Y Yuan (2025)

Stage-Specific Lipidomes of Gastrodia elata Extracellular Vesicles Modulate Fungal Symbiosis.

International journal of molecular sciences, 26(17): pii:ijms26178611.

The mycoheterotrophic orchid Gastrodia elata relies entirely on symbiosis with Armillaria for nutrient acquisition during tuber development. The signaling mechanisms underlying this interaction have long been a research focus, and several pathways, such as phytohormone-mediated signaling, have been reported. However, the role of plant-derived extracellular vesicles (PDEVs) in G. elata-Armillaria communication remains unexplored. In this study, we conducted a comprehensive lipidomic analysis of G. elata-derived extracellular vesicles (GDEVs) isolated from juvenile, immature (active symbiosis), and mature tubers. By employing high-resolution mass spectrometry and advanced statistical methods, we established a detailed EV lipidome profile for G. elata, identifying 996 lipid species spanning eight major classes. Distinct lipidomic remodeling was observed throughout tuber maturation. Notably, as the immature stage corresponds to the period of peak symbiotic activity, targeted lipidome comparisons enabled the identification of core lipid markers, particularly Glc-sitosterols and the polyketide 7,8-dehydroastaxanthin, which are highly enriched during active symbiosis and potentially associated with inter-kingdom communication. These findings suggest that developmentally regulated lipid transport via EVs plays a critical role in mediating G. elata-Armillaria interaction. Our work not only illuminates the contribution of vesicle lipids to plant-fungal interaction but also provides a methodological foundation for investigating EV-mediated signaling in non-model plant-microbe systems.

RevDate: 2025-09-13

Cántaro-Segura H, D Zúñiga-Dávila (2025)

Exogenous Application of ENOD40 and CEP1 Peptides Boosts Symbiotic Signaling Gene Expression and Productivity in Common Bean.

Plants (Basel, Switzerland), 14(17): pii:plants14172786.

Small signaling peptides play crucial roles in the regulation of legume-rhizobia symbiosis, yet their potential as exogenous biostimulants remains largely unexplored. In this study, we evaluated the effects of foliar application of the synthetic peptides ENOD40 and CEP1 on common bean (Phaseolus vulgaris) under both greenhouse and field conditions. Using a factorial design, we examined gene expression patterns, nodulation parameters, and yield-related traits in response to peptide treatments alone or in combination with Rhizobium. Results showed that ENOD40 and CEP1 significantly enhanced the transcription of key symbiotic signaling genes (PvENOD40, PvSYMRK, PvCCaMK, PvCYCLOPS, PvVAPYRIN) and modulated defense-related genes (PvAOS, PvICS), with the strongest effects observed at concentrations of 10[-7] M and 10[-8] M. In greenhouse assays, peptide-treated plants exhibited increased root and shoot biomass, nodule number, and seed yield. Field trials confirmed these responses, with CEP1 10[-7] M + Rhizobium treatment achieving the highest grain yield (3322 kg ha[-1]). Our findings provide the first evidence that ENOD40 and CEP1 peptides can function as foliar-applied biostimulants to enhance nodulation efficiency and improve yield in legumes. This approach offers a promising and sustainable strategy to reduce chemical nitrogen inputs and support biological nitrogen fixation in agricultural systems.

RevDate: 2025-09-13

Rahbari A, Esmaielpour B, Azarmi R, et al (2025)

Symbiotic Fungus Serendipita indica as a Natural Bioenhancer Against Cadmium Toxicity in Chinese Cabbage.

Plants (Basel, Switzerland), 14(17): pii:plants14172773.

Heavy metal toxicity, particularly cadmium (Cd), poses a growing threat to agriculture and human health due to its persistence and high solubility, which facilitates its entry into the food chain. Among the strategies proposed to reduce Cd toxicity in plants and the environment, the use of beneficial microorganisms, such as endophytic fungi, has gained attention due to its effectiveness and eco-friendliness. This study investigates the potential of the root-colonizing fungus Serendipita indica (formerly Piriformospora indica) to mitigate cadmium (Cd) stress in Chinese cabbage (Brassica rapa L. subsp. Pekinensis) grown hydroponically under varying Cd concentrations (0, 1, 3, and 4 mM). Several parameters were assessed, including morphological traits, physiological and biochemical responses, and changes in leaf composition. Exposure to Cd significantly reduced plant growth, increased membrane electrolyte leakage, and decreased relative water content and root colonization, while enhancing antioxidant enzyme activities and the accumulation of phenolics, flavonoids, proline, glycine betaine, and carbohydrates. Notably, plants treated with S. indica showed improved tolerance to Cd stress, indicating the potential of the fungus. These findings suggest that S. indica can enhance plant resilience in Cd-contaminated environments and may offer a promising biological strategy for sustainable crop production under heavy metal stress.

RevDate: 2025-09-13

Li J, Wang Y, Xu Z, et al (2025)

Effects of Roxithromycin Exposure on the Nitrogen Metabolism and Environmental Bacterial Recruitment of Chlorella pyrenoidosa.

Plants (Basel, Switzerland), 14(17): pii:plants14172774.

The ecotoxicity induced by macrolides has attracted widespread attention, but their impacts on the nitrogen metabolism and symbiotic environmental bacteria of microalgae remain unclear. This study examined the effects of roxithromycin (ROX) on the growth, chlorophyll levels, and nitrogen metabolism of Chlorella pyrenoidosa; investigated the changes in the composition and functions of environmental bacterial communities; and finally, analyzed the relationship between microalgae and environmental bacteria. The results indicated that all concentrations of ROX (0.1, 0.25, and 1 mg/L) inhibited microalgae growth, but the inhibition rates gradually decreased after a certain exposure period. For instance, the inhibition rate in the 1 mg/L treatment group reached the highest value of 43.43% at 7 d, which then decreased to 18.93% at 21 d. Although the total chlorophyll content was slightly inhibited by 1 mg/L ROX, the Chl-a/Chl-b value increased between 3 and 21 d. The nitrate reductase activities in the three treatments were inhibited at 3 d, but gradually returned to normal levels and even exceeded that of the control group at 21 d. Under ROX treatment, the consumption of NO3[-] by microalgae corresponded to the nitrate reductase activity, with slower consumption in the early stage and no obvious difference from the control group in the later stage. Overall, the diversity of environmental bacteria did not undergo significant changes, but the abundance of some specific bacteria increased, such as nitrogen-fixing bacteria (unclassified-f-Rhizobiaceae and Mesorhizobium) and organic contaminant-degrading bacteria (Limnobacter, Sphingopyxis, and Aquimonas). The 0.25 and 1 mg/L ROX treatments significantly enhanced the carbohydrate metabolism, cofactor and vitamin metabolism, amino acid metabolism, and energy metabolism of the environmental bacteria, but significantly downregulated nitrogen denitrification. This study provides new insights into the environmental bacteria-driven recovery mechanism of microalgae under antibiotic stress.

RevDate: 2025-09-13

Vásquez HV, Valqui L, Valqui-Valqui L, et al (2025)

Influence of Nitrogen Fertilization and Cutting Dynamics on the Yield and Nutritional Composition of White Clover (Trifolium repens L.).

Plants (Basel, Switzerland), 14(17): pii:plants14172765.

White clover (Trifolium repens L.) is known for its ability to fix nitrogen biologically, its high nutritional value, and its adaptability to livestock systems. However, excessive fertilization with synthetic nitrogen alters its symbiosis with Rhizobium and reduces the protein content of the forage. The objective of this study was to evaluate the interaction between nitrogen fertilization (0 and 60 kg N ha[-1]), cutting time, and post-cutting evaluation on the morphology, yield, and nutritional composition of white clover. A completely randomized block experimental design with three factors, distributed in three blocks, was used. Within each block, three replicates of each treatment were assigned (six interactions), giving a total of 54 experimental units. The data were analyzed using a three-way analysis of variance and Tukey's multiple comparison test. Exponential models and generalized additive models (GAMs) were applied to the morphology and yield data to identify the best fit. The treatment with 60 kg N ha[-1] and cutting at 30 days showed significant increases in plant height (47.42%), fresh weight (59.61%), dry weight (98.41%), and leaf width (27.55%) compared to the control. It also produced the highest protein content (28.44%) compared to the other treatments with fertilization, without negatively affecting digestibility. The GAMs best fit most morphological and yield parameters (except leaf height and width). All fertilized treatments had higher fresh and dry weight yields. In conclusion, applying 60 kg N ha[-1] after cutting at 30 days, followed by harvesting between 54 and 60 days, improved both the quality and yield of white clover, which favored sustainable pasture management and reduced excessive nitrogen use.

RevDate: 2025-09-13

Yurkov AP, Puzanskiy RK, Kryukov AA, et al (2025)

The Effect of Arbuscular Mycorrhizal Fungus and Phosphorus Treatment on Root Metabolome of Medicago lupulina During Key Stages of Development.

Plants (Basel, Switzerland), 14(17): pii:plants14172685.

The arbuscular mycorrhizal fungi (AMF) effect on the plant metabolome is an actual question of plant biology. Its alteration during host plant development and at different phosphorus supplies is of special interest. The aim of this study was to evaluate the effect of Rhizophagus irregularis (Błaszk., Wubet, Renker & Buscot) C. Walker & A. Schüßler inoculation and/or phosphorus treatment on the root metabolome of Medicago lupulina L. subsp. vulgaris Koch at the first true leaf, second leaf, third leaf development stages, the lateral branching initiation, the flowering and the mature fruit stages. The assessment of metabolic profiles was performed using GC-MS. In total, 327 metabolites were annotated: among them 20 carboxylic acids, 26 amino acids, 14 fatty acids and 58 sugars. The efficient AM was characterized by the upregulation of the metabolism of proteins, carbohydrates and lipids, as well as an increase in the content of phosphates. The tricarboxylic acid abundance was generally lower during mycorrhization. Fourteen metabolic markers of the efficient AM symbiosis were identified. The lateral branching initiation stage was shown to have key importance. Long-lasting metabolomic profiling indicated variances in mycorrhization and Pi supply effects at different key stages of host plant development.

RevDate: 2025-09-13

Bravo TEP, Teixeira IR, Teixeira GCDS, et al (2025)

Optimizing Common Bean Symbiosis via Stage-Specific Reinoculation and Co-Inoculation.

Plants (Basel, Switzerland), 14(17): pii:plants14172676.

The common bean relies on biological nitrogen fixation to meet part of its nitrogen requirements. This study aimed to evaluate the effect of reinoculation with Rhizobium tropici, alone or combined with Azospirillum brasilense, at different phenological stages. The experiments were conducted in the winter of 2023 and the rainy season of 2023/24, and significant differences were observed between seasons, mainly due to temperature and water stress, which impacted nodulation, plant growth and grain yield. However, appropriate water management mitigated these limitations, allowing reinoculation combined with co-inoculation at the V4 stage to improve nodular and morphophysiological traits, ensuring adequate nutrition through biological nitrogen fixation. This strategy promoted nodulation and plant development, resulting in an 8.5% increase in yield compared to nitrogen fertilization (80 kg ha[-1]), reaching 2197.87 kg ha[-1]. These results suggest that reinoculation with co-inoculation at the V4 stage can enhance biological nitrogen fixation, reduce dependence on synthetic fertilizers and serve as a sustainable and economically viable alternative.

RevDate: 2025-09-13

Bursakov SA, Karlov GI, Kroupin PY, et al (2025)

Microorganisms as Potential Accelerators of Speed Breeding: Mechanisms and Knowledge Gaps.

Plants (Basel, Switzerland), 14(17): pii:plants14172628.

The rapid and widespread development of technology is in line with global trends of population growth and increasing demand for food. Significant breakthroughs in science have not yet fully met the needs of agriculture for increased food production and higher yields. The aim of this work is to discuss the current advancements in the application of beneficial microorganisms for crop cultivation and their integration into speed breeding technology to create optimal growing conditions and achieve the ultimate goal of developing new plant varieties. New breeding techniques, such as speed breeding-now a critical component of the breeding process-allow multiple plant generations to be produced in a much shorter time, facilitating the development of new plant varieties. By reducing the time required to obtain new generations, breeders and geneticists can optimize their efforts to obtain the required crop genotypes for both agriculture and industry. This helps to meet the demand for food, animal feed and plant raw materials for industrial use. One potential aspect of speed breeding technology is the incorporation of effective beneficial microorganisms that inhabit both the above-ground and below-ground parts of plants. These microorganisms have the potential to enhance the speed breeding method. Microorganisms can stimulate growth and development, promote overall fitness and rapid maturation, prevent disease, and impart stress resistance in speed breeding plants. Utilizing the positive effects of beneficial microorganisms offers a pathway to enhance speed breeding technology, an approach not yet explored in the literature. The controlled practical use of microorganisms under speed breeding conditions should contribute to producing programmable results. The use of beneficial microorganisms in speed breeding technology is considered an indispensable part of future precision agriculture. Drawing attention to their practical and effective utilization is an urgent task in modern research.

RevDate: 2025-09-12

Arai H, Harumoto T, Katsuma S, et al (2025)

Striking diversity of male-killing symbionts and their mechanisms.

Trends in genetics : TIG pii:S0168-9525(25)00200-8 [Epub ahead of print].

Symbiosis is a fundamental characteristic of eukaryotic biology. Arthropods, including insects, often harbor maternally inherited endosymbiotic microbes, some of which have evolved the ability to selectively kill male hosts - a phenomenon known as 'male killing.' The evolutionary history and mechanisms of symbiont-induced male killing have remained poorly understood. However, recent studies have revealed a remarkable diversity of male-killing strategies and their associated causative genes in diverse bacteria and viruses that target different aspects of the host reproductive system. Some insects have evolved various suppressor genes to counteract male-killing actions. This review synthesizes the current knowledge on the evolution and mechanisms underlying microbe-induced male killing and explores their broader implications for the ecology and evolution of eukaryotic life forms.

RevDate: 2025-09-12

Ren Z, Sun P, Li H, et al (2025)

Novel photocatalytic bacteria-algae coupling system mediated by g-C3N4 nanoparticles: Effects of microbial ratio on performance and microbiome.

Bioresource technology pii:S0960-8524(25)01268-4 [Epub ahead of print].

This study explored symbiotic interactions within a graphitic carbon nitride (g-C3N4)-enhanced bacterial-algal system for advanced wastewater treatment by examining the effects of varying bacterial-algal ratios (10:1, 5:1, and 1:1) on nutrient removal, microbial aggregation, and community dynamics in sequencing batch reactors. The 1:1 ratio (R3) exhibited optimal performance, achieving highest chemical oxygen demand removal (98.7 %) and ammonium nitrogen removal (92.4 %), alongside increased algal biomass. R3 enhanced microbial aggregation via elevated extracellular polymeric substances (EPS, 80.2 mg/g SS), reduced electrostatic repulsion. Microbial profiling revealed higher abundances of Proteobacteria (37.6 %) and Cyanobacteria (9.1 %), synergistically enabling nitrogen assimilation and integration of photocatalytic and biological degradation pathways. The balanced ratio improved dissolved oxygen regulation via algal photosynthesis, while EPS helped mitigate g-C3N4-induced oxidative stress. These findings provide mechanistic insights for the strategic optimization of bacterial-algal consortia in photocatalytically enhanced wastewater treatment systems, with implications for the development of sustainable and energy-efficient water remediation technologies.

RevDate: 2025-09-12

Inès D, Pichereaux C, Wendehenne D, et al (2025)

Rhizophagus irregularis DAOM197198 modulates the root ubiquitinome of Medicago truncatula in the establishment and functioning of arbuscular mycorrhizal symbiosis.

Mycorrhiza, 35(5):54.

The regulation of cellular protein homeostasis involves the ubiquitin-proteasome system (UPS) by selectively targeting misfolded or end-of-life proteins. The involvement of the UPS in biotic stresses has been studied mainly in plant-pathogen interactions and poorly in plant-mutualistic interactions. Here, we studied through proteomic approaches (western blot, pull-down of polyubiquinated proteins and nano-LC-MS-MS analysis), the involvement of the UPS during the establishment of the mutualistic interaction between the arbuscular mycorrhizal fungus Rhizophagus irregularis DAOM197198 and the roots of Medicago truncatula, as well as in the established symbiosis. Roots of M. truncatula seedlings were harvested 0 h, 3 h, 6 h, 9 h, 12 h, 24 h and 15 days post-inoculation. We characterized a short-time and a-long-time response of the root ubiquitinome. Some proteins as such as flotilins or involved in the translational machinery were less-ubiquitinated, suggesting the facilitation of the de novo synthesis of proteins required to the establishment of arbuscular mycorrhizal symbiosis. In contrast, other proteins as transporters involved in plant nutrition through the direct pathway (i.e., MtPT5) and some enzymes involved in the lipid biosynthesis pathways were more-ubiquitinated, highlighting their putative degradation. In addition, Cdc48 protein accumulates in roots from 9 to 24 h post-inoculation, suggesting a role of Cdc48 in the transitory immune response during plant-fungal interactions. The activity of the UPS is consequently central in the establishment and functioning of arbuscular mycorrhizal symbiosis by modulating protein ubiquitination.

RevDate: 2025-09-12

Bernabéu-Roda LM, Rivera-Hernández G, Cuéllar V, et al (2025)

Identification of aSinorhizobium meliloti YbgC-like thioesterase that contributes to the production of the infochemical 2-tridecanone.

The Biochemical journal pii:236545 [Epub ahead of print].

Sinorhizobium meliloti is a soil bacterium that can establish beneficial symbiosis with legume plants. The fadD gene encodes a long-chain fatty acyl-coenzyme A (CoA) synthetase. Inactivation of FadD in S. meliloti leads to a pleiotropic phenotype, including the overproduction of several volatile methylketones (MKs). One of them, 2-tridecanone (2-TDC), was found to act as an infochemical that affects important bacterial traits and hampers plant-bacteria interactions. Knowledge about bacterial genes involved in MK production is limited. In wild tomato species, MK synthesis requires intermediates of fatty acid biosynthesis and the activity of the methylketone synthase 2 (MKS2), a thioesterase belonging to the hot dog-fold family. In this study, we have identified SMc03960, a conserved hypothetical protein with homology to bacterial YbgC-like thioesterases, as an ortholog of MKS2 in S. meliloti. Heterologous expression of smc03960 in Escherichia coli results in the formation of several MKs, including 2-TDC, and causes the accumulation of free fatty acids. Purified His-SMc03960 showed thioesterase activity for different acyl groups linked either to acyl carrier protein (ACP) or to CoA with preference for C14-long substrates. Moreover, formation of 2-TDC in vitro was achieved by using His-SMc03960 and 3-oxo-myristoyl-ACP. Although deletion of smc03960 in the wild type or in the fadD mutant does not significantly alter the amount of MKs released by S. meliloti, overexpression of the gene results in increased production of 2-TDC in these two strains. Overall, our data demonstrate that SMc03960 is an acyl-ACP/acyl-CoA thioesterase with broad substrate specificity that contributes to 2-TDC formation.

RevDate: 2025-09-12

Zhong W, Lin Z, Schmidt EW, et al (2025)

Discovery, biosynthesis, and bioactivities of peptidic natural products from marine sponges and sponge-associated bacteria.

Natural product reports [Epub ahead of print].

Covering 2010 to 2025Sponges are benthic, sessile invertebrate metazoans that are some of the most prolific sources of natural products in the marine environment. Sponge-derived natural products are often endowed with favorable pharmaceutical bioactivities, and paired with their structural complexity, have long served as title compounds for chemical syntheses. Sponges are holobionts, in that the sponge host is associated with symbiotic and commensal microbiome. Natural products isolated from sponges can be produced by the sponge host, or the associated microbiome. Recent genomic studies have shed light on the sponge eukaryotic host as the true producer of several classes of sponge-derived peptidic natural products. In this review spanning years 2010-2025, we describe peptidic natural products isolated from the sponge hosts and the associated microbiome, detail their biosynthetic processes where known, and offer forward looking insights into future innovation in discovery and biosynthesis of peptidic natural products from marine sponges.

RevDate: 2025-09-11

Sun Q, Wang J, Zhang H, et al (2025)

The effect of arbuscular mycorrhizal fungi on the growth of wheat seedlings with contrasting phosphorus use efficiencies under low phosphorus stress.

BMC plant biology, 25(1):1201.

BACKGROUND: Arbuscular mycorrhizal fungi (AMF) can stimulate root development in plants and enhance their ability to adapt to stress conditions. This study investigated the effects of arbuscular mycorrhizal fungi (AMF) inoculation on the growth, hormone dynamics, and phosphorus (P) metabolism of two wheat cultivars with differing phosphorus utilization efficiencies under both normal and low phosphorus concentration conditions. The research focused on the symbiotic interaction between AMF and these wheat varieties to elucidate their responses to varying phosphorus availability.

RESULT: The experiment showed that phosphorus inefficient wheat SW14 inoculated with AMF for 30 days under low phosphorus stress showed significant enhancement in plant height, biomass, leaf width, stem thickness, root surface area, and vegetative phosphorus content, while total root length and primary root length were reduced, This change in root length was attributed to the fact that the root system undergoes elongation and growth to adapt to the adversity under low phosphorus stress in crops, and inoculation with AMF effectively alleviated the extent of this low phosphorus stress. while IAA, SL, cellulose and lignin hormone levels and APC enzyme activities were significantly elevated, and stem structure was significantly optimized; whereas, the phosphorus-efficient variety, SW2, did not show significant improvement due to its own unique tolerance to low phosphorus stress (Table 2). Transcriptomic profiling identified 2,500 differentially expressed genes (DEGs: 983↑/1,517↓), enriched in ABC transporters (ko02010), Plant hormone signal transduction (ko04075), and MAPK signaling pathway - plant (ko04016), Cutin, suberin and wax biosynthesis(ko00073). WGCNA further resolved that AMF responded to low phosphorus stress by up-regulating the expression of cellulose, lignin, APC synthesis, and IAA/SL-related genes in SW14, with the most relevant phenotypes shown to correlate to primary root length, total root length, root dry weight and stem diameter.

CONCLUSION: AMF inoculation significantly enhanced growth and dry matter accumulation in the low-phosphorus-use-efficiency wheat variety SW14 under phosphorus-deficient stress. This treatment concurrently stimulated IAA, SL, and APC activities, resulting in increased phosphorus uptake/accumulation, notable accumulation of cellulose and lignin, and consequently significantly improved stem strength. Although AMF inoculation improved growth in the high-phosphorus-use-efficiency wheat variety SW2, these enhancements failed to reach statistical significance.

RevDate: 2025-09-11

Zonneveld KL, Bustos-Diaz ED, Francisco BG, et al (2025)

The cycad coralloid root: is there evidence for plant-microbe coevolution?.

Current opinion in microbiology, 88:102660 pii:S1369-5274(25)00082-7 [Epub ahead of print].

Cycads are survivors, ancient plants originating in the Carboniferous. We hypothesize that cycad resilience and recent diversification could be partially explained by their specialized coral-like (coralloid) roots and their microbiome and that these symbiotic partners are co-evolving. The coralloid root is unique in gymnosperms and rare in vascular plants. Coralloid roots and their associated microbes have been studied since the late 19th century, but a deeper understanding of their taxonomy and function has taken place only recently. And yet, we are at the 'tip of the root' as there are many open questions regarding this specialized organ and its evolutionary history. This review provides an overview of cycad coralloid roots and their microbiome, the technical limitations of their study to date, and the exciting questions that remain to be answered.

RevDate: 2025-09-11

Wang Y, M Liu (2025)

Relational vulnerability and technological mediation: The ethics of intelligent eldercare.

Nursing ethics [Epub ahead of print].

In current China, the 9073 elderly care system is accelerating the process of intelligentization. The fundamental tension between conventional filial piety ethics and technological rationality is evident in the numerous ethical debates triggered by intelligent older people's care services, despite their convenience. This study proposes an analytical paradigm called relational vulnerability, which creatively combines the philosophy of technology with Confucian relational ethics. Through the use of intricate mechanisms, this framework seeks to shed light on how technological mediation alters intergenerational ethics. According to research, intelligent services that improve physical care for older people while weakening emotional ties have a paradoxical effect that creates new kinds of alienation, such as the measurement of filial duty and the breakdown of ritual-embodied behaviors. By incorporating cultural calibration into the development of human-machine symbiosis, this study addresses this issue by proposing the design concepts of "differential regulation" and "embodiment retention." This counteracts the interpretive shortcomings of the Western autonomy-based ethical paradigm in the context of Chinese older people care, creating new avenues for the application of Confucian bioethics in the age of technology and offering fresh perspectives on moral dilemmas in intelligent older people care.

RevDate: 2025-09-10
CmpDate: 2025-09-11

Montoya QV, Gerardo NM, Martiarena MJS, et al (2025)

Digging into the evolutionary history of the fungus-growing-ant symbiont, Escovopsis (Hypocreaceae).

Communications biology, 8(1):1340.

Symbiotic relationships shape the evolution of organisms. Fungi in the genus Escovopsis share an evolutionary history with the fungus-growing "attine" ant system and are only found in association with these social insects. Despite this close relationship, there are key aspects of Escovopsis evolution that remain poorly understood. To gain further insight into the evolutionary history of these unique fungi, we delve deeper into Escovopsis' origin and distribution, considering the largest sampling, so far, across the Americas. Furthermore, we investigate Escovopsis' trait evolution, and relationship with attine ants. We demonstrate that, while the genus originated approximately 56.9 Mya, it only became associated with 'higher attine' ants in the last 38 My. Our results, however, indicate that it is likely that the ancestor of Escovopsis lived in symbiosis with early-diverging fungus-growing ants. Since then, the fungi have evolved morphological and physiological adaptations that have increased their reproductive efficiency, possibly to overcome barriers mounted by the ants and their other associated microbes. Taken together, these results provide new clues as to how Escovopsis has evolved within the context of this complex symbiosis and shed light on the evolutionary history of the fungus-growing ant system.

RevDate: 2025-09-10

Bhaya D, Birzu G, EPC Rocha (2025)

Horizontal Gene Transfer and Recombination in Cyanobacteriota.

Annual review of microbiology [Epub ahead of print].

Cyanobacteria played a pivotal role in shaping Earth's early history and today are key players in many ecosystems. As versatile and ubiquitous phototrophs, they are used as models for oxygenic photosynthesis, nitrogen fixation, circadian rhythms, symbiosis, and adaptations to harsh environments. Cyanobacterial genomes and metagenomes exhibit high levels of genomic diversity partly driven by gene flow within and across species. Processes such as recombination and horizontal transfer of novel genes are facilitated by the mobilome that includes plasmids, transposable elements, and bacteriophages. We review these processes in the context of molecular mechanisms of gene transfer, barriers to gene flow, selection for novel traits, and auxiliary metabolic genes. Additionally, Cyanobacteriota are unique because ancient evolutionary innovations, such as oxygenic photosynthesis, can be corroborated with fossil and biogeochemical records. At the same time, sequencing of extant natural populations allows the tracking of recombination events and gene flow over much shorter timescales. Here, we review the challenges of assessing the impact of gene flow across the whole range of evolutionary timescales. Understanding the tempo and constraints to gene flow in Cyanobacteriota can help decipher the timing of key functional innovations, analyze adaptation to local environments, and design Cyanobacteriota for robust use in biotechnology.

RevDate: 2025-09-10

Huang X, Li C, Zhang K, et al (2025)

Engineering and Functional Expression of the Type III Secretion System in Xenorhabdus: Enhancing Insecticidal Efficacy and Expanding T3SE Libraries.

Journal of agricultural and food chemistry [Epub ahead of print].

Entomopathogenic nematode symbiotic bacteria (EPNB) enhance nematode insecticidal capacity through symbiosis. This study cloned the complete 32-kb type III secretion system (T3SS) gene cluster from Photorhabdus luminescens TT01 using Red/ET recombineering and functionally expressed it in T3SS-deficient Xenorhabdus stockiae HN_xs01. Heterologous T3SS expression significantly enhanced HN_xs01 adhesion and invasion capabilities in CF-203 cells. In Helicoverpa armigera models, the engineered strain induced severe intestinal damage by suppressing antimicrobial peptide expression and demonstrated improved colonization and biocontrol efficacy (LC50 decreased by 3.7-fold). Crucially, the TT01 derived T3SS mediated delivery of XopA─a novel effector exhibiting YopJ-family homology and characteristic T3SS effector features─into host cells. These findings establish the synthetic biology-driven potential of T3SS and its effectors for biological control applications while providing a mechanistic framework for future research.

RevDate: 2025-09-10
CmpDate: 2025-09-10

Fox PT (2025)

Thirty years of SPM-BrainMap synergy: making and mining coordinate-based literature.

Cerebral cortex (New York, N.Y. : 1991), 35(8):.

Statistical Parametric Mapping (SPM) adheres to rigorous methodological standards, including: spatial normalization, inter-subject averaging, voxel-wise contrasts, and coordinate reporting. This rigor ensures that a thematically diverse literature is amenable to meta-analysis. BrainMap is a community database (www.brainmap.org; www.portal.brainmap.org) launched contemporaneously with SPM with the goal of efficiently sharing the results and methods of the literature compliant with SPM standards. The SPM-BrainMap symbiosis has motivated the development of coordinate-based meta-analytic methods and a substantial literature of secondary analyses. Collectively this corpus constitutes system-level probabilistic maps and models of the human brain, which details its functional organization, network architecture, and alterations by disease.

RevDate: 2025-09-10
CmpDate: 2025-09-10

Zhang X, Chen L, Li X, et al (2025)

Ectomycorrhizal symbiosis with Tuber spp. Enhances host performances in Pinus and Carya and induces host-specific patterns in defense-related regulation in the leaf transcriptomes.

Mycorrhiza, 35(5):53.

Ectomycorrhizal fungi (EMF) colonize roots to establish symbiotic associations with plants. Sporocarps of the EMF Tuber spp. are considered as a delicacy in numerous countries and is a kind of EMF of great economic and social importance. Elucidating host responses to Tuber colonization would facilitate the exploration of symbiotic interactions and contribute to truffle cultivation. Tuber indicum and T. panzhihuanense, two primary commercial truffle species in China, were selected to colonize Pinus armandii and Carya illinoinensis in a two-and-a-half-year symbiosis experiment. Host performances, including growth, nutrient uptake, and physiological characteristics, were dynamically monitored. The molecular response of host leaf to Tuber symbiosis was further analyzed using RNA-seq. Tuber indicum and T. panzhihuanense exhibited superior colonization of P. armandii compared to that of C. illinoinensis. Both Tuber species enhanced the performance of the two hosts by increasing their height, stem circumference, and biomass. Phosphorus levels and activities of peroxidase and catalase in hosts were observed to increase during Tuber symbiosis. The results confirmed that Tuber colonization led to significant alterations in leaf transcriptomic profiles of the two trees. Tuber indicum and T. panzhihuanense both elicited defense-related regulation in host leaves, such as secondary metabolism, cell wall biogenesis, plant hormone signal transduction, and plant-pathogen interaction, with distinct patterns in P. armandii and C. illinoinensis. Our study provides an evaluation of host performance during truffle symbiosis and highlights the diverse patterns of Tuber-induced systematic defense regulation in hosts, offering insights into the specific symbiotic traits of Tuber-host pairs.

RevDate: 2025-09-10

Veresoglou SD (2025)

Mycorrhizal ecology: In the land of the one-eyed king.

Journal of experimental botany pii:8250483 [Epub ahead of print].

Unlike most of the other disciplines in microbial ecology, a substantial fraction of the theory on mycorrhizal ecology originates from times when assaying microbes was laborious and inefficient. Most of those hypotheses target, as a result, the plant partner of the symbiosis, or at best treat the two mycorrhizal partners as a unified organism, a holobiont. I here address the legacy of this era of mycorrhizal ecology, as a means of systematizing our understanding of the discipline, but also identifying gaps of knowledge. First, I pair and review hypotheses that align with the holobiont concept with complementary hypotheses that explicitly consider the fitness of the mycorrhizal fungus. Second, I generate a hierarchy of hypotheses in mycorrhizal ecology to showcase the high potential for classifying theory that the distinction between hypotheses considering mycorrhiza as either a holobiont or an association of two individual partners maintains. Third, I identify settings that might dictate when to better abstract mycorrhizas into holobionts and when to consider all their partners individually to foster research progress. I conclude the review with suggestions on how to further unify expectations in mycorrhizal ecology.

RevDate: 2025-09-10

Boyno G, Danesh YR, Çevik R, et al (2025)

Plant-fungus synergy against soil salinity: The cellular and molecular role of arbuscular mycorrhizal fungi.

iScience, 28(9):113384.

Arbuscular mycorrhizal fungi (AMF) play a crucial role in disease control by establishing symbiotic relationships with plant roots. AMF improve salinity tolerance in plants by regulating the Na[+]/K[+] ratio through selective ion transport and mediate osmotic regulation by inducing the accumulation of osmotic-compatible solutes such as glycine betaine and proline to enable plant cells to maintain water content and the metabolic balance. AMF can also activate antioxidant defense responses by stimulating enzymes that protect plant cells from harmful oxidation and pathological infections. Plant salinity tolerance induced by AMF depends on abscisic acid (ABA)-dependent signaling mechanisms, calcium-calmodulin-dependent pathways, and reactive oxygen species (ROS)-modulated mitogen-activated protein kinase (MAPK) cascades. Therefore, future research should focus on optimizing the production and field efficacy of AMF-based inoculants, including their combined use with microbial biostimulants, to support the implementation of sustainable agricultural practices.

RevDate: 2025-09-10
CmpDate: 2025-09-10

Guo G, Zhao C, Xu W, et al (2025)

Treatment of Aquaculture Wastewater by Utilizing Single and Symbiotic Systems of Microalgae-Based Technology and Strigolactone Induction.

Water environment research : a research publication of the Water Environment Federation, 97(9):e70174.

This study investigated the efficacy of two microalgae treatment systems (Chlorella vulgaris monoculture and a Chlorella vulgaris-S395-2-Clonostachys rosea symbiotic system) in treating aquaculture wastewater, under varying concentrations of synthetic strigolactone analog (GR24). By exposing the systems to four GR24 doses (0, 10[-11], 10[-9], and 10[-7] M), we examined the impact on biomass growth, photosynthesis, and wastewater treatment. Elevated GR24 concentrations bolstered metabolism and photosynthesis in the systems, fostering rapid symbiont growth and enhanced treatment efficiency. Notably, the coculture system outperformed the monoculture in terms of photosynthetic rate, daily biomass accumulation, and nutrient reduction in aquaculture wastewater (p < 0.05). Optimally, at 10[-9] M GR24, the symbiotic system achieved remarkable average removal rates of COD (78.54 ± 6.11%), TN (81.69 ± 7.02%), and TP (82.67 ± 7.58%) from aquaculture wastewater. Additionally, a comparative analysis revealed the system's exceptional capacity to reduce oxytetracycline hydrochloride (OTC) levels, achieving a notable 98.72% removal rate. The outcomes significantly advance bioenhancement approaches and inform the design of efficient algal-bacterial-fungal symbiotic processes for treating antibiotic-contaminated wastewater.

RevDate: 2025-09-09

Bakrani Z, P Ehsanzadeh (2025)

Mycorrhizal inoculation mitigates drought stress in borage (Borago officinalis L.): Evidence from biochemical, physiological, and growth responses.

BMC plant biology, 25(1):1198.

RevDate: 2025-09-09
CmpDate: 2025-09-09

Udvardi M, C Mens (2025)

Symbiosis: A SWEET deal for nodules.

Current biology : CB, 35(17):R830-R832.

A new study shows that sucrose allocation within soybean roots by the sucrose transporter GmSWEET3c promotes rhizobial infection, nodulation, and symbiotic nitrogen fixation.

RevDate: 2025-09-09

Hu Y, CS Moreau (2025)

Nutritional Symbiosis Between Ants and Their Symbiotic Microbes.

Annual review of entomology [Epub ahead of print].

Nutritional symbioses with microorganisms have profoundly shaped the evolutionary success of ants, enabling them to overcome dietary limitations and thrive across diverse ecological niches and trophic levels. These interactions are particularly crucial for ants with specialized diets, where microbial symbionts compensate for dietary imbalances by contributing to nitrogen metabolism, vitamin supplementation, and the catabolism of plant fibers and proteins. This review synthesizes recent advances in our understanding of ant-microbe symbioses, focusing on diversity, functional roles in host nutrition, and mechanisms of transmission of symbiotic microorganisms. Despite progress, most research has concentrated on a few ant genera, and further exploration of microbial roles in different ant morphs and life stages and across various ant species is needed. Expanding research to include a broader array of ant lineages and integrating genomic data with additional experimental data will provide deeper insights into the metabolic strategies that facilitate ant success across diverse ecological habitats.

RevDate: 2025-09-09

Colombo M (2025)

Cognitive Symbionts. Expanding the Scope of Cognitive Science With Fungi.

Topics in cognitive science [Epub ahead of print].

It has been argued that fungi have cognitive capacities, and even conscious experiences. While these arguments risk ushering in unproductive disputes about how words like "mind," "cognitive," "sentient," and "conscious" should be used, paying close attention to key properties of fungal life can also be uncontroversially productive for cognitive science. Attention to fungal life can, for example, inspire new, potentially fruitful directions of research in cognitive science. Here, I introduce a concept of cognitive symbiosis whose significance for cognitive science becomes salient when we consider the centrality of symbioses in the life of fungi. Like fungi, virtually all cognitive systems live in close association with other kinds of cognitive systems, and this living together can have substantive psychological consequences. Expanding the scope of cognitive science to study a wide variety of cognitive symbioses underwrites the importance of biology and evolution in understanding minds.

RevDate: 2025-09-09

Amoros J, Buysse M, Floriano AM, et al (2025)

Diversity and spread of cytoplasmic incompatibility genes among maternally inherited symbionts.

PLoS genetics, 21(9):e1011856 pii:PGENETICS-D-25-00552 [Epub ahead of print].

Cytoplasmic Incompatibility (CI) causes embryonic lethality in arthropods, resulting in a significant reduction in reproductive success. In most cases, this reproductive failure is driven by Wolbachia endosymbionts through their cifA/cifB gene pair, whose products disrupts arthropod DNA replication during embryogenesis. While a cif pair has been considered a hallmark of Wolbachia, its presence and functional significance in other bacterial lineages remains poorly investigated. Here, we conducted a comprehensive survey of 762 genomes spanning non-Wolbachia endosymbionts and their close relatives, revealing that the cif pair is far more widespread than previously recognized. We identified cif loci in 8.4% of the surveyed genomes, with a striking incidence of 17.4% in facultative symbionts. Beyond Wolbachia, cif pair occurs across eight bacterial genera spanning α-Proteobacteria, γ-Proteobacteria, Mollicutes, and Bacteroidota. Notably, cif pair has been identified in several intracellular pathogens of mammals showing high rate of transovarial transmission in their arthropod hosts, suggesting a potential role of cif pair and CI in vector-borne disease dynamics. Structural analyses further reveal that the PD(D/E)-XK nucleases and AAA-ATPase-like motifs are consistently conserved across cif pairs in all bacterial taxa. Moreover, cif pairs are frequently integrated within diverse mobile genetic elements, from transposons to large intact WO prophages in Wolbachia and RAGEs in Rickettsiaceae. Phylogenetic analyses reveal recent and potentially ongoing horizontal transfers of cif pair between distantly related bacterial lineages, a process potentially facilitated by mobile genetic elements. Indeed, the PDDEXK2 transposase exhibits a phylogenetic pattern consistent with the co-transmission of cif genes, suggesting that it may facilitate horizontal transfers of cif across bacterial lineages. Furthermore, the detection of endosymbionts harboring cif pair in arthropod groups where Wolbachia is scarce, such as ticks, suggests that CI may be more widespread than previously known, with significant implications for arthropod symbiosis, reproductive manipulation, and future biocontrol strategies.

RevDate: 2025-09-09
CmpDate: 2025-09-09

Finegan C, Kates HR, Guralnick RP, et al (2025)

Convergent evolution of NFP-facilitated root nodule symbiosis.

Proceedings of the National Academy of Sciences of the United States of America, 122(37):e2424902122.

The origin and phylogenetic distribution of symbiotic associations between nodulating angiosperms and nitrogen-fixing bacteria have long intrigued biologists. Recent comparative evolutionary analyses have yielded alternative hypotheses: a multistep pathway of independent gains and losses of root nodule symbiosis vs. a single gain followed by numerous losses. A detailed reconstruction of the history of genes involved in signaling between nitrogen-fixing bacteria and potential hosts, particularly lipo-chitooligosaccharide (LCO) signaling, is needed to distinguish between these hypotheses. LCO recognition by plants involves the Nod Factor Perception (NFP) gene family; in the legume model Medicago truncatula (Fabales), MtNFP is essential for establishing rhizobial symbiosis. Here, we document convergent evolution of NFP, indicating multiple origins of LCO-driven symbiosis. In contrast to previous models that explain the recruitment of NFP via a single duplication in the ancestor of the nitrogen-fixing clade, our phylogenomic and synteny results suggest this duplication does not span the entire clade. Tandem duplication in a common ancestor of Cucurbitales and Rosales resulted in the NFP1 and NFP2 groups. In contrast, the phylogenetically closest paralog of MtNFP is MtLYR1, located on a different chromosome within a large syntenic block. All available data indicate that a large-scale duplication resulted in MtNFP and MtLYR1, likely corresponding to a whole-genome duplication in an ancestor of subfamily Papilionoideae of Fabaceae. We show that MtNFP and the NFP2-like group are not orthologous, indicating multiple independent gains of NFP-based LCO signaling. This molecular convergence provides a possible mechanism for multiple gains of root nodule symbiosis across the nitrogen-fixing clade.

RevDate: 2025-09-09

Wang S, Wang X, Adeniji OD, et al (2025)

Targeted Genome Editing of the ACC Deaminase Gene in Bradyrhizobium: Toward Enhanced Plant Growth and Stress Tolerance.

Biotechnology and bioengineering [Epub ahead of print].

Ensuring sufficient crop yields in an era of rapid population growth and limited arable land requires innovative strategies to enhance plant resilience and sustain, or even improve, growth and productivity despite environmental stress. Besides symbiotic nitrogen fixation, rhizobia may play a central role in sustainable agriculture by alleviating the detrimental effects of ethylene-a key stress hormone in plants-especially under conditions like drought through the deamination of 1-aminocyclopropane-1-carboxylic acid (ACC). In this study, we focused on genetically engineering a new Bradyrhizobium sp. isolate (Strain 9) from peanut root nodules to enhance its ACC deaminase activity. First, we developed a sacB-based genome-engineering tool and used it to knock out the ACC deaminase gene (acdS), confirming that its disruption severely diminished the strain's capacity to degrade ACC. Subsequently, we constructed an acdS-overexpressing strain by integrating a strong promoter and an optimized ribosome binding site upstream of acdS, achieving a five-fold increase in ACC deaminase activity relative to the wild-type. Peanut inoculation experiments demonstrated that both the acdS knockout and overexpression mutants effectively nodulated roots without impairing plant growth and nitrogen fixation, indicating that these modifications did not compromise symbiosis. Overall, this study highlights the utility of sacB-mediated counter-selection for precise genome editing in Bradyrhizobium and underscores the potential of enhanced ACC deaminase activity to improve plant growth under stress conditions. These findings pave the way for developing next-generation bioinoculants with superior ethylene mitigation capabilities, contributing to more productive and sustainable crop systems.

RevDate: 2025-09-08
CmpDate: 2025-09-08

Marks JC, Zampini MC, Fitzpatrick R, et al (2025)

Ecosystem consequences of a nitrogen-fixing proto-organelle.

Proceedings of the National Academy of Sciences of the United States of America, 122(37):e2503108122.

Microscale symbioses can be critical to ecosystem functions, but the mechanisms of these interactions in nature are often cryptic. Here, we use a combination of stable isotope imaging and tracing to reveal carbon (C) and nitrogen (N) exchanges among three symbiotic primary producers that fuel a salmon-bearing river food web. Bulk isotope analysis, nanoSIMS (secondary ion mass spectrometry) isotope imaging, and density centrifugation for quantitative stable isotope probing enabled quantification of organism-specific C- and N-fixation rates from the subcellular scale to the ecosystem. After winters with riverbed-scouring floods, the macroalga Cladophora glomerata uses nutrients in spring runoff to grow streamers up to 10 m long. During summer flow recession, riverine N concentrations wane and Cladophora becomes densely epiphytized by three species of Epithemia, diatoms with N-fixing endosymbionts (proto-organelles) descended from a free-living Crocosphaera cyanobacterium. Over summertime epiphyte succession on Cladophora, N-fixation rates increased as Epithemia spp. became dominant, Cladophora C-fixation declined to near zero, and Epithemia C-fixation increased. Carbon transfer to caddisflies grazing on Cladophora with high densities of Epithemia was 10-fold higher than C transfer to caddisflies grazing Cladophora with low Epithemia loads. In response to demand for N, Epithemia allocates high levels of newly fixed C to its endosymbiont. Consequently, these endosymbionts have the highest rates of C and N accumulation of any taxon in this tripartite symbiosis during the biologically productive season and can produce one of the highest areal rates of N-fixation reported in any river ecosystem.

RevDate: 2025-09-08

Luo Y, Srinivas A, Guidry C, et al (2025)

GacA regulates symbiosis and mediates lifestyle transitions in Pseudomonas.

mSphere [Epub ahead of print].

Through horizontal gene transfer, closely related bacterial strains assimilate distinct sets of genes, resulting in significantly varied lifestyles. However, it remains unclear how strains properly regulate horizontally transferred virulence genes. We hypothesized that strains may use components of the core genome to regulate diverse horizontally acquired genes. To investigate how closely related bacteria assimilate and activate horizontally acquired DNA, we used a model consisting of strains in the brassicacearum/corrugata/mediterranea (BCM) subclade of Pseudomonas fluorescens, including Pseudomonas species N2E2 and N2C3, which exhibit contrasting lifestyles on the model plant Arabidopsis. Pseudomonas sp. N2E2 is a plant commensal and contains genes encoding biosynthetic enzymes for the antifungal compound 2,4-diacetylphloroglucinol (DAPG). In contrast, Pseudomonas sp. N2C3 lacks DAPG biosynthesis and has gained a pathogenic island encoding syringomycin (SYR)- and syringopeptin (SYP)-like toxins from the plant pathogen Pseudomonas syringae. This causes a transition in lifestyle from plant-protective N2E2 to plant-pathogenic N2C3. We found that N2E2 and N2C3 share a highly conserved two-component system GacA/S, a known regulator of DAPG and SYR/SYP. Using knockout mutations, we found that a ΔgacA mutation resulted in loss of expression of SYR/SYP virulence genes and returned pathogenic N2C3 to a plant commensal lifestyle. Our study further explored the conservation of regulatory control across strains by demonstrating that GacA genes from both distant and closely related Pseudomonas strains could functionally complement one another across the genus.IMPORTANCEEmerging pathogens represent a significant threat to humans, agriculture, and natural ecosystems. Bacterial horizontal gene transfer (HGT) aids in the acquisition of novel genes that facilitate adaptation to new environments. Our work shows a novel role for GacA in orchestrating the regulatory changes necessary for virulence and lifestyle transitions facilitated by HGT. These findings suggest that the GacA/S system plays a key role in mediating transitions across diverse Pseudomonas symbiotic lifestyles. This work provides insights into the mechanisms that drive the emergence of pathogenic strains and highlights potential targets for managing bacterial threats to plant health.

RevDate: 2025-09-08

Xie T, Lv J, Wang L, et al (2025)

Uninfected cell-specific enzymes coordinate carbon supply and nitrogen assimilation in Medicago truncatula nodules.

The New phytologist [Epub ahead of print].

In legume root nodules, rhizobia invade host cells to form symbiosomes that drive atmospheric nitrogen fixation. Although the metabolic roles of infected cells (ICs) are well established, the contributions of adjacent uninfected cells (UCs) have remained largely unexplored. Here, through forward genetics methods, we identify DEBINO4, a phosphoenolpyruvate carboxylase (PEPC) uniquely expressed in UCs, as a pivotal regulator of carbon metabolism essential for sustaining symbiosome function and nitrogen assimilation. DEBINO4-deficient mutants display premature nodule senescence characterized by nonviable symbiosomes in the fixation zone and disrupted carbon and nitrogen metabolic profiles. The nodule-specific PEPC kinases (PPCKs), which are probably involved in DEBINO4 activation, are required to preserve symbiosome integrity, while Glutamine Synthetase 1a (GS1a), also restricted to UCs, is critical for ammonium assimilation and maintaining differentiated symbiosomes. Comprehensive analysis of metabolism-related genes further reveals that UCs execute specialized, stage-specific functions during nitrogen fixation. Collectively, our findings underscore the importance of cell-type-specific metabolic networks in orchestrating successful symbiosis and provide a framework for understanding how distinct nodule cell populations coordinate carbon and nitrogen metabolism to support efficient nitrogen fixation.

RevDate: 2025-09-08

Zhang L, Tian Y, Li L, et al (2025)

Movement Mechanisms Harness Lévy Flight for Energy-Efficient Wastewater Treatment in Microalgae-Bacteria Systems.

Advanced science (Weinheim, Baden-Wurttemberg, Germany) [Epub ahead of print].

Microalgae-bacteria symbiosis system is significant for sustainable and low-carbon wastewater treatment, with self-aggregation being key to its stable operation and effective pollutant removal. Cellular motility is the main driving force behind self-aggregation, crucial for symbiosis stability, but the characteristics and patterns involved still remain largely unexplored. Here, cellular movement dynamics into the microalgae-activated sludge model (ASM3) is incorporated, enabling synchronized simulation of metabolic activities and movement behaviors through physical and biochemical interactions in bioreactor systems. These findings indicate that microalgae induce bacterial movement towards Lévy flights, thereby increasing the bacterial encounter rate by 12.20%, augmenting signaling molecule concentration and biomass by 20.0% and 27.3%, respectively, which in turn strengthens the bacteria self-aggregation effect. Through practical reactor operations with metagenomic analysis, the efficacy of this model in elucidating self-aggregation is further corroborated, improving system stability and pollutant removal efficiency. An optimized microalgae-bacteria system reduces energy costs associated with cellular aggregation processes, economizing on the cost of chemotaxis-related proteins. This study not only elucidate the unique role of Lévy flight in self-aggregation, enhancing the understanding of microalgae-bacteria symbiosis, but also establish response mechanisms between motility patterns and operation dynamics. This allows for targeted regulation across various biosystems, ensuring cost-effective wastewater treatment and proactive prediction.

RevDate: 2025-09-08

Meng G, Li J, Cao Y, et al (2025)

Haplotype-resolved genomes of Phlebopus portentosus reveal nuclear differentiation, TE-mediated variation, and saprotrophic potential.

IMA fungus, 16:e161411.

Phlebopus portentosus is a widely consumed edible mushroom and the only Boletales species currently cultivated on an industrial scale. Despite its economic importance, its trophic strategy and genomic adaptations remain elusive. Here, we presented high-quality, chromosome-level genome assemblies for two sexually compatible monokaryons (PP78 and PP85) of P. portentosus. Comparative genomic analysis revealed a genome size difference of 1.17 Mb (30.87 vs. 32.04 Mb), primarily attributed to transposable element (TE) expansion in strain PP85. Genome structural variations were largely driven by TEs, particularly LTR retrotransposons. DNA transposons were also involved in structural rearrangement of secondary metabolite biosynthetic gene clusters, impacting their organization and transcriptional profiles. Functional annotation identified 187 PP78-specific and 236 PP85-specific genes, with the latter enriched in TE-related and putative virulence factors. P. portentosus displays genomic signatures of both ECM symbiosis (reduced lignocellulose-degrading enzymes) and saprotroph (expanded glycoside hydrolase 31 and sugar transporters), supporting a facultative ECM lifestyle. The expansion of non-ribosomal peptide synthetase and polyketide synthase pathways, alongside contraction of terpenoid clusters typical of ECM fungi, further indicated its adaptation to saprotroph. These findings highlight the role of TEs in driving genome plasticity, metabolic diversity, and nuclear divergence in P. portentosus, providing valuable genomic resources for this species.

RevDate: 2025-09-08

Fu L, Wang M, Li D, et al (2025)

Microbial metabolites short chain fatty acids, tight junction, gap junction, and reproduction: a review.

Frontiers in cell and developmental biology, 13:1624415.

The gut microbiota, comprising trillions of bacteria, fungi, and viruses, exists in symbiosis with the host. As the largest microbial ecosystem in the human body. The gut microbiota not only shapes the homeostasis of the intestinal microenvironment through gut-derived metabolites but also exerts regulatory effects on the functions of diverse tissues and organs throughout the body via the intricate "gut-distal organ axis" mechanism. Short chain fatty acids, such as acetic acid, propionic acid and butyric acid are high abundance intestinal metabolites, not only influence the intestinal barrier by regulating tight junction proteins, but also affect intestinal peristalsis by regulating gap junction proteins. These microbial metabolites may also play a important role in the formation and maintenance of the key barriers of the reproductive system, such as the ovarian blood follicle barrier, the testicular blood-testis barrier, and the endometrial epithelial barrier. In reproductive system, Gap junction-mediated intercellular communication, facilitated by connexins, proves essential in germ cell maturation, embryo implantation, and spermatogenesis. The dysregulation of these microbial metabolites leading to abnormal tight junction and gap junction protein functions provides novel perspectives for understanding the pathogenesis of reproductive disorders such as polycystic ovary syndrome and premature ovarian failure. This review systematically elucidates the molecular networks through which short-chain fatty acids regulate tight and gap junction proteins, highlighting their potential roles in reproductive physiology.

RevDate: 2025-09-08

Sharoni T, Jaimes-Becerra A, Lewandowska M, et al (2025)

Heat Stress Drives Rapid Viral and Antiviral Innate Immunity Activation in Hexacorallia.

Molecular ecology [Epub ahead of print].

The class Hexacorallia, encompassing stony corals and sea anemones, plays a critical role in marine ecosystems. Coral bleaching, the disruption of the symbiosis between stony corals and zooxanthellate algae, is driven by seawater warming and further exacerbated by pathogenic microbes. However, how pathogens, especially viruses, contribute to accelerated bleaching remains poorly understood. Here the model sea anemone Nematostella vectensis is used to explore these dynamics by creating a transgenic line with a reporter gene regulated by sequences from two RIG-I-like receptor genes involved in antiviral responses. Under heat stress, the reporter genes showed significant upregulation. Further, transcriptomes from N. vectensis, Exaiptasia diaphana and the stony coral Stylophora pistillata were analysed to reveal stress-induced activation of a set of bona fide immune-related genes conserved between the three species. Population-specific differences in stress-induced transcriptional responses of immune-related genes were evident in both Nematostella and Stylophora, depending on geographic origin. In Exaiptasia, the presence of zooxanthellae also influenced stress-induced immune gene expression. To test whether the viruses themselves contribute to this immune response under stress, we subjected N. vectensis to heat stress and measured the transcription dynamics of resident viruses as well as selected antiviral genes. While the antiviral genes responded within hours of heat stress, viral gene expression was already upregulated within 30 min, suggesting that their increase might be contributing to the elevated immune response under stress, and consequentially, the further demise of organismal homeostasis. These findings highlight the interplay between environmental stress, viruses, immune responses and symbiotic states in Hexacorallia.

RevDate: 2025-09-07
CmpDate: 2025-09-07

Xue H, Qiao X, Du L, et al (2025)

Host-microbe synergy in pesticide resilience: Rhodococcus-driven fitness compensation in chlorpyrifos-stressed Binodoxys communis.

Pesticide biochemistry and physiology, 214:106609.

Chlorpyrifos (CPF), a widely used organophosphate insecticide in cotton cultivation for controlling Aphis gossypii, has Binodoxys communis as the primary parasitic natural enemy of A. gossypii. This study evaluated the impact of two sub-lethal CPF concentrations (LC10 and LC30) on key biological parameters across two generations, transcriptomic responses, and symbiotic bacterial communities in B. communis. CPF exposure significantly reduced F1 generation survival by 39.89 % (LC10) and F2 generation survival by 33.31 % (LC30). Emergence rates were markedly decreased in both F1 (33.43 %) and F2 (19.86 %) generations under LC10 exposure. Furthermore, LC10 treatment significantly prolonged the F1 pre-pupal stage by 31.58 %. Short-term (1 h) CPF exposure markedly suppressed the expression of genes involved in energy metabolism, lipid metabolism, and PPAR signaling pathways. Notably, CPF exposure (both 1 h and 3 days) resulted in a significant increase in the relative abundance of Rhodococcus, suggesting a potential role of this bacterium in enhancing B. communis fitness under insecticide stress. Our findings not only inform the judicious application of CPF, but also identify molecular targets associated with energy and nutrient metabolism, while laying the groundwork for harnessing bacteria to enhance pesticide resistance in parasitoid wasps.

RevDate: 2025-09-08

Regan MD, Chiang E, Grahn M, et al (2025)

Host-microbiome mutualism drives urea carbon salvage and acetogenesis during hibernation.

bioRxiv : the preprint server for biology.

Hibernation is a seasonal survival strategy employed by certain mammals that, through torpor use, reduces overall energy expenditure and permits long-term fasting. Although fasting solves the challenge of winter food scarcity, it also removes dietary carbon, a critical biomolecular building block. Here, we demonstrate a process of urea carbon salvage (UCS) in hibernating 13-lined ground squirrels, whereby urea carbon is reclaimed through gut microbial ureolysis and used in reductive acetogenesis to produce acetate, a short-chain fatty acid (SCFA) of major value to the host and its gut microbiota. We find that urea carbon incorporation into acetate is more efficient during hibernation than the summer active season, and that while both host and gut microbes oxidize acetate for energy supply throughout the year, the host's ability to absorb and oxidize acetate is highest during hibernation. Metagenomic analysis of the gut microbiome indicates that genes involved in the degradation of gut mucins, an abundant endogenous nutrient, are retained during hibernation. The hydrogen disposal associated with reductive acetogenesis from urea carbon helps facilitate this mucin degradation by providing a luminal environment that sustains fermentation, thereby generating SCFAs and other metabolites usable by both the host and its gut microbes. Our findings introduce UCS as a mechanism that enables hibernating squirrels and their gut microbes to exploit two key endogenous nutrient sources - urea and mucins - in the resource-limited hibernation season.

RevDate: 2025-09-08

Lian J, Zou D, Trebuch LM, et al (2025)

Exploring the interactions between algae and archaea.

Marine life science & technology, 7(3):450-465.

Algae and archaea co-exist in diverse aquatic ecosystems and play a significant role in ecological functions and biogeochemical cycles. Compared to well-studied algal-bacterial interactions, there is a lack of information on algal-archaeal interactions and how their interactions affect their physiological fitness and nutrient cycles in either artificial cultivation systems or natural environments. The vast archaeal biodiversity, as indicated by genomic sequencing and computational approaches, has stimulated great interest in exploring uncultivated archaea to expand our knowledge of algae-archaea symbiosis. In this review, we summarize the latest studies on the diversity of algae-associated archaea and their (putative) symbiotic interactions, highlight the effects of algal-archaeal interactions on biogeochemical cycles and extend such knowledge to facilitate novel archaeal isolation and a broad range of algae-based biotechnological applications.

RevDate: 2025-09-07
CmpDate: 2025-09-07

Costa FF, Lustosa BPR, Perico CP, et al (2025)

In silico search reveals the association of lichens with black yeast-like fungi in the order Chaetothyriales.

Fungal biology, 129(6):101618.

Lichens exemplify a unique symbiotic relationship between fungi and algae or cyanobacteria, where fungi (mycobionts) provide structural support, while algae or cyanobacteria (photobionts) provide nutrients. Recent discoveries in the order Chaetothyriales have led to the description of several lichenicolous species, underscoring an intricate relationship of some black yeast-like fungi with lichens. The present study aims to investigate public metagenomic data of lichens available in the SRA database, covering a total of 2888 samples. The analysis incorporated 122 molecular marker sequences (barcodes and padlock probes) previously documented in the literature for species classified within Chaetothyriales. Additionally, 11 novel barcodes for species recently identified in lichens of the genera Cladophialophora and Paracladophialophora are described. The selected metagenomes were then compared with molecular marker sequences using local BLASTn (v2.6.0+), considering only alignments with a coverage cut-off and 100 % identity (perfect match). Reads from each sample were retrieved from the SRA as a multifasta file and analyzed with the SWeeP method for vector-based, alignment-free sequence analysis. The analysis identified fungi that are known as environmental inhabitants and, occasionally, opportunistic pathogens of vertebrates, including species in the genera Cladophialophora, Cyphellophora, and Exophiala. These species were distributed across 11 BioProjects from various locations around the world. The findings of this study corroborate extant knowledge concerning fungal colonization in diverse extremophilic environments, including deserts, tundra, and rocky surfaces.

RevDate: 2025-09-07

Shu P, Zhao L, Wen X, et al (2025)

Iron oxide-mediated enhancement of extracellular electron transfer and symbiosis in consortium of electroactive bacteria and microalgae for wastewater treatment.

Water research, 287(Pt B):124516 pii:S0043-1354(25)01420-4 [Epub ahead of print].

This study explores the role of α-Fe2O3 in improving extracellular electron transfer (EET) and symbiotic interactions between electroactive Shewanella oneidensis MR-1, its gene-deficient mutants (ΔmtrC, ΔomcA, and ΔcymA), and microalgae (Chlorella vulgaris). The iron oxide facilitates the efficient transfer of electrons generated by MR-1 to microalgal photosystem via the pathway of CymA-MtrC-OmcA to α-Fe2O3. This process enhances the removals of TOC, TN, and NH4[+]-N in the MR-1 bacterial-algal consortium by 9.99%, 12.32%, and 52.25% respectively via OmcA regulation while boosting phosphorus removal by 16.27% through CymA regulation. The consortium exhibits 26.76% lower CO2 emission and 62.93% higher biomass productivity. When integrated into microbial fuel cells with ΔcymA mutants, α-Fe2O3 elevates open-circuit voltage by 283.33%, confirming its ability to compensate for electron deficiencies caused by CymA defects. α-Fe2O3 enhances energy metabolisms (TCA cycle, quinone pool, and photosynthesis) to modulate the key metabolites including starch/sucrose, glycolysis, amino acids, lipids, and quorum sensing. These adaptations strengthen the symbiotic interactions and utilization of MR-1 bacterial-algal consortium for carbon and nutrients. Reactor experiments validate that α-Fe2O3 integration with the consortium achieves 93.43% COD removal and 55.99% NH4[+]-N removal, while reducing N2O emissions by 61.37%. The results reveal the interplay between OmcA, CymA, and iron oxides in optimizing bacterial-algal consortia and underscore the molecular mechanisms underlying iron oxide-enhanced EET for developing low-carbon, resource-efficient wastewater treatment.

RevDate: 2025-09-07

Ortiz J, Sanhueza C, Romero-Munar A, et al (2025)

Nitrogen source and availability associate to mitochondrial respiratory pathways and symbiotic function in Lotus japonicus.

Journal of plant physiology, 314:154606 pii:S0176-1617(25)00188-9 [Epub ahead of print].

Legumes form symbioses with nitrogen-fixing bacteria, well studied metabolically but less so in terms of respiration. Symbiotic nitrogen fixation demands high respiratory ATP and carbon skeletons, linking nitrogen assimilation and both NADH- and ATP-dependent process to mitochondrial respiration. The plant mitochondrial electron transport chain contains two terminal oxidases that differentially fractionate against [18]O, providing estimations in vivo of the energy efficiency of respiration. The regulation of N2 fixation by plant respiratory parameters remains unknown. To investigate the regulatory interactions of these two metabolic processes, we tested the effect of different plant N status and sources on respiratory parameters and nutrition in Lotus japonicus. Plants were grown with two levels of KNO3 fertilization (5 mM and 25 mM) and with the N2 fixing symbiotic bacteria Mesorhizobium loti, which induced the formation of root nodules (NP). Additionally, we characterized roots containing non-fixing nodules by growing plants that display spontaneous nodule formation (snf) (SNF). We evaluated the natural abundances of [13]C and [15]N, and [18]O discrimination during respiration in leaves and roots using isotope-ratio mass spectrometry. NADH and nutrient content were measured using ultra-performance liquid chromatography and inductively coupled plasma spectrometry. We observed that cytochrome c oxidase activity was higher in nodulated roots capable of nitrogen fixation than in plants fertilized with high availability of nitrate, and that nitrogen status strongly associates to respiratory parameters. These findings highlight the role of cytochrome c oxidase in meeting the carbon and energy demands of symbiotic nitrogen fixation.

RevDate: 2025-09-07
CmpDate: 2025-09-07

Gao Y, Wu Y, Chang P, et al (2025)

Mycorrhizal Network and Symbiotic N-Fixer Jointly Enhance the Interplant Nitrogen Sharing.

Ecology letters, 28(9):e70204.

Symbioses with mycorrhizal fungi and nitrogen-fixing bacteria (NFB) enhance nitrogen (N) acquisition in host plants and may promote N transfer to neighbouring plants through mycorrhizal networks (MN). Nevertheless, the extent and mechanisms of this transfer remain unclear. On the basis of a synthesis of [15]N labeling studies, we show that MN and NFB synergistically enhanced interplant N sharing. In the presence of MN, N transfer from N-fixing donors to non-N-fixing receivers increased by an average of 9.7-fold, accounting for 5.61% of the total N in receiver plants. Moreover, greater amounts of N were transferred from N-fixing plants towards their phylogenetically distant plants. Source-sink gradients driven by differences in N content between neighbouring plants further promoted N transfer. Together, our findings highlight the ecological significance of an expanded MN framework in explaining interplant N sharing and provide new insights into how symbiotic guild interactions promote species coexistence and biodiversity maintenance.

RevDate: 2025-09-06

Havlik MN, Geraldi NR, Hopkins LW, et al (2025)

Boat noise alters behaviour of two coral reef macroinvertebrates, Lambis lambis and Tridacna maxima.

Marine pollution bulletin, 222(Pt 1):118650 pii:S0025-326X(25)01126-9 [Epub ahead of print].

Boat noise has been shown to distract and cause harm to many marine organisms. Most of the study effort has focused on fish & marine mammals, even though invertebrates represent over 92 % of all marine life. The few studies conducted on invertebrates have demonstrated clear negative effects of anthropogenic noise pollution. The small giant clam Tridacna maxima and the spider conch Lambis lambis are two invertebrate species which play key roles in coral reef ecosystems, and are little studied for the effects of noise disturbance. T. maxima functions as prey for many fish species, contributes up to 9 % of the reef's calcium carbonate budget, and plays a role in nutrient cycling. The herbivorous strombid L. lambis can occur in large numbers on reef flats and is prey for other snails and several elasmobranchs. Using two case study reefs, we show that both boat noise and biotic sounds are prominent sound sources in Red Sea reef habitats. In-situ controlled exposure experiments were conducted on two shallow central Red Sea reefs, where Daily Diary smart tags were used to measure the reactions of T. maxima and L. lambis during underwater playback of boat noise and ambient reef sound. Both macroinvertebrates exhibited behavioral changes during the boat noise treatment. Our results suggest that L. lambis and T. maxima individuals may spend energy averting the invisible "threat" of boat noise, rather than feeding or staying open for symbiotic algae to perform photosynthesis, in the case of T. maxima. As boat noise is prevalent on Red Sea reefs, invertebrates may be affected on a large scale in the Red Sea.

RevDate: 2025-09-06

Lopes MR, Direito R, Guiguer EL, et al (2025)

Bridging the Gut Microbiota and the Brain, Kidney, and Cardiovascular Health: The Role of Probiotics.

Probiotics and antimicrobial proteins [Epub ahead of print].

The symbiosis between intestinal bacteria and the human body's physiological processes can modulate health. The intestinal microbiota is linked to the development of neurotrophic factors; therefore, it is increasingly related to the modulation of nervous system pathologies. Moreover, microbiota can interfere with inflammation and oxidative stress, which are closely linked to cardiovascular risk factors and several other inflammatory conditions, such as kidney and neurodegenerative diseases. Probiotics are live microorganisms that help regulate and maintain healthy microbiota; thus, they can help prevent these diseases. Due to these reasons, this review aimed to evaluate the effects of probiotics on the gut, kidneys, brain, and heart homeostasis. Clinical trials showed several positive results with the treatment. In the brain, probiotics reduce depressive symptoms (decreases in HAMA, GAD-7, and BDI-II scales), improving patients' sleep quality and fatigue, enhancing cognitive subscales while slowing brain atrophy, and reducing IL-6 levels in the central areas, also modulating REM delta power to reduce high-frequency brain waves. Probiotics can also reduce cardiovascular risk factors, such as inflammation. Probiotics can also benefit the heart by decreasing TMAO, LDL-c, TG, CRP, MDA, TNF-α, IL-6, and urea levels, improving dyslipidemia and toxin profiles. Probiotics also increase HDL-c, ApoE, and insulin sensitivity, decreasing BMI, body fat, and the risk of developing chronic hyperglycemia while increasing lean mass. Besides, probiotic supplementation helped reduce toxic uremic toxins (serum urea) and sodium levels, bringing benefits to the kidneys, and improve energy/amino acid metabolism. Probiotics can also modulate and enhance kidney function due to decreased pro-inflammatory TGFβ-1 and TNF-α levels and RUNX2. Furthermore, enhanced gastrointestinal motility and diversity have been reported using specific bacteria. Although probiotics can bring several health benefits, there are still challenges regarding these supplements, such as dose, frequency, and pharmaceutical formula. Therefore, new studies are welcome to deepen the understanding of these microorganisms.

RevDate: 2025-09-06

Mostafa KM, Cheng YH, Chu LW, et al (2025)

Environment-dependent mutualism-parasitism transitions in the incipient symbiosis between Tetrahymena utriculariae and Micractinium tetrahymenae.

The ISME journal pii:8248686 [Epub ahead of print].

Mutualistic endosymbiosis is a cornerstone of evolutionary innovation, enabling organisms to exploit diverse niches unavailable to individual species. However, our knowledge about the early evolutionary stage of this relationship remains limited. The association between the ciliate Tetrahymena utriculariae and its algal endosymbiont Micractinium tetrahymenae indicates an incipient stage of photoendosymbiosis. Although T. utriculariae cells rely on endosymbiotic algae to grow in low-oxygen conditions, they gradually lose the endosymbionts in oxic conditions. In this study, comparative phylogenomics revealed accelerated evolution in mitochondrial DNA and nucleus-encoded mitochondrial genes in T. utriculariae. Symbiotic cells displayed elongated mitochondria that interacted intimately with endosymbionts. Inhibition of mitochondrial fatty acid oxidation reduced host fitness but increased the endosymbiont population. Time-series transcriptomics revealed physiological fine-tuning of the host across day-night cycles, highlighting symbiosis-associated regulatory adjustments. Endosymbiotic algae downregulated photosynthesis-related genes compared with free-living cells, which correlated with reduced chlorophyll content, suggesting a shift toward host resource exploitation to compensate for diminished photosynthetic capacity. Under oxic conditions, symbiotic T. utriculariae cells exhibited lower fitness than aposymbiotic cells. Our results demonstrate that incipient endosymbioses employ mitochondrial remodeling and endosymbiont metabolic reprogramming to actively regulate transitions between mutualistic and parasitic states, revealing how symbiotic partnerships navigate environmental pressures during their incipient stage of evolutionary establishment.

RevDate: 2025-09-05

Chandola U, Manirakiza E, Maillard M, et al (2025)

A Bradyrhizobium isolate from a marine diatom induces nitrogen-fixing nodules in a terrestrial legume.

Nature microbiology [Epub ahead of print].

Biological nitrogen fixation converts atmospheric nitrogen into ammonia, essential to the global nitrogen cycle. While cyanobacterial diazotrophs are well characterized, recent studies have revealed a broad distribution of non-cyanobacterial diazotrophs (NCDs) in marine environments, although their study is limited by poor cultivability. Here we report a previously uncharacterized Bradyrhizobium isolated from the marine diatom Phaeodactylum tricornutum. Phylogenomic analysis places the strain within photosynthetic Bradyrhizobium, suggesting evolutionary adaptations to marine and terrestrial niches. Average nucleotide identity supports its classification as a previously undescribed species. Remarkably, inoculation experiments showed that the isolate induced nitrogen-fixing nodules in the Aeschynomene indica legume, pointing to symbiotic capabilities across ecological boundaries. Pangenome analysis and metabolic predictions indicate that this isolate shares more features with terrestrial photosynthetic Bradyrhizobium than with marine NCDs. Overall, these findings suggest that symbiotic interactions could evolve across different ecological niches, and raise questions about the evolution of nitrogen fixation and microbe-host interactions.

RevDate: 2025-09-05
CmpDate: 2025-09-05

Chang ACG, Amaral MWW, Greenwood M, et al (2025)

Evolutionary dynamics in plastomes and mitogenomes of diatoms.

PloS one, 20(9):e0331749 pii:PONE-D-25-06220.

Diatoms are pivotal in global oxygen, carbon dioxide, and silica cycling, contributing significantly to photosynthesis and serving as fundamental components in aquatic ecosystems. Recent advancements in genomic sequencing have shed light on their evolutionary dynamics, revealing evolutionary complex genomes influenced by symbiotic relationships and horizontal gene transfer events. By analyzing publicly available sequences for 120 plastomes and 70 mitogenomes, this paper aims to elucidate the evolutionary dynamics of diatoms across diverse lineages. Gene losses and pseudogenes were more frequently observed in plastomes compared with mitogenomes. Overall, gene losses were particularly abundant in the plastomes of Astrosyne radiata, Toxarium undulatum, and Proboscia sp. Frequently lost and pseudogenized genes were acpP, ilv, serC, tsf, tyrC, ycf42 and bas1. In mitogenomes, mttB, secY and tatA genes were lost repeatedly across several diatom taxa. Analysis of nucleotide substitution rates indicated that, in general, mitogenomes were evolving at a more rapid rate compared to plastomes. This is contrary to what was observed in synteny analyses, where plastomes exhibited more structural rearrangements than mitogenomes, with the exception of the genus Coscinodiscus and one group of species within Thalassiosira.

RevDate: 2025-09-05

Tang J, Yang S, Li S, et al (2025)

Editing a gibberellin receptor gene improves yield and nitrogen fixation in soybean.

Journal of integrative plant biology [Epub ahead of print].

Soybean is an important source of oil, protein, and feed. However, its yield is far below that of major cereal crops. The green revolution increased the yield of cereal crops partially through high-density planting of lodging-resistant semi-dwarf varieties, but required more nitrogen fertilizers, posing an environmental threat. Genes that can improve nitrogen use efficiency need to be integrated into semi-dwarf varieties to avoid the overuse of fertilizers without the loss of dwarfism. Unlike cereal crops, soybean can assimilate atmospheric nitrogen through symbiotic bacteria. Here, we created new alleles of GmGID1-2 (Glycine max GIBBERELLIN INSENSITIVE DWARF 1-2) using clustered regularly interspaced short palindromic repeats (CRISPR)/CRISPR-associated nuclease 9 (Cas9) editing, which improved soybean architecture, yield, seed oil content, and nitrogen fixation, by regulation of important pathways and known genes related to branching, lipid metabolism, and nodule symbiosis. GmGID1-2 knockout reduced plant height, and increased stem diameter and strength, number of branches, nodes on the primary stem, pods, and seeds per plant, leading to an increase in seed weight per plant and yield in soybean. The nodule number, nodule weight, nitrogenase activity, and nitrogen content were also improved in GmGID1-2 knockout soybean lines, which is novel compared with the semi-dwarf genes in cereal crops. No loss-of-function allele for GmGID1-2 was identified in soybean germplasm and the edited GmGID1-2s are superior to the natural alleles, suggesting the GmGID1-2 knockout mutants generated in this study are valuable genetic resources to further improve soybean yield and seed oil content in future breeding programs. This study illustrates the pleiotropic functions of the GID1 knockout alleles with positive effects on plant architecture, yield, and nitrogen fixation in soybean, which provides a promising strategy toward sustainable agriculture.

RevDate: 2025-09-05

Zhang G, Yue Y, Tu L, et al (2025)

Responses of microbial communities during oilseed plant-based phytoremediation of heavy metal contaminated soils.

Journal of applied microbiology pii:8248509 [Epub ahead of print].

AIMS: Phytoremediation is an effective method of remediating soils contaminated with heavy metals. However, it has some limitations in practical applications with regard to rare plant species, poor environmental adaptability, and long growth cycles. The dynamic response mechanisms of soil microbial communities during phytoremediation are still unclear, which restricts the optimization and promotion of this approach.

METHODS AND RESULTS: No ethical approval was required for this study. In this study, soil bacterial, fungal, and archaeal communities during the remediation of Cu-, Pb-, and Zn-contaminated soils with five industrial oilseed plants (Xanthium strumarium (XS), Bidens pilosa (BP), Kosteletzkya virginica (KV), Sesbania cannabina (SC), and Commelina communis (CC)) were analyzed using metagenome sequencing. Compared with soil contaminated with heavy metals, remediation through five industrial oilseed plants significantly reduced the content of heavy metals in the soil, with soil Cu, Pb, and Zn decreasing by 44.01%, 46.32%, and 27.62%, respectively, and WSCu, WSPb, and WSZn content decreasing by 28.23%, 50.68%, and 75.26%, respectively. Microbial diversity analysis showed that phytoremediation significantly affected the soil microbial communities, with a significant decrease in archaeal diversity. Variation partitioning analysis and Mantel tests revealed that heavy metals and soil physicochemical properties significantly affected microbial communities, and heavy metals exerted stronger effects on archaeal communities. Meanwhile, soil contaminated with heavy metals was mainly dominated by fungal-fungal interactions, whereas phytoremediation increased the complexity of microbial symbiotic networks.

CONCLUSION: Collectively, these results provide fundamental insights into the microbial community structure during phytoremediation of heavy metal contaminated soil, which may aid in the bioregulation of phytoremediation.

RevDate: 2025-09-05
CmpDate: 2025-09-05

Irum S, Cilkiz M, Al-Kubaisi N, et al (2025)

Genome-wide characterization and expression analysis of the chitinase gene family in chickpea (Cicer arietinum L.) for fungal stress resistance.

Molecular biology reports, 52(1):871.

Chitinases, enzymes responsible for hydrolyzing chitin, a significant component of fungal cell walls, play a crucial role in plant defense mechanisms, growth, symbiotic relationships, and stress resistance. In this study, we identified 27 chitinase genes in chickpeas (CaChi) and classified them into five classes based on phylogenetic analysis. Overall, chitinase genes are clustered on eight chromosomes. Among these chromosomes (Chr), Chr-2 displayed the maximum number of genes. Meanwhile, promoter analysis revealed that cis-elements are involved in responses to phytohormones, biotic stress, plant growth, and development. Tissue-based expression analysis indicated that CaChi genes are predominantly expressed in the seedling and floral parts. Furthermore, qRT-PCR analysis revealed that CaChi genes play diverse roles in plant-environment interactions. Notably, several CaChi members were strongly induced by Fusarium oxysporum f. sp. and fourteen genes (CaChi20, CaChi25, CaChi11, CaChi3, CaChi16, CaChi14, CaChi1, CaChi4, CaChi5, CaChi8, CaChi9, CaChi21, CaChi18, CaChi13) exhibited elevated expression levels after post-inoculation, depicting a significant function of Chi genes in chickpea resistance to Fusarium wilt. These findings enhance understanding of the chitinase family in chickpea crops and clarify the functions of chickpea chitinase in response to fungal stress.

RevDate: 2025-09-05

Chen M, Raisin A, Judkins N, et al (2025)

Inhibition of rhizobial cheaters by the host Medicago truncatula involves repression of symbiotic functions and induction of defense.

The New phytologist [Epub ahead of print].

In symbiotic plant-microbe interactions, the host invests considerable amounts of resources in the microbial partner. If the microbe does not reciprocate with a comparable symbiotic benefit, it is regarded as a cheater. The host responds to cheaters with negative feedback mechanisms (sanctions) to prevent fitness deficits resulting from being exploited. We study sanctioning in the symbiosis between Medicago truncatula and the nitrogen-fixing rhizobium Sinorhizobium meliloti. We manipulated the exchange of resources between the partners in three ways: by using mutant rhizobia defective in nitrogenase; replacing nitrogen in the atmosphere with argon gas; and supplying rich nitrogen fertilizer to the host. We follow the consequences of simulated cheating by examining the metabolome and proteome of both partners. We find that sanctioning occurs at multiple levels. In particular, we observe repression of essential symbiotic functions and changes in central metabolism that are likely to be relevant for microbial fitness and that could therefore contribute to sanctioning. In addition, sanctioning triggers a broad panel of defense markers. A thorough understanding of the multilevel phenomenon of sanctioning will be essential for its genetic dissection and for the breeding of elite legume crops with efficient symbiosis.

RevDate: 2025-09-05

Bruzzese DJ, Gstöttenmayer F, Weiss BL, et al (2025)

Comparative genomics and transcriptomics of the Spiroplasma glossinidia strain sGff reveal insights into host interaction and trypanosome resistance in Glossina fuscipes fuscipes.

Research square pii:rs.3.rs-7295611.

Tsetse (Glossina spp.) are vectors of African trypanosomes, the causative agents of Human and African Animal trypanosomiases, diseases that remain significant medical and socioeconomic challenges in sub-Saharan Africa. In addition to trypanosomes, tsetse harbor both obligate and facultative symbiotic bacteria that can influence vector competence and reproductive biology. One such facultative symbiont, Spiroplasma glossinidia , infects several tsetse species within the Palpalis subgroup. In Glossina fuscipes fuscipes (Gff), the Spiroplasma glossinidia strain s Gff induces a trypanosome-refractory phenotype and negatively impacts reproductive fitness by reducing female fecundity. However, the mechanisms behind these Spiroplasma -derived phenotypes remain poorly understood. Here, we report successful in vitro cultivation of s Gff and present complete genomes from three sources: in vitro cultured s Gff and s Gff isolated from both laboratory-maintained and wild-caught (Uganda) Gff flies. Comparative genomic analyses revealed a high degree of similarity in gene content and synteny among these s Gff samples, confirming that they represent isolates of the same strain. Phylogenomic analyses placed s Gff within the Spiroplasma poulsonii clade. The s Gff genome is highly dynamic, containing numerous mobile genetic elements. Additionally, in silico annotations indicate that s Gff relies on its host for both lipids and carbohydrates and produces several toxins, all of which could be implicated in the observed trypanosome refractory phenotype. Finally, comparative transcriptomic analysis of s Gff from host hemolymph versus in vitro culture provided insights into potential factors relevant to host-symbiont interactions. Our findings provide a foundation for understanding the nutritional dialogue between s Gff and its host and identify symbiotic products that may contribute to trypanosome resistance. Furthermore, the establishment of an in vitro culture system for s Gff represents a significant resource for future functional studies with potential implications for vector control.

RevDate: 2025-09-05
CmpDate: 2025-09-05

Oguchi K, Munakata M, Hiruta C, et al (2025)

Intracellular Localization of the Bacterial Endosymbiont Cardinium in the Ostracod Heterocypris spadix.

Zoological science, 42(4):.

Symbiosis is a key driver of evolution in life-history traits and reproductive strategies. Some symbiotic microorganisms manipulate host reproduction to enhance their own transmission, a phenomenon well studied in insects but less understood in crustaceans. Among these microorganisms, Cardinium manipulates host reproductive systems, such as parthenogenesis, cytoplasmic incompatibility, and male killing in arthropods. However, its role in ostracods, small bivalve-shelled crustaceans, remains unclear. Some ostracod species reproduce via parthenogenesis, and high Cardinium infection rates in these lineages suggest a potential link between the symbiont and asexual reproduction. To investigate this relationship, we examined Cardinium localization in the parthenogenetic ostracod Heterocypris spadix from Japan. Using tissue clearing and fluorescence in situ hybridization (FISH), we visualized Cardinium within the ovaries. FISH observations revealed a widespread infection across the germarium, nurse cells, and oocytes. In early-stage oocytes, bacteria were evenly dispersed throughout the cytoplasm, whereas in more-developed oocytes, they clustered around the nucleus. Additionally, Cardinium was also detected in the hepatopancreas, indicating infection of both the reproductive and digestive systems. The presence of Cardinium in host reproductive structures, particularly the germarium, nurse cells, and developing oocytes, suggests its role in reproductive manipulation. To our knowledge, this study provides the first detailed localization of Cardinium in ostracods, reinforcing its potential influence on reproduction. Future research using antibiotics and genomic analysis will be crucial to confirm Cardinium's role in parthenogenesis induction.

RevDate: 2025-09-05

Yamlahi YE, Remmal I, Maurady A, et al (2025)

Characterization of the olive fly (Bactrocera oleae) microbiome across diverse geographic regions of Morocco.

Insect science [Epub ahead of print].

The olive fruit fly (Bactrocera oleae) is a significant pest threatening olive production worldwide. Bactrocera oleae relies on symbiotic bacteria for nutrition, development, and adaptation to its environment. Among these, Candidatus Erwinia dacicola is the most dominant symbiont and plays a key role in the fly's physiology and ecological adaptation. Understanding the dynamics between B. oleae, Ca. E. dacicola, and other components of the B. oleae microbiome is essential for developing effective targeted area-wide pest management strategies. This study aims to leverage full 16S rRNA gene sequencing to enhance the characterization of microbiome diversity in wild B. oleae populations from different regions in Morocco: Ouezzane, Rabat, Tanger, Errachidia, and Beni-Mellal. The results revealed distinct microbiome compositions influenced by geographic locations, with Candidatus Erwinia dacicola as the dominant symbiont, followed by Erwinia persicina as a secondary contributor. Other bacterial taxa, including Asaia bogorensis, were also identified, highlighting the functional diversity within the olive fly microbiome. These findings provide insights into the microbial ecology of B. oleae, contributing to the development and enhancement of sustainable pest control strategies.

RevDate: 2025-09-05

Afonso GVF, Johnson GD, Collins R, et al (2025)

Associations between fishes (Actinopterygii: Teleostei) and anthozoans (Anthozoa: Hexacorallia) in epipelagic waters based on in situ records.

Journal of fish biology [Epub ahead of print].

We formally describe the association of fishes and anthozoans in epipelagic waters, extending this relationship to beyond the benthos. In situ observations and photographs of Aluterus schoepfii, Ariomma regulus, Caranx cf. latus and Brama spp. swimming alongside or holding larval tube anemones (Cerianthidae and Arachnactidae) and larval zoanthids (Sphenopidae) were made during blackwater SCUBA dives off Palm Beach, Florida, USA, and off Punaauia, Tahiti, French Polynesia. We report and illustrate the behaviour of these interactions, and suggest an advantage for the anthozoans.

RevDate: 2025-09-04
CmpDate: 2025-09-04

Nishida H, Itakura M, Win KT, et al (2025)

Genetic design of soybean hosts and bradyrhizobial endosymbionts reduces N2O emissions from soybean rhizosphere.

Nature communications, 16(1):8023.

Soybeans fix atmospheric N2 through symbiosis with rhizobia. The relationship between rhizobia and soybeans, particularly those with high nitrous oxide (N2O)-reducing (N2OR) activities, can be leveraged to reduce N2O emissions from agricultural soils. However, inoculating soybeans with these rhizobia under field conditions often fails because of the competition from indigenous rhizobia that possess low or no N2OR activity. In this work, we utilize natural incompatibility systems between soybean and rhizobia to address this challenge. Specifically, Rj2 and GmNNL1 inhibit certain rhizobial infections in response to NopP, an effector protein. By combining a soybean line with a hybrid accumulation of the Rj2 and GmNNL1 genes and bradyrhizobia lacking the nopP gene, we develop a soybean-bradyrhizobial symbiosis system in which strains with high N2OR activity predominantly infect. Our optimize symbiotic system substantially reduces N2O emissions in field and laboratory tests, presenting a promising approach for sustainable agricultural practices.

RevDate: 2025-09-04

Zeng Q, Wang Z, Shen Z, et al (2025)

Microbiome Diversity and Dynamics in Lotus-Fish Co-Culture Versus Intensive Pond Systems: Implications for Sustainable Aquaculture.

Biology, 14(8): pii:biology14081092.

The lotus-fish co-culture (LFC) system leverages plant-fish symbiosis to optimize aqua-culture environments, enhancing both economic and ecological yields. However, the eco-logical mechanisms of microbial communities in LFC systems remain poorly understood, particularly regarding the functional roles of fungi, archaea, and viruses. This study compared microbiota (viruses, archaea, fungi) in water, sediment, and fish (crucian carp) gut of LFC and intensive pond culture (IPC) systems using integrated metagenomic and environmental analyses. Results demonstrated that LFC significantly reduced concentrations of total nitrogen, total phosphorus, and nitrite nitrogen and chemical oxygen demand in water, and organic matter and total nitrogen in sediment compared to IPC. Community diversity analysis, LefSe, and KEGG annotation revealed suppressed viral diversity in LFC, yet increased complexity and stability of intestinal virus communities compared to IPC. Archaeal and functional analyses revealed significantly enhanced ammonia oxidation and OM decomposition in LFC versus IPC, promoting methane metabolism equilibrium and sediment organic matter decomposition. Moreover, crucian carp intestines in LFC harbored abundant Methanobacteria, which contributed to maintaining a low hydrogen partial pressure, suppressing facultative anaerobes and reducing intestinal infection risk. The abundance of fungi in sediment and crucian carp intestine in LFC was significantly higher than that in IPC, showing higher ecological self-purification ability and sustainability potential in LFC. Collectively, LFC's optimized archaeal-fungal networks strengthened host immunity and environmental resilience, while viral community suppression reduced pathogen risks. These findings elucidate microbiome-driven mechanisms underlying LFC's ecological advantages, providing a framework for designing sustainable aquaculture systems through microbial community modulation.

RevDate: 2025-09-04

Makwarela TG, Seoraj-Pillai N, TC Nangammbi (2025)

Exploring the Molluscan Microbiome: Diversity, Function, and Ecological Implications.

Biology, 14(8): pii:biology14081086.

Mollusks are among the most ecologically and economically significant invertebrates; yet, their associated microbiomes remain understudied relative to those of other metazoans. This scoping review synthesizes the current literature on the diversity, composition, functional roles, and ecological implications of molluscan microbiomes, with an emphasis on three major groups: gastropods, bivalves, and cephalopods. Drawing on studies from terrestrial, freshwater, and marine systems, we identified the dominant bacterial phyla, including Proteobacteria, Bacteroidetes, and Firmicutes, and explored how microbiota vary across different habitats, diets, tissue types, and host taxonomies. We examined the contribution of molluscan microbiomes to host functions, including digestion, immune modulation, stress responses, and nutrient cycling. Particular attention was given to the role of microbiota in shell formation, pollutant degradation, and adaptation to environmental stressors. The review also evaluated microbial interactions at different developmental stages and under aquaculture conditions. Factors influencing microbiome assembly, such as the host's genetics, life history traits, and environmental exposure, were mapped using conceptual and graphical tools. Applications of molluscan microbiome research in aquaculture, conservation biology, and environmental biomonitoring are highlighted. However, inconsistencies in the sampling methods, taxonomic focus, and functional annotations limit the generalizability across taxa. We identify key knowledge gaps and propose future directions, including the use of meta-omics, standardized protocols, and experimental validation to deepen insights. By synthesizing emerging findings, this review contributes to a growing framework for understanding mollusk-microbiome interactions and their relevance to host fitness and ecosystem health. It further establishes the importance of mollusks as model systems for advancing microbiome science.

RevDate: 2025-09-04

Alcantar-Orozco EJ, Hernández-Elizárraga VH, Vega-Tamayo JE, et al (2025)

Comparative Proteomic Analysis of Non-Bleached and Bleached Fragments of the Hydrocoral Millepora complanata Reveals Stress Response Signatures Following the 2015-2016 ENSO Event in the Mexican Caribbean.

Biology, 14(8): pii:biology14081042.

The hydrocoral Millepora complanata (fire coral) plays a critical role in reef structure and relies on a symbiotic relationship with Symbiodiniaceae algae. Environmental stressors derived from climate change, such as UV radiation and elevated temperatures, disrupt this symbiosis, leading to bleaching and threatening reef survival. To gain insight into the thermal stress response of this reef-building hydrocoral, this study investigates the proteomic response of M. complanata to bleaching during the 2015-2016 El Niño event. Fragments from non-bleached and bleached colonies of the hydrocoral M. complanata were collected from a coral reef in the Mexican Caribbean, and proteomic extracts were analyzed using nano-liquid chromatography-tandem mass spectrometry (nano-LC-MS/MS). Uni- and multivariate analyses were applied to identify significant differences in protein abundance. A total of 52 proteins showed differential abundance, including 24 that showed increased expression and 28 whose expression decreased in bleached fragments. Differentially abundant proteins were associated with amino acid biosynthesis, carbohydrate metabolism, cytoskeleton organization, DNA repair, extracellular matrix composition, redox homeostasis, and protein modification. These molecular alterations reflect critical physiological adaptations that may influence stress sensitivity or tolerance in hydrocorals. The findings indicate that heat stress induces molecular responses involving protein refolding, enhanced vesicular transport, cytoskeletal reorganization, and modulation of redox activity. This contributes to a deeper understanding of the molecular mechanisms underlying bleaching in reef-building hydrozoans and broadens current knowledge beyond the more extensively studied anthozoan corals.

RevDate: 2025-09-04

Mohamed HI, Ullah I, Toor MD, et al (2025)

Heavy metals toxicity in plants: understanding mechanisms and developing coping strategies for remediation: a review.

Bioresources and bioprocessing, 12(1):95.

Heavy metal (HM) contamination is an increasing environmental and agricultural concern due to the persistence, toxicity, and bioaccumulative nature of metals such as cadmium (Cd), lead (Pb), mercury (Hg), and arsenic (As). These pollutants are primarily introduced through industrial effluents, mining, and agrochemicals, negatively impacting soil health, crop productivity, and food safety, ultimately posing serious risks to both ecosystems and human health. Conventional remediation methods can be costly, labor-intensive, and environmentally disruptive. Heavy metals like Cd, Pb, Hg, and As disrupt cellular homeostasis, inhibit photosynthesis, generate oxidative stress, and interfere with nutrient uptake, leading to significant yield losses in plants. In response to these stresses, plants utilize complex molecular mechanisms for tolerance, including the activation of antioxidant enzymes, upregulation of metal transporters, production of metal-chelating molecules, and modulation of stress-responsive genes and transcription factors. In contrast, bioremediation offers a sustainable and eco-friendly alternative by leveraging the detoxification capabilities of plants, microbes, and their symbiotic interactions. Techniques such as phytoremediation, microbial-assisted remediation, and integrated strategies involving biochar and organic amendments have demonstrated promising results in restoring heavy metal-contaminated soils. Recent advancements in molecular biology and synthetic biology have further improved the efficiency of bioremediation through the genetic engineering of hyperaccumulator plant species and metal-resistant microbes. This review examines the toxic effects of heavy metals on plants and highlights innovative, nature-based remediation strategies, emphasizing their potential for scalable and sustainable environmental cleanup.

RevDate: 2025-09-04

Basit A, Haq IU, Hyder M, et al (2025)

Microbial Symbiosis in Lepidoptera: Analyzing the Gut Microbiota for Sustainable Pest Management.

Biology, 14(8): pii:biology14080937.

Recent advances in microbiome studies have deepened our understanding of endosymbionts and gut-associated microbiota in host biology. Of those, lepidopteran systems in particular harbor a complex and diverse microbiome with various microbial taxa that are stable and transmitted between larval and adult stages, and others that are transient and context-dependent. We highlight key microorganisms-including Bacillus, Lactobacillus, Escherichia coli, Pseudomonas, Rhizobium, Fusarium, Aspergillus, Saccharomyces, Bifidobacterium, and Wolbachia-that play critical roles in microbial ecology, biotechnology, and microbiome studies. The fitness implications of these microbial communities can be variable; some microbes improve host performance, while others neither positively nor negatively impact host fitness, or their impact is undetectable. This review examines the central position played by the gut microbiota in interactions of insects with plants, highlighting the functions of the microbiota in the manipulation of the behavior of herbivorous pests, modulating plant physiology, and regulating higher trophic levels in natural food webs. It also bridges microbiome ecology and applied pest management, emphasizing S. frugiperda as a model for symbiont-based intervention. As gut microbiota are central to the life history of herbivorous pests, we consider how these interactions can be exploited to drive the development of new, environmentally sound biocontrol strategies. Novel biotechnological strategies, including symbiont-based RNA interference (RNAi) and paratransgenesis, represent promising but still immature technologies with major obstacles to overcome in their practical application. However, microbiota-mediated pest control is an attractive strategy to move towards sustainable agriculture. Significantly, the gut microbiota of S. frugiperda is essential for S. frugiperda to adapt to a wide spectrum of host plants and different ecological niches. Studies have revealed that the microbiome of S. frugiperda has a close positive relationship with the fitness and susceptibility to entomopathogenic fungi; therefore, targeting the S. frugiperda microbiome may have good potential for innovative biocontrol strategies in the future.

RevDate: 2025-09-04

Meesil W, Ardpairin J, Sharkey LKR, et al (2025)

Whole-Genome Sequencing and Biosynthetic Gene Cluster Analysis of Novel Entomopathogenic Bacteria Xenorhabdus thailandensis ALN 7.1 and ALN 11.5.

Biology, 14(8): pii:biology14080905.

Xenorhabdus species are entomopathogenic bacteria that live in symbiosis with Steinernema nematodes and produce a wide range of bioactive secondary metabolites. This study aimed to characterize the complete genomes and biosynthetic potential of two novel Xenorhabdus isolates, ALN7.1 and ALN11.5, recovered from Steinernema lamjungense collected in Northern Thailand. High-quality genome assemblies were generated, and phylogenomic comparisons confirmed that both isolates belonged to the recently described species Xenorhabdus thailandensis. The assembled genomes were approximately 4.02 Mb in size, each comprising a single circular chromosome with a GC content of 44.6% and encoding ~3800 protein-coding sequences, consistent with the features observed in other members of the genus. Biosynthetic gene cluster (BGCs) prediction using antiSMASH identified 19 BGCs in ALN7.1 and 18 in ALN11.5, including known clusters for holomycin, pyrrolizixenamide, hydrogen cyanide, and gamexpeptide C, along with several uncharacterized clusters, suggesting unexplored metabolic potential. Comparative analyses highlighted conserved yet strain-specific BGC profiles, indicating possible diversification within the species. These results provide genomic insights into X. thailandensis ALN7.1 and ALN11.5 and support their potential as valuable sources for the discovery of novel natural products and for future biotechnological applications.

RevDate: 2025-09-04

Zeng X, Chen J, Liu G, et al (2025)

Host Shaping Associated Microbiota in Hydrothermal Vent Snails from the Indian Ocean Ridge.

Biology, 14(8): pii:biology14080954.

Snails at hydrothermal vents rely on symbiotic bacteria for nutrition; however, the specifics of these associations in adapting to such extreme environments remain underexplored. This study investigated the community structure and metabolic potential of bacteria associated with two Indian Ocean vent snails, Chrysomallon squamiferum and Gigantopelta aegis. Using microscopic, phylogenetic, and metagenomic analyses, this study examines bacterial communities inhabiting the foot and gland tissues of these snails. G. aegis exhibited exceptionally low bacterial diversity (Shannon index 0.14-0.18), primarily Gammaproteobacteria (99.9%), including chemosynthetic sulfur-oxidizing Chromatiales using Calvin-Benson-Bassham cycle and methane-oxidizing Methylococcales in the glands. C. squamiferum hosted significantly more diverse symbionts (Shannon indices 1.32-4.60). Its black variety scales were dominated by Campylobacterota (67.01-80.98%), such as Sulfurovum, which perform sulfur/hydrogen oxidation via the reductive tricarboxylic acid cycle, with both Campylobacterota and Gammaproteobacteria prevalent in the glands. The white-scaled variety of C. squamiferum had less Campylobacterota but a higher diversity of heterotrophic bacteria, including Delta-/Alpha-Proteobacteria, Bacteroidetes, and Firmicutes (classified as Desulfobacterota, Pseudomomonadota, Bacteroidota, and Bacillota in GTDB taxonomy). In C. squamiferum, Gammaproteobacteria, including Chromatiales, Thiotrichales, and a novel order "Endothiobacterales," were chemosynthetic, capable of oxidizing sulfur, hydrogen, or iron, and utilizing the Calvin-Benson-Bassham cycle for carbon fixation. Heterotrophic Delta- and Alpha-Proteobacteria, Bacteroidetes, and Firmicutes potentially utilize organic matter from protein, starch, collagen, amino acids, thereby contributing to the holobiont community and host nutrition accessibility. The results indicate that host species and intra-species variation, rather than the immediate habitat, might shape the symbiotic microbial communities, crucial for the snails' adaptation to vent ecosystems.

RevDate: 2025-09-04

Haque MT, Paul S, Herberstein ME, et al (2025)

A parasitic or mutualistic conundrum: can symbiotic protists increase thermal tolerance in a semi-aquatic insect?.

Royal Society open science, 12(9):251061.

Rising temperatures and frequent heatwaves pose a major threat to ectotherms due to their reliance on environmental temperature for physiological processes. Thermal tolerance, the ability to withstand varying temperature, determines how effectively and efficiently individuals can survive under extreme conditions. Host-microbial symbiotic interactions can influence thermal tolerance in insects; however, we have limited information especially for some endosymbionts such as gregarines, a group of apicomplexan endoparasites, which are commonly found in the guts of many aquatic and terrestrial insects. Gregarines are often considered parasitic, while a few recent studies have shown beneficial effects on hosts. Here, we tested the impact of gregarines on thermal tolerance in Ischnura heterosticta damselflies. We found that damselflies naturally infected with gregarines had higher thermal tolerance than damselflies without gregarine infections. Our findings provide evidence in support of gregarines as an endosymbiont of I. heterosticta damselfly. Our study indicates that gregarine endosymbionts may assist damselfly and possibly other semi-aquatic insects to sustain extreme heat and highlights the importance of understanding host-symbiont interactions in the context of climate change and species conservation.

RevDate: 2025-09-04

Wei G, Li B, Huang M, et al (2025)

Polarization of Tumor Cells and Tumor-Associated Macrophages: Molecular Mechanisms and Therapeutic Targets.

MedComm, 6(9):e70372.

Tumor-associated macrophages (TAMs) are prominent constituents of solid tumors, and their prevalence is often associated with poor clinical outcomes. These highly adaptable immune cells undergo dynamic functional changes within the immunosuppressive tumor microenvironment (TME), engaging in reciprocal interactions with malignant cells. This bidirectional communication facilitates concurrent phenotypic transformation: tumor cells shift toward invasive mesenchymal states, whereas TAMs develop immunosuppressive, pro-tumorigenic traits. Increasing evidence highlights metabolic reprogramming, characterized by dysregulation of lipid metabolism, amino acid utilization, and glycolytic activity, as the fundamental molecular basis orchestrating this pathological symbiosis. However, a comprehensive understanding of how metabolic reprogramming specifically coordinates the mutual polarization of tumor cells and TAMs is lacking. This review thoroughly examines the molecular mechanisms governing this co-polarization process, detailing critical transcriptional regulators, essential signaling pathways, and the maintenance of adaptive phenotypes within the TME. Furthermore, this review critically assesses promising therapeutic strategies aimed at disrupting this alliance, including the use of metabolically targeted agents, engineered chimeric antigen receptor macrophages, and TAM-selective nanoparticle delivery systems. These insights provide a crucial foundation for the development of next-generation cancer immunotherapies focused on reprogramming pathological polarization dynamics to overcome treatment resistance and improve clinical outcomes.

RevDate: 2025-09-04
CmpDate: 2025-09-04

Liu JJ, Yu QX, Chen DH, et al (2025)

[Research progress in key technologies for the development of Dendrobium officinale: from a rare and endangered species to a 10-billion-RMB-level industry].

Zhongguo Zhong yao za zhi = Zhongguo zhongyao zazhi = China journal of Chinese materia medica, 50(13):3670-3678.

Dendrobium officinale(DO) is a traditional Chinese medicinal and edible plant, while it is critically endangered worldwide. This article, primarily based on the original research findings of the author's team and available articles, provides a comprehensive overview of the factors contributing to the endangerment of DO and the key technologies for the conservation, efficient cultivation, and value-added utilization of this plant. The scarcity of wild populations, low seed-setting rates, lack of endosperm in seeds, and the need for symbiosis with endophytic fungi for seed germination under natural conditions are identified as the primary causes for the rarity and endangerment of DO. Artificial seed production and tissue culture are highlighted as key technologies for alleviating the endangered status. The physiological and ecological mechanisms underlying the adaptation of DO to epiphytic growth are explored, and it is proposed that breaking the coupling of high temperature and high humidity is essential for preventing southern blight, a devastating affliction of DO. The roles of endophytic fungi in promoting the growth, improving the quality, and enhancing the stress resistance of DO are discussed. Furthermore, the integration of variety breeding, environment selection, and co-culture with endophytic fungi is emphasized as a crucial approach for efficient cultivation. The value-added applications of DO in pharmaceuticals, health foods, food products, and daily chemicals-particularly in the food and daily chemical industries-are presented as key drivers for a 10-billion-RMB-level industry. This systematic review offers valuable insights for the further development, utilization, and industrialization of DO resources, as well as for the broader application of conservation strategies for other rare and endangered plant species.

RevDate: 2025-09-04
CmpDate: 2025-09-04

Guo BL, C Pan (2025)

[Resource assessment as collaborative bridge: resolving dilemmas and fostering symbiosis in traditional Chinese medicine research and industry].

Zhongguo Zhong yao za zhi = Zhongguo zhongyao zazhi = China journal of Chinese materia medica, 50(13):3556-3560.

The research and development of new traditional Chinese medicine(TCM) drugs has entered a phase integrating high-quality development with resource assurance. Drawing from 18 new TCM drug registration resource assessment projects, this study systematically summarizes three core challenges in TCM resource management:(1) industrial chain complexity amplifies quantity-quality risks through material heterogeneity(multi-origin variations and wild-to-cultivated genetic shifts) and production chain coupling(germplasm-cultivation-processing whole-chain volatility);(2) structural misalignment among institutions, enterprises, and producers leads to disattachment of research and development from industrial demand;(3) technical barriers exist in quality control systems, involving producing area shift, cultivation evolution, and harvesting and processing innovations. This study proposes a four-dimensional assessment framework prioritizing "species stabilization, quantity availability, quality control, and quality optimization", which is supported by an early-warning system addressing multi-origin selection, adulterant control, endangered species protection, and standardized cultivation. Risk management strategies emphasize supply chain traceability, particularly for imported and ethnic medicinal materials. Using Epimedii Folium as a case study, this study demonstrates a tripartite industrial upgrade paradigm integrating premium germplasm, cultivation technology, and quality control, ultimately establishing an innovation mechanism with deep academia-industry collaboration. The research advocates transforming resource assessment from compliance checks to strategic decision-making tools through enhanced academia-industry collaboration, so as to provide resource assurance for high-quality TCM development.

RevDate: 2025-09-04

Yuan QS, Luo L, Shi H, et al (2025)

Fungal symbiont Mycena complements impaired nitrogen utilization in Gastrodia elata and supplies indole-3-acetic acid to facilitate its seed germination.

Plant communications pii:S2590-3462(25)00262-7 [Epub ahead of print].

Nitrogen and auxin uptake plays pivotal roles in seed germination and development. Gastrodia elata, a fully mycoheterotrophic plant, depends entirely on its symbiotic association with Mycena for early growth and seed germination. The process by which Mycena enables the supply of nitrogen nutrients and auxin, which are deficient in G. elata, remains poorly understood. In this study, a genome-scale dataset for G. elata revealed the loss of genes associated with nitrogen utilization and indole-3-acetic acid (IAA) biosynthesis, genes which were present in Mycena. Further evaluation of the dynamic transcriptomic interactions between G. elata seeds and Mycena at different symbiotic stages demonstrated that genes involved in nitrogen- and tryptophan-dependent IAA biosynthesis were significantly upregulated in Mycena. Concurrently, G. elata seeds exhibited increased expression of genes involved in the "hormone signal transduction pathway" and "starch and sucrose metabolism pathway." As representative enzymes in nitrogen assimilation and IAA biosynthesis pathways, functional disruption of nitrite reductase (MyNir, EVM0012344) and amidase (MyAmid, EVM0010270) in Mycena significantly impeded the symbiotic germination of G. elata seeds. This disruption interfered with the energy supply and caused cellular restructuring and hormonal signaling crosstalk. In conclusion, our findings provide novel insights into the mutualistic symbiotic relationship between Mycena and G. elata. Specifically, the fungus Mycena compensated for the incomplete nitrogen metabolism of its plant partner, G. elata, promoting seed germination. These results shed light on plant-fungal symbiotic associations from the perspective of nitrogen utilization.

RevDate: 2025-09-03

Liu J, Du C, Xu N, et al (2025)

A novel algae-assisted sequencing batch and intermittent air-lift bioreactor (A-SBIAB) using polyester filament-based carriers for piggery wastewater treatment.

Bioprocess and biosystems engineering [Epub ahead of print].

Algae-assisted biological wastewater treatment technology has been widely applied in wastewater treatment due to its low cost and great removal performance. However, the stabilization and sustainability of the alga-bacteria symbiosis system still need to be developed. In this work, an algae-assisted sequencing batch and intermittent air-lift bioreactor (A-SBIAB) system was constructed for removing the nutrients from the piggery wastewater. A strengthened algae-bacterial symbiosis system was also achieved with the aid of a suspended bio-carrier composed of polyester filament fixed on concentric plastic rings, which provided enhanced surface area and illumination access for microbial attachment. The removal efficiencies of chemical oxygen demand (COD), total nitrogen (TN) and total phosphorus (TP) were up to 92.0%, 81.7% and 89.3%, respectively, at the optimum parameters (Chl-a concentration of 1000 mg/m[3], light intensity of 6000 lx and lighting time 10 h). The Campylobacteria (72.05%), Desulfuromonadia (11.16%), Spirochaetia (3.10%) and Bacteroidia (1.73%) as the dominant bacterial communities would be responsible for the nitrate ammonification, nitrogen fixation, nitrate reduction and organics degradation, respectively. Meanwhile, Chlorophyceae (98.21%) became the overwhelming algal community, playing a positive effect on the nutrients removal.

RevDate: 2025-09-03
CmpDate: 2025-09-03

Laplanche V, Speciale I, De Castro C, et al (2025)

Cell surface polysaccharides in the gut microbiota: occurrence, structure and role.

Gut microbes, 17(1):2536082.

The gastrointestinal (GI) tract is colonized by trillions of microorganisms living in a symbiotic relationship with the host. Commensal bacteria in the gut engage in cross-talks with epithelial and immune cells through effector molecules secreted or attached to the cell surface. Although cell surface polysaccharides have mainly been studied in the context of pathogen-host interactions, these are increasingly being recognized as important factors of the symbiotic interaction between the gut microbiota and the host conferring biological activities and physiological functions. In this review, we focus on the structure and role of polysaccharides surrounding the bacterial cell wall, namely capsular polysaccharide (CPS) and cell wall polysaccharides (CWPS), both tightly linked to the cell surface, and exopolysaccharides (EPS) which are loosely attached to the extracellular surface or secreted into the environment. We will focus on structurally characterized CPS, CWPS and EPS from both gut commensal bacteria and food-derived bacteria found in the gut. These polysaccharides show high structural diversity and are important for the bacteria to adapt to the GI environment and/or influence host immune response. The combined diversity of microbes in the gut provides a vast array of glycans that could be harnessed to benefit human health.

RevDate: 2025-09-03
CmpDate: 2025-09-03

Kamyab A, D Samsampour (2025)

How thyme thrives under drought: insights into photosynthetic and membrane-protective mechanisms.

BMC biotechnology, 25(1):95.

BACKGROUND: Drought is an abiotic stress that significantly reduces the yield of thyme (Thymus vulgaris). This study investigated how iron oxide nanoparticles (FeNPs), together with symbiotic bacterial (Azospirillum lipoferum) and fungal (Aspergillus oryzae) endophytes, modulate osmotic adjustment, molecular and biochemical mechanisms related to photosynthesis, and drought tolerance mechanisms in thyme.

RESULTS: The experiment was evaluated as a factorial experiment in a completely randomized design with three replications. evaluating three treatment factors: four irrigation levels (100%, 75%, 50%, and 25% of field capacity), four FeNPs concentrations (0, 0.5, 1, and 1.5 mg L⁻¹), and three endophyte treatments (control, bacterial (EB), and fungal (EF) inoculation). At 25% FC, EB and spraying with 1 mg L[- 1] FeNPs increased Fv/Fm (maximum quantum efficiency of photosystem II), chlorophyll a, chlorophyll b, and total chlorophyll, carotenoids, relative water content (RWC), and protein levels level protein levels by 18.75%, 10.41%, 31.54%, 18.20%, 14.26%, 35.53%, and 125.22% respectively, compared to the control. At 25% FC, electrolyte leakage (EL) was increased by 47.44% with the combination of EF and 1.5 mg L[- 1] FeNPs. The highest proline accumulation at 25% FC was observed after inoculation with EF and 1 mg L[- 1] FeNPs, resulting in significant increases of 36.36% and 13.04%, respectively, compared to the control. Soluble sugar was remarkably increased by 28.57% under upon treatment with FeNPs (1.5 mg L[- 1] FeNPs). At 25% FC, EB and 1.5 mg L[- 1] FeNPs showed significant reductions of 17.33% and 37.10%, respectively, in malondialdehyde levels compared to control plants. At 50% FC, 1 mg L⁻¹ FeNPs increased Catalase by 15%, peroxidase by 31.25%, and superoxide dismutase by 43.42%, while higher concentrations reduced enzyme activities. Similarly, 1.5 mg L⁻¹ FeNPs and EB inoculation enhanced ascorbate peroxidase by 37.44% and 17.37%, respectively. FeNPs acted as abiotic stressors at low levels but became toxic at higher concentrations.

CONCLUSION: Our findings demonstrate that the synergistic application of FeNPs and endophytes significantly enhances drought tolerance in T. vulgaris by optimizing photosynthetic efficiency (Fv/Fm, chlorophyll content) and preserving membrane integrity (RWC, MDA reduction). These results provide a framework for leveraging nano-bio partnerships to improve crop resilience under water scarcity.

RevDate: 2025-09-02

Masoudi A, Joseph RA, NO Keyhani (2025)

Spatial organization within social ambrosia beetle nests limits spread of infectious disease.

iScience, 28(9):113281 pii:S2589-0042(25)01542-1.

Ambrosia beetles are social, fungal-farming insects that nest within tree xylem. Their close living conditions make them potentially vulnerable to microbial infectious diseases. We show that the insect pathogenic fungus Metarhizium anisopliae effectively infects and kills Xyleborus affinis adults, even within sawdust-based colony habitats. Healthy beetles did not avoid infected nestmates, and increased contact led to higher mortality and reduced offspring; however, larvae and pupae were still produced, even when colonies began with only infected beetles. Diseased individuals and Metarhizium CFUs were concentrated in the upper third of the nest, while surviving adults and brood were found in the middle/lower areas. A beetle symbiotic fungus, Neocosmospora sp. Xa1 was identified, which inhibited Metarhizium growth, potentially aiding in defense. Our findings suggest spatial structuring and microbial interactions within the nest help protect vulnerable brood to support colony persistence, revealing colony-level mechanisms that buffer against spread of infectious diseases, favoring offspring survival.

RevDate: 2025-09-02

De Santiago A, Barnes S, Pereira TJ, et al (2025)

Pseudoalteromonas is a novel symbiont of marine invertebrates that exhibits broad patterns of phylosymbiosis.

bioRxiv : the preprint server for biology pii:2025.08.22.671635.

Despite growing insights into the composition of marine invertebrate microbiomes, our understanding of their ecological and evolutionary patterns remains poor, owing to limited sampling depth and low-resolution datasets. Previous studies have provided mixed results when evaluating patterns of phylosymbiosis between marine invertebrates and marine bacteria. Here, we investigated potential animal-microbe symbioses in Pseudoalteromonas, an overlooked bacterial genus consistently identified as a core microbiome taxon in diverse invertebrates. Using a pangenomic analysis of 236 free-living and invertebrate-associated bacterial strains (including two new nematode-associated isolates generated in this study), we confirm that Pseudoalteromonas is a novel symbiont with substantial evidence of phylosymbiosis across at least three marine invertebrate phyla (e.g., Nematoda, Mollusca, and Cnidaria). Patterns of symbiosis were consistent irrespective of geography (including in Antarctica), with FISH images from nematodes indicating that bacterial symbionts form biofilms in the mouth and esophagus. The evolutionary history of Pseudoalteromonas is marked by substantial host-switching and lifestyle transitions, and host-associated genomes suggest that these bacteria are facultative symbionts involved in nutritional mutualisms. In marine environments, we hypothesize that horizontally-acquired symbionts may have co-evolved with invertebrates, using host mucus as a physical niche and food source, while providing their animal hosts with Vitamin B, amino acids, and bioavailable carbon compounds in return.

RevDate: 2025-09-02

Liu Z, Zhao X, Yang J, et al (2025)

Microbial removal mechanism of chromium and cadmium by humic acid-loaded nano zero-valent iron prepared by liquid-phase reduction method.

Frontiers in plant science, 16:1596063.

Heavy metal pollution is a global issue that has drawn significant attention due to its environmental and health risks. This thesis focuses on the research of highly toxic chromium and cadmium in the environment. It explores the removal mechanism of Cr and Cd contamination using humic acid-loaded nano-zero-valent iron (NZVI@HA) prepared through a liquid-phase reduction method. Additionally, it investigates the interaction mechanism of removing Cr and Cd contamination by synergizing with the Chromium and Cadmium Symbiotic Bacterial Colony (NZVI@HA+Cr/CdMC). The findings indicate that NZVI@HA exhibited optimal removal efficiency for Cr(VI) at pH=2 (85.7%) and Cd(II) at pH=8 (94.8%). The initial concentration of Cr and Cd pollution showed an inverse relationship with the removal rates of Cd(II) and Cr(VI). Moreover, the reaction temperatures were positively correlated with the removal rates of Cd(II) and Cr(VI). Cu2+ significantly enhanced Cr(VI) removal in the water column (p<0.01), whereas Zn2+ notably inhibited Cd(II) removal (p<0.05). In the NZVI@HA+Cr/CdMC system, extracellular polymers (EPS), tyrosine, and tryptophan, through van der Waals forces, facilitated the removal of Cd(II) and Cr(VI) complexation. This reduced the stress of Cr(VI) and Cd(II) on Cr/CdMC, thereby enhancing the removal of Cr(VI) and Cd(II).

RevDate: 2025-09-02

Lopez JV, Pomponi SA, Hentschel U, et al (2025)

The chromosomal genome sequence of the giant barrel sponge, Xestospongia muta Schmidt 1870 and its associated microbial metagenome sequences.

Wellcome open research, 10:336.

We present a genome assembly from a specimen of Xestospongia muta (Caribbean barrel sponge; Porifera; Demospongiae; Haplosclerida; Petrosiidae). The genome sequence has a total length of 158.52 megabases. Most of the assembly (99.56%) is scaffolded into 15 chromosomal pseudomolecules. The mitochondrial genome has also been assembled and is 18.99 kilobases in length. Several symbiotic bacterial genomes were assembled as MAGs, including Candidatus Poribacteria species, Candidatus Latescibacteria, Acidobacteriota, Actinomycetota Gemmatimonadota, multiple Chloroflexota and the archaeon Nitrosopumilus. Gene annotation of this assembly on Ensembl identified 20,220 protein-coding genes.

RevDate: 2025-09-02

Tayeh M, Sama-Ae I, Wisessombat S, et al (2025)

Antimigration and Anti-Invasion Properties of Aspergillus aculeatus Extract, an Endophyte Isolated From Capsicum annuum L. on Non-Small-Cell Lung Cancer Cells: In Vitro Experiments and In Silico Methods.

Scientifica, 2025:5676577.

Endophytic fungi are microorganisms that infect living plant tissues internally without producing obvious symptoms of infection, existing in a symbiotic relationship with plants for a portion of their life cycle. Currently, endophytic fungi serve as alternate sources for the production of new bioactive chemicals with great efficacy. This study aimed to examine the antimigration and anti-invasion capabilities of the endophytic fungus Aspergillus aculeatus extract, isolated from Capsicum annuum L., utilizing in vitro and in silico methods. This study isolated the endophytic fungus A. aculeatus from the leaves of C. annuum L. LC-MS analysis revealed fifty-five active components within the extract. Ten compounds exhibited favorable results in the in silico assessment. Computational predictions indicate that tajixanthone methanoate (-8.80 kcal/mol) and aspernigerin (-12.95 kcal/mol) exhibited high binding affinity against MMP-2. The A. aculeatus extract demonstrated antiproliferative activity with an IC50 value of 286.36 ± 122.57 μg/mL. The extract, at noncytotoxic concentrations, reduced the migration and invasion of A549 cells in a dose-dependent manner. Furthermore, A. aculeatus extract demonstrated a marked reduction in MMP-2 activity. According to these results, the compounds may serve as antimigration and anti-invasion agents by inhibiting the MMP-2 protein. The results demonstrated that A. aculeatus extract derived from C. annuum L. inhibited A549 cell migration and invasion via reducing MMP-2 activity. The findings indicated that A. aculeatus extract derived from C. annuum L. may be utilized for the treatment of lung cancer.

RevDate: 2025-09-02

Pandit SS, Meganathan P, H Vedagiri (2025)

Harmonizing gut microbiota dysbiosis: Unveiling the influence of diet and lifestyle interventions.

Metabolism open, 27:100384 pii:S2589-9368(25)00040-4.

The gut microbiota, comprising trillions of microorganisms inhabiting the gastrointestinal tract, is essential to human health and disease. Recent research has illuminated the interactions between many components of human physiology and the gut microbiota, including immune function, metabolism, and neurological health. Central to maintaining this symbiotic relationship is the concept of dysbiosis - an imbalance in the makeup and roles of the gut microbiota. Dysbiosis of the gut microbiota has emerged as a significant factor in the pathogenesis of numerous health conditions, spanning from gastrointestinal disorders like inflammatory bowel disease and irritable bowel syndrome to systemic diseases such as obesity, metabolic syndrome, and even neurological disorders like depression and anxiety. While dysbiosis can result from a myriad of factors including antibiotic use, stress, and genetic predispositions, emerging evidence suggests that diet and lifestyle choices exert profound influences regarding the make-up and capabilities of the gut microbiota. In this review, We explore the complex interactions among lifestyle, nutrition, and gut microbial dysbiosis. In particular, we investigate how the gut microbiota can be modified and dysbiosis can be mitigated by dietary patterns, food composition, prebiotics, probiotics, and lifestyle factors including exercise, stress reduction, and good sleep hygiene. Restoring microbial balance and enhancing general health and well-being can be achieved through preventive and therapeutic measures that can be made more effective by understanding how dietary and lifestyle changes might affect the gut microbiota. Through this exploration, we aim to elucidate the possibility of using lifestyle and dietary modifications as tools for managing gut microbial dysbiosis.

RevDate: 2025-09-02

Margarita V, Nguyen THT, Petretto GL, et al (2025)

Effect of essential oils from Cymbopogon citratus, Citrus grandis, and Mentha arvensis on Trichomonas vaginalis and role of its symbionts Mycoplasma hominis and Ca. Mycoplasma girerdii.

Frontiers in parasitology, 4:1610965.

INTRODUCTION: Trichomoniasis, the most common non-viral sexually transmitted disease, is caused by the protozoon Trichomonas vaginalis. T. vaginalis can establish a symbiosis with two bacteria, Mycoplasma hominis and Candidatus Mycoplasma girerdii, whose intracellular presence may modulate several characteristics of the protozoan, including its sensitivity to 5-nitroimidazoles, the only class of drugs currently effective in treating trichomoniasis. The rising prevalence of T.vaginalis strains resistant to metronidazole, the most commonly used antitrichomonal drug, underscores the need for therapeutic alternatives active against the protozoon.

METHODS: In this study, we evaluate the antimicrobial activity of essential oils extracted from three plants cultivated in Vietnam - Cymbopogon citratus, Citrus grandis, and Mentha arvensis - against thirty T. vaginalis strains isolated from symptomatic women in Italy and Vietnam. We also assess the influence of M. hominis and Ca. M. girerdii on T. vaginalis susceptibility to essential oils and metronidazole, through dedicated susceptibility assays. Additionally, given the importance of lactobacilli in maintaining vaginal health, we investigate the effects of the essential oils on Lactobacillus gasseri and Lactobacillus crispatus. The cytotoxic activity of the oils against HeLa cells was also tested in vitro.

RESULTS: All three essential oils showed effective antitrichomonal activity without inhibiting lactobacilli growth. Among them, C. citratus oil exhibited the strongest inhibitory effect on T. vaginalis, including strains harboring bacterial symbionts. Moreover, the oils demonstrated no cytotoxic activity against HeLa cells at the concentrations effective against the protozoan.

DISCUSSION: The results support the potential of C. citratus essential oil as a natural antitrichomonal agent. Its effectiveness against both free and symbiont-infected T. vaginalis strains positions it as a promising candidate for developing alternative therapies against drug-resistant trichomoniasis.

RevDate: 2025-09-02

Cheng P, Wang Z, Lu B, et al (2025)

Effect of different concentrations of gibberellins on antibiotics and nutrient removal using microalgae-bacteria consortia system.

International journal of phytoremediation [Epub ahead of print].

Phytohormone gibberellins (GAs) were utilized to enhance the removal of tetracycline antibiotics and nutrients from swine wastewater by different algal-bacterial symbiosis. Compared to microalgae monoculture, microalgae-activated sludge, and microalgae-Bacillus licheniformis, microalgae-endophytic bacteria showed better growth, photosynthetic, and purification performance. At 50 mg L[-1] GAs addition concentration, the specific growth rate of Chlorella vulgaris-endophytic bacterial (S395-2) system was 0.331 ± 0.03 d[-1], the maximum removal rate of tetracycline (TC), total nitrogen (TN) and total phosphorus (TP) was 96.31 ± 2.73%, 86.37 ± 8.31% and 87.26 ± 8.42%, respectively. The purification effect was much higher than the level of microalgae monoculture without GAs addition (TC removal of 81.33 ± 7.71%, TN and TP removal of 62.51 ± 5.95% and 64.25 ± 6.13%, respectively). In summary, exogenous GAs simultaneously promoted the resistance and biomass accumulation of algal symbiosis, which supplied a theoretical foundation for the treatment of high-concentration nutrients and antibiotics wastewater.

RevDate: 2025-09-02

McCauley M, Montesanto F, Bedgood SA, et al (2025)

Manipulation of the Symbiodiniaceae microbiome confers multigenerational impacts on symbioses and reproductive ecology of its Exaiptasia diaphana host.

The ISME journal pii:8245721 [Epub ahead of print].

Symbiodiniaceae-associated microbiota strongly affect cnidarian symbioses. We systematically reduced the bacterial and fungal communities associated with Symbiodiniaceae to study effects on the cnidarian holobiont Exaiptasia diaphana (Aiptasia). Clonal anemones were inoculated with xenic Breviolum minutum (SSB01) and microbiome manipulated cultures after antibacterial or antifungal treatment. The asexual reproduction of pedal laceration allowed for three generations of clonal aposymbiotic Aiptasia to be included in this study, from the initial adult generation (G0), to the first (G1) and second (G2) generation. We inoculated small and large G1 Aiptasia with algae and monitored onset of symbiosis, rate of algal proliferation, and holobiont characteristics. Sequencing the 16S and 18S rRNA gene regions identified significant differences in the bacterial and fungal communities of the G0 and G1 generations, alongside differences between the size classes of small and large G1 anemones. The microbiome of larger G1 individuals was distinct to the smaller G1 anemones, suggesting a microbiome maturation process. Control B. minutum cultures exhibited a significantly greater proliferation rate in large G1 anemones when compared to antibacterial or antifungal treated cultures, whereas the opposite trend was documented in the small G1 anemones. Although no differences were observed between algal photochemical parameters, or the growth and behavior of G1 juveniles, we observed a significant influence in the production of G2 clones between treatments. Overall, we provide strong ecological implications of manipulating Symbiodiniaceae microbiome, not for the algae themselves, but for the maturation of the host Aiptasia, as well as for the cnidarian holobiont over multiple generations.

RevDate: 2025-09-02

Zhou G, Ding M, Li X, et al (2025)

Genome Assembly of Elysia leucolegnote Reveals the Secrets of Autonomous Photosynthesis and Extraordinary Symbiotic Relationships in Photosynthetic Animals.

Plant, cell & environment [Epub ahead of print].

RevDate: 2025-09-02

Orosz J, Lin EX, Torres Ascurra YC, et al (2025)

CORYNE modulates Medicago truncatula inflorescence meristem branching and plays a conserved role in the regulation of arbuscular mycorrhizal symbiosis.

Journal of experimental botany pii:8245561 [Epub ahead of print].

The CLAVATA signaling pathway regulates plant development and plant-environment interactions. CLAVATA signaling consists of mobile, cell-type or environment-specific CLAVATA3/ESR-related (CLE) peptides, which are perceived by a receptor complex consisting of leucine-rich repeat receptor-like kinases such as CLAVATA1 and receptor-like proteins such as CLAVATA2, which often functions with the pseudokinase CORYNE (CRN). CLAVATA signaling has been extensively studied in various plant species for its developmental role in meristem maintenance. In addition, CLAVATA signaling was implicated in plant-microbe interactions, including root nodule symbiosis and plant interactions with mutualistic arbuscular mycorrhizal (AM) fungi. However, knowledge on AM symbiosis regulation by CLAVATA signaling is limited. Here, we report a dual role for Medicago truncatula CRN in development and plant-microbe interactions. In shoots, MtCRN modulates inflorescence meristem branching. In roots, the MtCRN promoter is active in vascular tissues and meristematic regions. In addition, MtCRN expression is activated in cortex cells colonized by AM fungi and negatively regulates root interactions with these microbes in a nitrogen-dependent manner; negative AM symbiosis regulation by CRN was also observed in the monocot Zea mays, suggesting this function is conserved across plant clades. We further report that MtCRN functions partially independently of the AM autoregulation signal MtCLE53. Transcriptomic data revealed that M. truncatula crn roots display signs of perturbed nutrient, symbiosis, and stress signaling, suggesting that MtCRN plays various roles in plant development and interactions with the environment.

RevDate: 2025-09-01
CmpDate: 2025-09-01

Chen MF, YZ Gao (2025)

Application of [15]N stable isotope techniques to biological nitrogen fixation in terrestrial ecosystems.

Ying yong sheng tai xue bao = The journal of applied ecology, 36(7):1952-1960.

Biological nitrogen fixation (BNF) is an important nitrogen source in terrestrial ecosystems. Accurate estimation of BNF rate is essential to accurately quantify atmospheric nitrogen input to natural ecosystems. [15]N natural abundance is commonly used to measure the BNF in symbiotic and associative nitrogen fixing plants, but are highly dependent on the choice of the reference plants. In contrast, the [15]N isotope labeling technique allows precise determination of BNF rates of symbiotic, free-living, and associative N-fixing types, and surpasses the previous methods in studying plant nitrogen fixation strategies, nitrogen transfer processes, and carbon-nitrogen trading between nodules and hosts. The [15]N isotope dilution method is mainly used for plant nitrogen fixation research. Although the [15]N stable isotope probe technique is technically challenging and expensive, it enables the detection and study of N-fixing microorganisms by labeling DNA or RNA, and provides an effective way for assessing asymbiotic microorganism nitrogen fixation rates. The development of [15]N stable isotope technique provides a strong technical guarantee for biological nitrogen fixation research.

RevDate: 2025-09-01
CmpDate: 2025-09-01

Petinger C, Crowley T, BV Wyk (2025)

Patterns of Transition of Adolescents in an HIV Care Programme in Peri-Urban Cape Town, South Africa: A Photovoice Study.

Journal of the International Association of Providers of AIDS Care, 24:23259582251362908.

Successful transition from paediatric to adult HIV care programme is a critical developmental milestone in the care trajectory of adolescents living with HIV (ALHIV). The transition process involves a shift from a structured, caregiver-supported healthcare model to one that requires independence and self-management. This process should be guided and supportive to ensure continued engagement in care and optimal adherence when ALHIV are transferred. This study utilised photovoice methods to explore the transition experiences of ALHIV in the Cape Town Metropole. Audio-recorded focus group data were transcribed verbatim and subjected to reflexive thematic analysis. Three distinctive patterns of behaviour from ALHIV were identified as themes. Type 1: socially reliant, dependent adolescent who heavily relies on family and peer support and struggles with adherence. Type 2: socially disconnected, hyper-independent adolescent, who is self-reliant, seeks solitude, and is generally resistant to external support. We configured a third (ideal) type, who is interdependent and able to self-manage their chronic condition, but within a supportive health care environment that provides positive healthcare and transition experiences. The findings underscore the need for supportive transition models promoting self-management skills, while facilitating a symbiotic relation with healthcare staff promoting sustained engagement in care well into adulthood. We recommend that adolescent or youth friendly services for ALHIV be expanded to support and monitor the transition process and outcomes in the adult HIV program.

RevDate: 2025-09-01

Yang H, Y Wang (2025)

From Fragmentation to Resolution: High-Fidelity Genome Assembly of Zancudomyces culisetae through Comparative Insights from PacBio, Nanopore, and Illumina Sequencing.

G3 (Bethesda, Md.) pii:8244970 [Epub ahead of print].

Zancudomyces culisetae is an obligate symbiotic fungus inhabiting the digestive tracts of aquatic insect larvae, including black flies, midges, and mosquitoes. With a global distribution and high prevalence in disease-transmitting insects, Z. culisetae serves as a model for studying insect gut fungi. A previous draft genome assembly using Illumina short reads provided insights into its genome composition, such as a low GC ratio and evidence of horizontal gene transfer. However, its fragmented nature has limited deeper exploration of the evolutionary mechanisms shaping these gut symbionts. To address this gap, we generated a wealth of genomic resources for Z. culisetae using multiple sequencing platforms, including Illumina, Oxford Nanopore, PacBio-CLR (Complete Long Reads), and PacBio-HiFi (High Fidelity). This also provides an opportunity to compare these popular sequencing methods to suggest the optimal approach for fungal genome assembly. Our results suggest that PacBio-HiFi produced the most complete assembly, yielding a 27.8 Mb genome size with 26 contigs, representing the highest-quality genome of insect gut fungi to date. Additionally, we generated transcriptomic data to support genome annotation, identifying 8,484 protein-coding genes. Despite the improved genome quality, Z. culisetae lacks approximately 20% of Benchmarking Universal Single-Copy Orthologue (BUSCO) commonly found in fungi, reflecting adaptations to its obligate symbiotic lifestyle. This study not only provides valuable genomic resources for insect gut fungal research but also evaluates the strengths and limitations of current genome sequencing and assembly approaches, offering best practices for fungal genome analysis and genetic research.

RevDate: 2025-08-30

Li L, Yang Q, Liu M, et al (2025)

Symbiotic bacteria mediate chemical-insecticide resistance but enhance the efficacy of a biological insecticide in diamondback moth.

Current biology : CB pii:S0960-9822(25)01035-8 [Epub ahead of print].

Insecticide resistance has been a major challenge for pest management worldwide. Here, we investigated how gut symbiotic bacteria in insects might affect resistance to chemical (organophosphate) and biological (Bacillus thuringiensis) insecticides in different ways to create opportunities for strategic pesticide rotations. Using the diamondback moth (Plutella xylostella) as the target pest, we demonstrated that long-term exposure to chlorpyrifos (an organophosphate insecticide) promotes the proliferation of the gut symbiont Enterococcus mundtii in P. xylostella populations, resulting in chlorpyrifos resistance in field populations across China that correlates closely with the abundance of this bacterium. Metabolic analysis revealed that E. mundtii can directly metabolize chlorpyrifos via a conserved cytochrome P450 enzyme in the genus Enterococcus. However, the accumulation of E. mundtii in the gut of chlorpyrifos-resistant populations may increase their susceptibility to Bacillus thuringiensis toxins, resulting in the increased efficacy of Bacillus thuringiensis in populations with high chemical insecticide resistance. The gut barrier disruption caused by Bacillus thuringiensis promotes invasion of E. mundtii from the gut into the hemolymph, leading to death by septicemia to enhance susceptibility. The study highlights an interaction between resistance to chemically synthesized and biological insecticides mediated by gut symbiotic bacteria and suggests a control strategy involving chemical/biological pesticide rotations that may apply to other cases of resistance to chemically synthesized insecticides.

RevDate: 2025-08-30

Grujcic V, Mehrshad M, Vigil-Stenman T, et al (2025)

Stepwise genome evolution from a facultative symbiont to an endosymbiont in the N2-fixing diatom-Richelia symbioses.

Current biology : CB pii:S0960-9822(25)01034-6 [Epub ahead of print].

A few genera of diatoms that form stable partnerships with N2-fixing filamentous cyanobacteria Richelia spp. are widespread in the open ocean. A unique feature of the diatom-Richelia symbioses is the symbiont cellular location spans a continuum of integration (epibiont, periplasmic, and endobiont) that is reflected in the symbiont genome size and content. In this study, we analyzed genomes derived from cultures and environmental metagenome-assembled genomes of Richelia symbionts, focusing on characters indicative of genome evolution. Our results show an enrichment of short-length transposases and pseudogenes in the periplasmic symbiont genomes, suggesting an active and transitionary period in genome evolution. By contrast, genomes of endobionts exhibited fewer transposases and pseudogenes, reflecting advanced stages of genome reduction. Pangenome analyses identified that endobionts streamline their genomes and retain most genes in the core genome, whereas periplasmic symbionts and epibionts maintain larger flexible genomes, indicating higher genomic plasticity compared with the genomes of endobionts. Functional gene comparisons with other N2-fixing cyanobacteria revealed that Richelia endobionts have similar patterns of metabolic loss but are distinguished by the absence of specific pathways (e.g., cytochrome bd ubiquinol oxidase and lipid A) that increase both dependency and direct interactions with their respective hosts. In conclusion, our findings underscore the dynamic nature of genome reduction in N2-fixing cyanobacterial symbionts and demonstrate the diatom-Richelia symbioses as a valuable and rare model to study genome evolution in the transitional stages from a free-living facultative symbiont to a host-dependent endobiont.

RevDate: 2025-08-30

Liu Y, Feng R, Zhao Y, et al (2025)

Solar-Mechano Symbiosis Dual-Mode Janus Bioaerogel for Context-Adaptive Atmospheric Water Harvesting Beyond Solar Reliance.

Advanced materials (Deerfield Beach, Fla.) [Epub ahead of print].

Solar-driven sorption-based atmospheric water harvesting (SS-AWH) offers promise for addressing global freshwater scarcity. However, the SS-AWH heavily relies on favorable and sustained solar irradiation; yet real-world solar irradiation exhibits significant spatiotemporal fluctuations, limiting its sustainable application, as non/low-light conditions sharply reduce water productivity. This constraint is fundamentally due to the singleness of the water release pathway via photothermal desorption. Here, a novel dual-mode bio-based Janus aerogel (DBJA) is presented, enabling efficient, all-weather, multi-scenario atmospheric water harvesting via selectively solar-driven and compression-activated water release. The Janus structure optimizes mass/heat transfer between hygroscopic and photothermal domains, achieving the most balanced adsorption-desorption kinetics and compression-recovery strength for solar-mechano symbiosis. Under favorable sunlight, DBJA demonstrates a competitive water release efficiency of 1.32 g g[-1] day[-1] outdoors. Crucially, without solar irradiation, DBJA achieves a total water productivity of 12.80 g g[-1] over 5-cycle adsorption-compression with 98% volume recovery and is stable within 50 cycles. Enhanced physical inlay and multiple chemical interactions ensure limited leakage of Li[+] ions during compression, and the collected water easily conforms to the World Health Organization (WHO) drinking water standards. This work provides a flexible approach for sustainable atmospheric water harvesting beyond solar reliance through multi-mode synergy and gradient architecture.

RevDate: 2025-08-29

Niu Z, Guo H, Li D, et al (2025)

Characterizing the Symbiotic Relationship between Wolbachia (wSpic) and Spodoptera picta (Lepidoptera: Noctuidae): From Genome to Phenotype.

Insect biochemistry and molecular biology pii:S0965-1748(25)00140-7 [Epub ahead of print].

Wolbachia is a genus of symbiotic bacteria prevalent in arthropods, with diverse effects on host reproduction and fecundity; however, it is unclear how Wolbachia modulates the host reproductive system. In this study, a novel Wolbachia strain, wSpic, was identified in the Noctuid moth Spodoptera picta and its effect on the reproduction of this host was investigated. We sequenced and annotated the 1,339,720 bp genome of wSpic. We identified a total of five WO phage regions in the genome and found no evidence of any plasmids associated with wSpic. Evolutionary analysis revealed that wSpic belongs to supergroup B and has undergone horizontal transmission between S. picta and Trichogramma pretiosum, a wasp parasitoid of insect eggs. The removal of Wolbachia by antibiotic treatment resulted in significantly decreased fecundity and abnormal development of S. picta ovaries, but no differences in egg hatching rate. An integrated transcriptome and proteome analysis indicated that major molecular pathways for Wolbachia-induced reproduction fitness benefits include its effects on insect juvenile hormone, vitellogenesis, choriogenesis, and nutritional metabolism. Our findings demonstrate that wSpic plays a critical role in promoting ovary development and sustaining fecundity in S. picta hosts.

RevDate: 2025-08-29

Wang K, Xu J, Luo X, et al (2025)

Insights into microalgal-bacterial consortia in sustaining denitrification via algal-derived organic matter in harsh low-C/N wastewater.

Journal of environmental management, 393:127108 pii:S0301-4797(25)03084-1 [Epub ahead of print].

Conventional nitrate removal processes are often hampered by insufficient carbon sources for remediating low-C/N wastewater. Herein, a microalgal-bacterial (MB) consortia system was constructed to leverage algal-derived organic matter for sustaining denitrification. The system demonstrated superior nitrate removal performance when assisted by algal-derived organic matter, achieving a 168.62 ± 4.17 % enhancement in nitrate removal capacity compared to the sole bacterial system. Furthermore, Fourier Transform Ion Cyclotron Resonance Mass Spectrometry (FT-ICR-MS) analysis of algal-derived organic matter revealed that specific components facilitating nitrate elimination included unsaturated aliphatic compounds, aliphatic/peptide-like/amino sugars, lignin-like, and tannin-like substances. Notably, the consortia showed preferential utilization of unsaturated aliphatic (35.21 %) and aliphatic/amino sugars over aliphatic/peptide-like/amino acids (31.05 %) and aliphatic/peptide-like compounds (31.31 %) within the CHO, CHON, CHON2, and CHON3 classes, respectively. Metagenomic analysis identified notable disparities in microbial community composition between the bacterial and MB consortia systems. Moreover, the MB consortia exhibited higher abundances of genes encoding nitrate removal enzymes, including those involved in denitrification, assimilatory/dissimilatory reduction, and L-glutamate synthesis pathways. Genes associated with lignin degradation were also detected, suggesting potential indirect contributions to nitrate elimination. Besides, the MB symbiotic microspheres were successfully fabricated and achieved efficient nitrate removal. These findings provide novel insights into the development of innovative MB symbiotic systems for nitrate removal under harsh carbon-limited conditions.

RevDate: 2025-08-29

Hu X, Li H, Liu A, et al (2025)

Editorial: Microbial symbiosis and infectious disease dynamics in reptiles and wildfowl.

Frontiers in microbiology, 16:1673344.

RevDate: 2025-08-29

Padilla-Serrato JG, Soriano-Honorato LD, Kuk-Dzul JG, et al (2024)

Rediscovery of Mesotheres unguifalcula (Glassell, 1936) (Crustacea: Brachyura: Pinnotheridae) with Remarks on the Symbiotic Relationship with its New Host, the Spindle Sea Snail Leucozonia cerata (W. Wood, 1828) (Mollusa: Gastropoda: Fasciolariidae).

Zoological studies, 63:e44.

The symbiotic pinnotherid crab Mesotheres unguifalcula was rediscovered in Acapulco Guerrero, Mexico, and was found infesting the spindle sea snail Leucozonia cerata (Fasciolaridae), a new host record for this crab. A total of 432 snails were collected in 2020, with a prevalence of 77%, well explained by the host width frequency. Monthly prevalence varied from 54% to 90%, and the mean intensity was 1.4 +/- 0.5 crabs per host. The sex ratio of snails was 1:1, and the crab did not prefer to infest males or females. The sex ratio of the crabs was positively skewed towards females. Crabs infested both small and large snails; however, most infested snails ranged between 20 and 40 mm in width. Prevalence increased with the host size: with hosts smaller than 30 mm experiencing an average of 53% infestation, while those from 30 mm to 52 mm averaged 93% infestation. The number of crabs by host varied from 1 to 3; solitary females and males were dominant (51%), followed by heterosexual couples (24%) and other combinations that included homosexual couples and triads, which barely represented 2%. Although there are many heterosexual couples, monogamy is ruled out due to the higher number of solitary males and females and the lower number of heterosexual couples compared to those statistically expected. The available evidence about the life history of Mesotheres unguialcula, like that of other studied species of the subfamily Pinnotherinae sensu stricto, suggests a pure-search polygynandry of sedentary females as its mating system (i.e., larger, solitary, and sedentary females, and smaller males who, in reproductive season, are roaming from one host to another in search of females receptive to copulation).

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ESP Quick Facts

ESP Origins

In the early 1990's, Robert Robbins was a faculty member at Johns Hopkins, where he directed the informatics core of GDB — the human gene-mapping database of the international human genome project. To share papers with colleagues around the world, he set up a small paper-sharing section on his personal web page. This small project evolved into The Electronic Scholarly Publishing Project.

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In 1995, Robbins became the VP/IT of the Fred Hutchinson Cancer Research Center in Seattle, WA. Soon after arriving in Seattle, Robbins secured funding, through the ELSI component of the US Human Genome Project, to create the original ESP.ORG web site, with the formal goal of providing free, world-wide access to the literature of classical genetics.

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Although the methods of molecular biology can seem almost magical to the uninitiated, the original techniques of classical genetics are readily appreciated by one and all: cross individuals that differ in some inherited trait, collect all of the progeny, score their attributes, and propose mechanisms to explain the patterns of inheritance observed.

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In reading the early works of classical genetics, one is drawn, almost inexorably, into ever more complex models, until molecular explanations begin to seem both necessary and natural. At that point, the tools for understanding genome research are at hand. Assisting readers reach this point was the original goal of The Electronic Scholarly Publishing Project.

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Usage of the site grew rapidly and has remained high. Faculty began to use the site for their assigned readings. Other on-line publishers, ranging from The New York Times to Nature referenced ESP materials in their own publications. Nobel laureates (e.g., Joshua Lederberg) regularly used the site and even wrote to suggest changes and improvements.

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When the site began, no journals were making their early content available in digital format. As a result, ESP was obliged to digitize classic literature before it could be made available. For many important papers — such as Mendel's original paper or the first genetic map — ESP had to produce entirely new typeset versions of the works, if they were to be available in a high-quality format.

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Early support from the DOE component of the Human Genome Project was critically important for getting the ESP project on a firm foundation. Since that funding ended (nearly 20 years ago), the project has been operated as a purely volunteer effort. Anyone wishing to assist in these efforts should send an email to Robbins.

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With the development of methods for adding typeset side notes to PDF files, the ESP project now plans to add annotated versions of some classical papers to its holdings. We also plan to add new reference and pedagogical material. We have already started providing regularly updated, comprehensive bibliographies to the ESP.ORG site.

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