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Bibliography on: CRISPR-Cas

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ESP: PubMed Auto Bibliography 17 Jul 2025 at 01:42 Created: 

CRISPR-Cas

Clustered regularly interspaced short palindromic repeats (CRISPR, pronounced crisper) are segments of prokaryotic DNA containing short repetitions of base sequences. Each repetition is followed by short segments of "spacer DNA" from previous exposures to foreign DNA (e.g a virus or plasmid). The CRISPR/Cas system is a prokaryotic immune system that confers resistance to foreign genetic elements such as those present within plasmids and phages, and provides a form of acquired immunity. CRISPR associated proteins (Cas) use the CRISPR spacers to recognize and cut these exogenous genetic elements in a manner analogous to RNA interference in eukaryotic organisms. CRISPRs are found in approximately 40% of sequenced bacterial genomes and 90% of sequenced archaea. By delivering the Cas9 nuclease complexed with a synthetic guide RNA (gRNA) into a cell, the cell's genome can be cut at a desired location, allowing existing genes to be removed and/or new ones added. The Cas9-gRNA complex corresponds with the CAS III crRNA complex in the above diagram. CRISPR/Cas genome editing techniques have many potential applications, including altering the germline of humans, animals, and food crops. The use of CRISPR Cas9-gRNA complex for genome editing was the AAAS's choice for breakthrough of the year in 2015.

Created with PubMed® Query: ( "CRISPR.CAS" OR "crispr/cas" ) NOT pmcbook NOT ispreviousversion

Citations The Papers (from PubMed®)

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RevDate: 2025-07-16
CmpDate: 2025-07-16

Valcárcel G, Lazarenkov A, López-Rubio AV, et al (2025)

Modulating immune cell fate and inflammation through CRISPR-mediated DNA methylation editing.

Science advances, 11(29):eadt1644.

Immune cell differentiation and activation are associated with widespread DNA methylation changes; however, the causal relationship between these changes and their impact in shaping cell fate decisions still needs to be fully elucidated. Here, we conducted a genome-wide analysis to investigate the relationship between DNA methylation and gene expression at gene regulatory regions in human immune cells. By using CRISPR-dCas9-TET1 and -DNMT3A epigenome editing tools, we successfully established a cause-and-effect relationship between the DNA methylation levels of the promoter of the interleukin-1 receptor antagonist (IL1RN) gene and its expression. We observed that modifying the DNA methylation status of the IL1RN promoter is sufficient to alter human myeloid cell fate and change the cellular response to inflammatory and pathogenic stimuli. Collectively, our findings demonstrate the potential of targeting specific DNA methylation events to directly modulate immune and inflammatory responses, providing a proof of principle for intervening in a broad range of inflammation-related diseases.

RevDate: 2025-07-16

Yang X, Fan Y, Xu X, et al (2025)

Direct Testing of Blood Samples to Diagnose Bloodstream Infections.

ACS infectious diseases [Epub ahead of print].

Bloodstream infection (BSI) is a critical condition with extremely high mortality. Rapid and accurate diagnosis is crucial for effective treatment. The traditional blood culture (BC) method has issues, such as long testing times and limited sensitivity, making it challenging to meet the need for timely diagnosis. To address this problem, various molecular biology methods for directly detecting blood samples (whole blood, plasma, serum, and positive BC samples) have emerged. These include Raman spectroscopy, mass spectrometry, nucleic acid amplification, and hybridization techniques (such as the CRISPR/Cas system, digital droplet PCR (ddPCR), and T2 magnetic resonance (T2MR)), biosensors, and next-generation sequencing (NGS). These methods can quickly identify pathogens and their drug-resistant markers, significantly reducing diagnostic delays and helping to provide earlier targeted treatment. This article systematically analyzes the principles, advantages, and disadvantages of these advanced techniques, explores their value in revolutionizing the BSI diagnostic model, and looks ahead to future development directions, providing a reference for research and clinical applications in this field.

RevDate: 2025-07-16
CmpDate: 2025-07-16

Wu X, Luteijn RD, Lozano-Andrés E, et al (2025)

Identification of β4GALNT2 as an anti-hPIV3 factor through genome-wide CRISPR/Cas9 library screening.

Emerging microbes & infections, 14(1):2529895.

Human respirovirus 3 (also known as human parainfluenza virus 3; hPIV3) is a major cause of severe acute respiratory infections in vulnerable populations. Here we conducted a genome-wide CRISPR/Cas9 library screen to identify key host factors for hPIV3 infection. In addition to identifying several host proteins involved in glycosylation as proviral factors, we identified β-1,4-N-Acetyl-Galactosaminyltransferase 2 (β4GALNT2) as a potent restriction factor. Further investigation demonstrated that the addition of a GalNAc residue to α2-3-sialylated glycans by β4GALNT2, resulting in the Sd[a] glycotope, disrupted the interaction between the viral hemagglutinin-neuraminidase (HN) attachment protein and sialoglycan receptors. Specifically, the additional GalNAc residue interfered with the interaction of residue W371 in HN with sub-terminal glycan moieties. β4GALNT2-mediated Sd[a] epitope expression also negatively affected infection by other respiroviruses, with the strongest effect being observed for hPIV3.

RevDate: 2025-07-16
CmpDate: 2025-07-16

Shao F, Zhou Y, Shi J, et al (2025)

Establishment and Application of Mice Models for Tracing Gene Expression and Protein Product of TNF.

Biotechnology journal, 20(7):e70080.

Tumor necrosis factor α (TNF-α) is a pleiotropic cytokine crucial for immune function, cellular homeostasis, and disease progression, yet its complex roles in vivo remain unclear. Challenges in studying TNF-α include its widespread gene expression, variability in expression levels, diverse protein forms, and low baseline expression, which complicate traditional detection and tracking methods. To address these challenges, we constructed three distinct transgenic luciferase reporter mouse models (TNF-IRES-Luc, TNF-Nanoluc, and TNF-HiBiT) driven by the endogenous TNF-α gene, using CRISPR/Cas9 technology through homology-directed repair. The firefly luciferase gene, secreted NanoLuc gene, and HiBiT gene were individually integrated into the mouse genome under the control of the endogenous TNF-α promoter. Our results demonstrate that endogenous TNF-α expression can be effectively monitored by measuring luciferase levels in vivo and in vitro, using an in vivo imaging system and a luminometer. This was validated during inflammatory processes such as lipopolysaccharide (LPS)-induced sepsis and phorbol ester (TPA)-induced mouse ear edema. Furthermore, the anti-inflammatory drug dexamethasone (DXM) significantly inhibited TNF-α and luciferase expression in both inflammatory models. Our study demonstrates these mouse models are valuable tools for studying TNF-α expression in inflammatory responses and related diseases, as well as evaluating anti-inflammatory drug efficacy.

RevDate: 2025-07-15
CmpDate: 2025-07-16

Wongborisuth C, Innachai P, Saisawang C, et al (2025)

Disrupting ZBTB7A or BCL11A binding sites reactivates fetal hemoglobin in erythroblasts from healthy and β[0]-thalassemia/HbE individuals.

Scientific reports, 15(1):25580.

CRISPR/Cas9 genome editing has emerged as a promising treatment for genetic diseases like β-thalassemia. Editing γ-globin promoters to disrupt ZBTB7A/LRF or BCL11A binding sites has shown potential for reactivating fetal hemoglobin and treating sickle cell disease. However, its application to β[0]-thalassemia/HbE disease remains unclear. This study utilized CRISPR/Cas9 to disrupt these sites in mobilized CD34 + hematopoietic stem /progenitor cells from healthy donors and β[0]-thalassemia/HbE patients. The editing efficiency for the BCL11A site (75-92%) was higher than for the ZBTB7A/LRF site (57-60%). Both disruptions similarly increased fetal hemoglobin production in healthy donors (BCL11A 26.2 ± 1.4%, ZBTB7A/LRF 27.9 ± 1.5%) and β[0]-thalassemia/HbE cells (BCL11A 62.7 ± 0.9%, ZBTB7A/LRF 64.0 ± 1.6%). Off-target effects were absent in BCL11A-edited cells but observed at low frequencies in ZBTB7A/LRF-edited cells. Neither disruption significantly affected erythroid differentiation. These findings highlight the comparable contributions of ZBTB7A/LRF and BCL11A binding sites to γ-globin reactivation. CRISPR/Cas9 editing of either site may offer a potential therapeutic strategy for β[0]-thalassemia/HbE disease.

RevDate: 2025-07-16
CmpDate: 2025-07-16

Guler Kara H, Dogan E, Bozok V, et al (2025)

The G protein-coupled receptor GPR89A is a novel potential therapeutic target to overcome cisplatin resistance in NSCLC Calu1 cells.

The FEBS journal, 292(14):3755-3770.

Lung cancer is the most frequently diagnosed cancer type worldwide and is characterised by its high metastatic potential. Standard therapy for nonsmall cell lung cancer (NSCLC) cases includes chemotherapy with the platinum-based chemotherapeutic agent cisplatin. Although lung cancer cases respond well to cisplatin at the beginning of treatment, ~ 60% develop chemotherapy resistance during this process. In this study, a genome-wide CRISPR-Cas9-based genetic screening approach was employed to identify genes that cisplatin-resistant NSCLC Calu1 cells are more addicted to than sensitive cells. Cisplatin-resistant Calu1 cells were generated by the dose escalation method, and genome-wide CRISPR-Cas9-based genetic screening was performed with the Brunello CRISPR knockout library. Bioinformatics analyses of the obtained next-generation sequencing data revealed 63 potential candidate genes responsible for cisplatin resistance, including G protein-coupled receptor 89A (GPR89A), Poly(U) binding splicing factor 60 (PUF60), NBAS subunit of NRZ tethering complex (NBAS) and GrpE like 1, mitochondrial (GRPEL1). The GPR89A protein is located in the Golgi cisterna and Golgi-associated vesicle membrane, enables voltage-gated anion channel activity, and is involved in intracellular pH reduction. Functional studies carried out with GPR89A-knockout cisplatin-resistant Calu1 cells resulted in cell cycle arrest in the G2/M phase and increased polyploidy, and also prevented colony formation and cell migration. Cisplatin treatment, on the other hand, resulted in increased cell death by apoptosis upon cell cycle arrest in the S phase. In conclusion, this is the first study that identified GPR89A as a potential therapeutic target to overcome cisplatin resistance in NSCLC Calu1 cells.

RevDate: 2025-07-15
CmpDate: 2025-07-15

Besati M, Safarnejad MR, Aliahmadi A, et al (2025)

Detection of tomato brown rugose fruit virus through CRISPR-Cas12a and CRISPR-Cas9 systems.

Scientific reports, 15(1):25638.

Tomato brown rugose fruit virus (ToBRFV) is a single-stranded positive-sense RNA virus that targets tomato and pepper plants and is causing significant damage to crops in some regions of the world. ToBRFV is a highly contagious virus that is stable and rapidly spreads by mechanical methods and seeds. As a result, it may spread both locally and over long distances, and it is now recognized as a pandemic in plants. This study investigates the effectiveness of the systems CRISPR-Cas12a and CRISPR-Cas9, in conjugation with recombinase polymerase amplification (RPA), to detect ToBRFV in tomato plant samples collected from the field. The trans-cleavage activity of both nucleases, Cas12a and Cas9, was exploited to process a probe labelled with fluorescein and biotin to be resolved on a lateral flow device, thereby enabling a visual readout. We were able to detect the RNA genome of the virus in about 1 h at a low constant temperature. These results could pave way to offer a rapid, sensitive, and specific method for on-site detection of ToBRFV.

RevDate: 2025-07-15
CmpDate: 2025-07-15

Chen H, Tan Q, Li L, et al (2025)

Refined DNA repair manipulation enables a universal knock-in strategy in mouse embryos.

Nature communications, 16(1):6502.

The design and screening of sgRNA in CRISPR-dependent gene knock-in is always laborious. Therefore, a universal and highly efficient knock-in strategy suitable for different sgRNA target sites is necessary. In our mouse embryo study, we find that the knock-in efficiency guided by adjacent sgRNAs varies greatly, although similar indel frequency. MMEJ-biased sgRNAs usually lead to high knock-in efficiency, whereas NHEJ-biased sgRNAs result in low knock-in efficiency. Blocking MMEJ repair by knocking down Polq can enhance knock-in efficiency, but inhibiting NHEJ repair shows variable effects. We identify a compound, AZD7648, that can shift DSBs repair towards MMEJ. Finally, by combining AZD7648 treatment with Polq knockdown, we develop a universal and highly efficient knock-in strategy in mouse embryos. This approach is validated at more than ten genomic loci, achieving up to 90% knock-in efficiency, marking a significant advancement toward predictable and highly efficient CRISPR-mediated gene integration.

RevDate: 2025-07-15

Lau CH, Liang QL, Chen X, et al (2025)

CRISPR/Dx-based colorimetric and electrochemical detection systems for POCT applications.

Biosensors & bioelectronics, 288:117778 pii:S0956-5663(25)00654-2 [Epub ahead of print].

To realize point-of-care testing (POCT) for human diseases, CRISPR/Cas technology has been integrated with commercial analytical devices and chromogenic substrates such as personal glucose meter (PGM), pregnancy test strips (PTS), and horseradish peroxidase (HRP). These integrated detection platforms enable portable diagnostics, economical, universal, rapid, and high throughput detection. The change in color and electrochemical signal enables visible signal readout and intuitive results without specialized equipment and skillful operators. Herein, we comprehensively and critically discuss these advancements and describe the molecular principles of each detection system. The current challenges and technical shortcomings associated with these CRISPR-based diagnostics for POCT applications are discussed. We also provide future perspectives and directions in this field that will improve the performance of CRISPR-PGM, CRISPR-PTS, and CRISPR-HRP for pathogens detection and molecular diagnostics. Their applications in early tumor detection and pan-cancer screening are highlighted. The potential ethical and societal impact of home self-tests for cancer are discussed.

RevDate: 2025-07-15
CmpDate: 2025-07-15

Carmichael JC, Stevens CS, Atanasoff KE, et al (2025)

Precision engineering of human cytomegalovirus without BAC constraints: a Sendai virus-delivered CRISPR/Cas9 approach.

The Journal of general virology, 106(7):.

Human cytomegalovirus (HCMV) genetic manipulation traditionally relies on bacterial artificial chromosome (BAC) recombineering, necessitated by its large ~236 kb genome. This approach is limited by the scarcity of HCMV strains engineered into BACs and often requires the deletion of 'non-essential' genes to accommodate the BAC cassette. We developed a novel approach using temperature-sensitive Sendai virus (SeV) vectors to deliver CRISPR/Cas9 for targeted HCMV genome editing without these constraints. This system achieves high editing efficiency (80-90%) in fibroblasts, epithelial cells and endothelial cells without BAC intermediates. As proof of principle, we targeted the HCMV (TB40/E strain) pentamer complex (PC) genes UL128 and UL130, crucial for viral entry into non-fibroblast cells. Edited viruses showed significantly reduced infectivity in epithelial cells, confirming functional disruption of the PC. Plaque purification yielded isogenic clones with phenotypes comparable to AD169, a naturally PC-deficient strain. Furthermore, multiplexed editing created precise 663 bp deletions in over 60% of viral genomes. Importantly, this method enables HCMV editing in physiologically relevant cell types without fibroblast passaging, which typically introduces mutations. This SeV-Cas9 system represents a significant advancement for studying HCMV biology in diverse cell types.

RevDate: 2025-07-15
CmpDate: 2025-07-15

Tao S, Fang Y, Zheng L, et al (2025)

Mechanistic study of the immune defense function of the CRISPR1-Cas system in Enterococcus faecalis.

Virulence, 16(1):2530665.

Enterococci are Gram-positive cocci that are considered to be one of the causative agents of hospital-acquired infections. CRISPR-Cas is an adaptive immune system with targeted defense functions against foreign invading nucleic acids and plays an important role in antibiotic resistance. In this study, we aimed to investigate II-A CRISPR-Cas-mediated immunity and the molecular mechanism underlying the horizontal transfer of drug resistance genes in Enterococcus faecalis. The mutant strains were constructed by the homologous recombination strategy. The interference of plasmid transformation by the Enterococcus faecalis CRISPR1/Cas system was confirmed through plasmid transformation efficiency. The different mutation positions in the protospacer sequence S1 and PAM region recombinant plasmids were constructed through enzyme digestion and sequencing verification to assess the impact of the CRISPR-encoded immunity. In the wild-type strain, the transformation efficiency of plasmids pAT28-S1-S9 containing protospacers and PAM sites decreased (p < 0.05). Single-base mutations at positions 25 and 28 of the protospacer region eliminated the ability of the wild-type strain to prevent plasmid transformation containing the protospacer and PAM sites (p > 0.05), whereas a single mismatch at protospacer positions 2,10,18,23 did not affect the ability of CRISPR-Cas system-positive strains to interfere with plasmid transformation (p < 0.05). There was no significant difference between the wild-type strain and the mutant strain in the transformation efficiency of the pS1-pΔPAM plasmid without PAM and plasmids containing single mutations (p > 0.05). In conclusion, the CRISPR-Cas system can block the transformation of matching protospacer sequences, and mutations near or within the protospacer adjacent motif (PAM) allow the plasmid to escape CRISPR-encoded immunity.

RevDate: 2025-07-15
CmpDate: 2025-07-15

Yerlikaya BA, Yerlikaya S, Gül B, et al (2025)

Harnessing CRISPR/Cas9 in engineering biotic stress immunity in crops.

Planta, 262(3):54.

There is significant potential for CRISPR/Cas9 to be used in developing crops that can adapt to biotic stresses such as fungal, bacterial, viral, and pest infections and weeds. The increasing global population and climate change present significant threats to food security by putting stress on plants, making them more vulnerable to diseases and productivity losses caused by pathogens, pests, and weeds. Traditional breeding methods are inadequate for the rapid development of new plant traits needed to counteract this decline in productivity. However, modern advances in genome-editing technologies, particularly CRISPR/Cas9, have transformed crop protection through precise and targeted modifications of plant genomes. This enables the creation of resilient crops with improved resistance to pathogens, pests, and weeds. This review examines various methods by which CRISPR/Cas9 can be utilized for crop protection. These methods include knocking out susceptibility genes, introducing resistance genes, and modulating defense genes. Potential applications of CRISPR/Cas9 in crop protection involve introducing genes that confer resistance to pathogens, disrupting insect genes responsible for survival and reproduction, and engineering crops that are resistant to herbicides. In conclusion, CRISPR/Cas9 holds great promise for advancing crop protection and ensuring food security in the face of environmental challenges and increasing population pressures. The most recent advancements in CRISPR technology for creating resistance to bacteria, fungi, viruses, and pests are covered here. We wrap up by outlining the most pressing issues and technological shortcomings, as well as unanswered questions for further study.

RevDate: 2025-07-15
CmpDate: 2025-07-15

Maillard M, Nishii R, Vu HS, et al (2025)

The NUDIX hydrolase NUDT5 regulates thiopurine metabolism and cytotoxicity.

The Journal of clinical investigation, 135(14): pii:190443.

Thiopurines are anticancer agents used for the treatment of leukemia and autoimmune diseases. These purine analogs are characterized by a narrow therapeutic index because of the risk of myelosuppression. With the discovery of NUDIX hydrolase 15 (NUDT15) as a major modulator of thiopurine metabolism and toxicity, we sought to comprehensively examine all members of the NUDIX hydrolase family for their effect on the pharmacologic effects of thiopurine. By performing a NUDIX-targeted CRISPR/Cas9 screen in leukemia cells, we identified NUDT5, whose depletion led to drastic thiopurine resistance. NUDT5 deficiency resulted in a nearly complete depletion of active metabolites of thiopurine and the loss of thioguanine incorporation into DNA. Mechanistically, NUDT5 deletion resulted in substantial alteration in purine nucleotide biosynthesis, as determined by steady-state metabolomics profiling. Stable isotope tracing demonstrated that the loss of NUDT5 was linked to a marked suppression of the purine salvage pathway but with minimal effects on purine de novo synthesis. Finally, we comprehensively identified germline genetic variants in NUDT5 associated with thiopurine-induced myelosuppression in 582 children with acute lymphoblastic leukemia. Collectively, these results pointed to NUDT5 as a key regulator of the thiopurine response primarily through its effects on purine homeostasis, highlighting its potential to inform individualized thiopurine therapy.

RevDate: 2025-07-15

Mestanza M, Hernández-Amasifuen AD, Pineda-Lázaro AJ, et al (2025)

Genome editing for sustainable agriculture in Peru: advances, potential applications and regulation.

Frontiers in genome editing, 7:1611040.

Peruvian agriculture is characterize by crops such as potato, maize, rice, asparagus, mango, banana, avocado, cassava, onion, oil palm, chili, papikra, blueberry, coffee, cacao, grapes, quinoa, olive, citrus and others. All of them have challenges in production in their specific agroecosystems under stress due to pests, diseases, salinity, drought, cold among others. Gene editing through CRISPR/Cas is a key tool for addressing critical challenges in agriculture by improving resilience to biotic and abiotic stress, increasing yield and enhancing the nutritional value of the crops. This approach allows precise mutation on site-specific gene at the DNA level, obtaining desirable traits when its function is altered. The CRISPR/Cas system could be used as a transgene-free genome editing tool when the ribonucleoprotein (RNP) acts as a carrier to delivered the CRISPR/Cas components into the plant cell protoplasts, or when the tRNA-like sequence (TLS) motifs are fused to single-guide RNA (sgRNA) and Cas mRNA sequence and expressed in transgenic plants rootstock to produce "mobile" CRISPR/Cas components to upper tissue (scion). Those innovations could be a potential approach to strengthen the Peruvian agriculture, food security and gricultural economy, especially in the tropical, Andean and coastal regions. This review article examines the advances and strategies of gene editing, focusing on transgene-free methodologies that could be adopted for research, development and use, and also identifies potential applications in key crops for Peru and analyzes their impact in the productivity and reduction of agrochemicals dependence. Finally, this review highlights the need to establish regulatory policies that strengthen the use of biotechnological precise innovations, ensuring the conservation and valorization of agrobiodiversity for the benefit of Peruvian farmers.

RevDate: 2025-07-15

Shentu TP, Wu T, Zhou Z, et al (2025)

Mechanosensitive Endothelial METTL7A Regulates Internal m [7] G mRNA Methylation and Protects Against Atherosclerosis.

bioRxiv : the preprint server for biology pii:2025.05.22.655328.

BACKGROUND: Internal N [7] -methylguanosine (m [7] G) is a recently identified chemical modification of mammalian mRNA and a component of the epitranscriptome. While the epitranscriptome plays a key role in regulating RNA metabolism and cellular function, the specific contribution of internal m [7] G to cardiovascular health and disease remains unknown. Atherosclerosis preferentially develops at sites where disturbed blood flow activates endothelial cells, but whether internal m [7] G and its regulatory machinery influence endothelial mechanotransduction and atherogenesis is unclear.

METHODS: We integrated epitranscriptomic profiling, human tissue analysis, genetically modified mouse models, and targeted nanomedicine approaches to investigate the role of Methyltransferase-like protein 7A (METTL7A), a putative internal m [7] G methyltransferase, in regulating the flow-sensitive endothelial transcriptome and atherosclerosis. Vascular endothelial cells were subjected to well-defined athero-protective and athero-prone flow waveforms in vitro and in vivo . METTL7A function was assessed using RNA sequencing (RNA-seq), liquid chromatography-tandem mass spectrometry (LC-MS/MS), crosslinking immunoprecipitation sequencing (CLIP-seq), RNA stability assays, and a CRISPR-Cas-inspired RNA targeting system (CIRTS). METTL7A expression in human coronary arteries with and without atherosclerosis was evaluated by RNA-seq and immunostaining. In vivo atherosclerosis studies were conducted in both global and endothelial-specific Mettl7a1 knockout mice. Endothelial METTL7A expression was restored using cationic polymer-based nanoparticles delivering CDH5 promoter-driven METTL7A plasmids or VCAM1-targeted lipid nanoparticles delivering N1-methylpseudouridine (m¹Ψ)-modified METTL7A mRNA.

RESULTS: Athero-protective unidirectional flow significantly induced METTL7A expression, which promoted internal m [7] G methylation of endothelial transcripts, while other major epitranscriptomic marks and cap-associated m [7] G were not affected by METTL7A. METTL7A preferentially binds to AG-enriched motifs in protein-coding mRNAs and plays a key role in regulating KLF4 and NFKBIA transcripts, enhancing their internal m [7] G and stability and supporting vascular homeostasis. In contrast, endothelial METTL7A expression was significantly reduced by disturbed blood flow and in human atherosclerotic lesions. Global or endothelial-specific loss of METTL7A exacerbated disturbed flow-induced atherosclerosis in mice, independent of serum lipid levels. Restoration of endothelial METTL7A, via nanoparticle-mediated plasmid or m [1] Ψ mRNA delivery, markedly reduced lesion formation in Mettl7a1 [⁻/⁻] and ApoE [⁻/⁻] mice.

CONCLUSIONS: These findings establish METTL7A as a previously unrecognized mechanosensitive methyltransferase that maintains endothelial homeostasis by stabilizing key anti-inflammatory transcripts, KLF4 and NFKBIA, through internal m [7] G methylation. Loss of METTL7A disrupts endothelial function and accelerates atherogenesis in response to disturbed flow. Therapeutic restoration of endothelial METTL7A, via targeted nanoparticle-mediated gene or m [1] Ψ mRNA delivery, significantly lessens atherosclerosis. Collectively, these results uncover a novel epitranscriptomic mechanism governing vascular health and position METTL7A as a promising target for precision nanomedicine in atherosclerotic cardiovascular disease.

RevDate: 2025-07-15

Xiao R, Hoffmann FT, Xie D, et al (2025)

Structural basis of RNA-guided transcription by a dCas12f-σ [E] -RNAP complex.

bioRxiv : the preprint server for biology pii:2025.06.10.658880.

RNA-guided proteins have emerged as critical transcriptional regulators in both natural and engineered biological systems by modulating RNA polymerase (RNAP) and its associated factors [1-5] . In bacteria, diverse clades of repurposed TnpB and CRISPR-associated proteins repress gene expression by blocking transcription initiation or elongation, enabling non-canonical modes of regulatory control and adaptive immunity [1,6,7] . Intriguingly, a distinct class of nuclease-dead Cas12f homologs (dCas12f) instead activates gene expression through its association with unique extracytoplasmic function sigma factors (σ [E]) [8] , though the molecular basis has remained elusive. Here we reveal a novel mode of RNA-guided transcription initiation by determining cryo-electron microscopy structures of the dCas12f-σ [E] system from Flagellimonas taeanensis . We captured multiple conformational and compositional states, including the DNA-bound dCas12f-σ [E] -RNAP holoenzyme complex, revealing how RNA-guided DNA binding leads to σ [E] -RNAP recruitment and nascent mRNA synthesis at a precisely defined distance downstream of the R-loop. Rather than following the classical paradigm of σ [E] -dependent promoter recognition, these studies show that recognition of the -35 element is largely supplanted by CRISPR-Cas targeting, while the melted -10 element is stabilized through unusual stacking interactions rather than insertion into the typical recognition pocket. Collectively, this work provides high-resolution insights into an unexpected mechanism of RNA-guided transcription, expanding our understanding of bacterial gene regulation and opening new avenues for programmable transcriptional control.

RevDate: 2025-07-14
CmpDate: 2025-07-15

Wang D, Guo Y, Liu M, et al (2025)

The function of TaWOX14 in wheat genetic transformation.

Plant cell reports, 44(8):176.

Overexpression of TaWOX14 can significantly improve the genetic transformation and genome editing efficiencies of some wheat immature embryos, and TaPLD serves as a promising candidate gene for haploid induction in wheat. Genetic transformation and genome editing systems have the potential for accelerating the breeding process in crops. However, their effectiveness is often limited by the regeneration efficiency of explants. The WUSCHEL-related homeobox (WOX) family, a group of plant-specific transcription factors, plays a crucial role in somatic embryogenesis. In wheat, WOX genes are categorized into three clades: ancient, intermediate, and WUS. In this study, we systematically analyzed the function of the WUS clade genes in wheat transformation. Our results demonstrated that overexpression of TaWOX14 significantly improved genetic transformation efficiencies in several wheat genotypes, including Fielder, Kenong199, Zhengmai7698, and Yangmai13. Furthermore, by combining the CRISPR-Cas9 system with TaWOX14, we observed enhanced genome editing efficiency in the wheat variety Fielder. Additionally, we explored the potential of TaPLD as a candidate gene for haploid induction in wheat. Based on the amino acid sequence of Zea mays PHOSPHOLIPASE D3 (ZmPLD3), we edited its homologs in wheat and identified a TaPLD-edited plant with a ploidy level intermediate between haploid and hexaploid. Overall, these findings are expected to accelerate the wheat breeding process by improving genetic transformation efficiency and identifying a potential haploid induction gene. Future research will focus on further characterizing the mechanisms of TaWOX14 and TaPLD, and exploring their applications in breeding programs.

RevDate: 2025-07-15
CmpDate: 2025-07-15

Zhong J, Chen Y, Dong Y, et al (2025)

SPARC: An Orthogonal Cas12a/Cas13a Dual-Channel CRISPR Platform for Reliable SNV Identification and Mutation Confirmation.

Analytical chemistry, 97(27):14629-14636.

Rapid and reliable detection of single nucleotide variants (SNVs) is essential for accurate pathogen diagnostics, genetic mutation screening, and personalized medicine. However, existing CRISPR-based nucleic acid detection platforms frequently suffer from ambiguous signal interpretation, specificity limitations, and complex assay workflows. Herein, we introduce SPARC (specific and precise mutation recognition with Cas12a/Cas13a), a novel orthogonal dual-channel CRISPR assay that significantly enhances the SNV detection reliability. SPARC integrates Acidaminococcus sp. Cas12a (AsCas12a), which specifically detects a conserved region as an internal reference, with our recently identified DNA-activated Leptotrichia buccalis Cas13a (LbuCas13a), which exhibits exceptionally high intrinsic SNV specificity without requiring engineered crRNA mismatches. The orthogonal design uniquely resolves the common diagnostic ambiguity between genuine SNVs and target absence. Combined with recombinase polymerase amplification (RPA) and T7 exonuclease digestion, the SPARC platform achieved a sensitivity as low as 1 aM. We demonstrated the platform's robust clinical applicability through successful detection and accurate differentiation of hepatitis B virus (HBV) and clinically significant YMDD resistance mutations. This work presents an innovative and versatile CRISPR-based solution, highlighting substantial potential for advancing clinical diagnostics and precision medicine.

RevDate: 2025-07-15
CmpDate: 2025-07-15

Xia L, Yin J, Wang Y, et al (2025)

Wide Dynamic Range Multiplex Digital Clustered Regularly Interspaced Short Palindromic Repeat Chip for Rapid Detection and Absolute Quantification of Nucleic Acids.

ACS nano, 19(27):24874-24883.

Rapid detection and accurate quantification of multiplex nucleic acids are crucial for infectious diagnosis and pathogen identification, yet they still represent a significant challenge that deserves further attention and investigation. Herein, this research developed a wide dynamic range multiplex digital clustered regularly interspaced short palindromic repeat (CRISPR) (WDRM-dCRISPR) chip and established a rapid, sensitive, multiplexed nucleic acid detection (RSMND) platform that can achieve absolute quantification of multiplex nucleic acids with a limit of detection of 90 copies/mL within 30 min. The chip integrates the rapid amplification capability of RPA, the specific cleavage activity of CRISPR/Cas12a, and the portability of microfluidics, enabling precise and reliable digital absolute quantification of multiplex nucleic acids. As a proof of concept, this chip allows for multiplex absolute quantification of foodborne pathogens with a linear dynamic range of 9 × 10[1] to 1.8 × 10[6] copies/mL (R[2] > 0.9999), high sensitivity, high specificity, and strong tolerance to background interference. The platform was successfully used for the analysis of foodborne pathogens in milk. Compared to qPCR, the RSMND platform exhibited superior accuracy and sensitivity in nucleic acid quantification. Overall, this study demonstrates that the platform provides a powerful tool for multiplex nucleic acid detection and holds significant potential for applications in point-of-care testing.

RevDate: 2025-07-15
CmpDate: 2025-07-15

Liu F, Chen L, Zhu L, et al (2025)

Aptamer-Amplified and CRISPR-Cas12a-Assisted Dual-Mode PEC-SERS Biosensor for Ultrasensitive Detection of Inflammatory Bowel Disease Biomarkers.

Analytical chemistry, 97(27):14377-14387.

Inflammatory bowel disease (IBD) has proven to be a critical global health problem characterized by severe life-threatening complications; thus, the development of noninvasive, reliable, and cost-effective diagnostic methods remains an urgent clinical need. Herein, a novel photoelectrochemical (PEC) and surface-enhanced Raman scattering (SERS) dual-mode platform was successfully developed for ultrasensitive detection of IBD-associated biomarkers, matrix metalloproteinases-9 (MMP-9), and intestinal alkaline phosphatase (IAP). A bifunctional covalent organic frameworks/MXene-Au substrate was synthesized with excellent PEC and SERS properties. An aptamer-based amplification strategy was first employed for MMP-9 detection, which was also the basis for the detection of IAP. The magnetic bead-conjugated double-stranded DNA was then designed to generate activator DNA in the presence of IAP, which activated the trans-cleavage activity of the CRISPR-Cas12a system. The resultant Cas12a specifically cleaved the electrode-immobilized single-stranded DNA (ssDNA), triggering the release of methylene blue as a dual-signal reporter, thereby enabling synchronized PEC-SERS detection for MMP-9 and IAP. The biosensor exhibited a wide linear range with detection limits of 0.074 pg/mL (PEC) and 0.016 pg/mL (SERS) for MMP-9, and 0.38 pg/mL (PEC) and 0.16 pg/mL (SERS) for IAP, respectively. Significantly, clinical validation was performed using a murine IBD model and human intestinal inflammation specimens, confirming the practical utility of the PEC-SERS platform. This study establishes a robust dual-mode biosensing strategy with multicomponent detection, enabling advanced biological analysis and precision health monitoring.

RevDate: 2025-07-15
CmpDate: 2025-07-15

Gu J, Iyer A, Wesley B, et al (2025)

Mapping multimodal phenotypes to perturbations in cells and tissue with CRISPRmap.

Nature biotechnology, 43(7):1101-1115.

Unlike sequencing-based methods, which require cell lysis, optical pooled genetic screens enable investigation of spatial phenotypes, including cell morphology, protein subcellular localization, cell-cell interactions and tissue organization, in response to targeted CRISPR perturbations. Here we report a multimodal optical pooled CRISPR screening method, which we call CRISPRmap. CRISPRmap combines in situ CRISPR guide-identifying barcode readout with multiplexed immunofluorescence and RNA detection. Barcodes are detected and read out through combinatorial hybridization of DNA oligos, enhancing barcode detection efficiency. CRISPRmap enables in situ barcode readout in cell types and contexts that were elusive to conventional optical pooled screening, including cultured primary cells, embryonic stem cells, induced pluripotent stem cells, derived neurons and in vivo cells in a tissue context. We conducted a screen in a breast cancer cell line of the effects of DNA damage repair gene variants on cellular responses to commonly used cancer therapies, and we show that optical phenotyping pinpoints likely pathogenic patient-derived mutations that were previously classified as variants of unknown clinical significance.

RevDate: 2025-07-15
CmpDate: 2025-07-15

Lei X, Huang A, Chen D, et al (2025)

Rapid generation of long, chemically modified pegRNAs for prime editing.

Nature biotechnology, 43(7):1156-1167.

The editing efficiencies of prime editing (PE) using ribonucleoprotein (RNP) and RNA delivery are not optimal due to the challenges in solid-phase synthesis of long PE guide RNA (pegRNA) (>125 nt). Here, we develop an efficient, rapid and cost-effective method for generating chemically modified pegRNA (125-145 nt) and engineered pegRNA (epegRNA) (170-190 nt). We use an optimized splint ligation approach and achieve approximately 90% production efficiency for these RNAs, referred to as L-pegRNA and L-epegRNA. L-epegRNA demonstrates enhanced editing efficiencies across various cell lines and human primary cells with improvements of up to more than tenfold when using RNP delivery and several hundredfold with RNA delivery of PE, compared to epegRNA produced by in vitro transcription. L-epegRNA-mediated RNP delivery also outperforms plasmid-encoded PE in most comparisons. Our study provides a solution to obtaining high-quality pegRNA and epegRNA with desired chemical modifications, paving the way for the use of PE in therapeutics and various other fields.

RevDate: 2025-07-15
CmpDate: 2025-07-15

Karasu ME, Toufektchan E, Chen Y, et al (2025)

Removal of TREX1 activity enhances CRISPR-Cas9-mediated homologous recombination.

Nature biotechnology, 43(7):1168-1176.

CRISPR-Cas9-mediated homology-directed repair (HDR) can introduce desired mutations at targeted genomic sites, but achieving high efficiencies is a major hurdle in many cell types, including cells deficient in DNA repair activity. In this study, we used genome-wide screening in Fanconi anemia patient lymphoblastic cell lines to uncover suppressors of CRISPR-Cas9-mediated HDR. We found that a single exonuclease, TREX1, reduces HDR efficiency when the repair template is a single-stranded or linearized double-stranded DNA. TREX1 expression serves as a biomarker for CRISPR-Cas9-mediated HDR in that the high TREX1 expression present in many different cell types (such as U2OS, Jurkat, MDA-MB-231 and primary T cells as well as hematopoietic stem and progenitor cells) predicts poor HDR. Here we demonstrate rescue of HDR efficiency (ranging from two-fold to eight-fold improvement) either by TREX1 knockout or by the use of single-stranded DNA templates chemically protected from TREX1 activity. Our data explain why some cell types are easier to edit than others and indicate routes for increasing CRISPR-Cas9-mediated HDR in TREX1-expressing contexts.

RevDate: 2025-07-14
CmpDate: 2025-07-14

Karimi M, Ghorbani A, Niazi A, et al (2025)

Integrating AI and CRISPR Cas13a for rapid detection of tomato brown rugose fruit virus.

Scientific reports, 15(1):25422.

The Tomato Brown Rugose Fruit Virus (ToBRFV) has recently emerged as a serious threat to global tomato production, underscoring the need for rapid and sensitive diagnostic tools. Here, we present an AI-driven CRISPR-Cas13a pipeline for designing crRNAs with high specificity to enable the detection of ToBRFV. A computational pipeline that retrieves viral sequences, aligns them in multiple sequence alignments, analyzes their conservation, and screens for off-targets-all coupled with machine learning to optimize crRNA sequences. Experimentally validated crRNAs were evaluated with a fluorescence-based Cas13a assay and showed better sensitivity than RT-PCR, RT-qPCR, and RT-LAMP. By the CRISPR-Cas13a system, ToBRFV was detected at 1:200 (1 ng/µL) dilutions, which performed superior to conventional methods. Integrating bioinformatics with experimental workflows, this pipeline provides a powerful framework for rapid diagnostics that can be deployed in the field, addressing significant challenges in plant virus surveillance and management.

RevDate: 2025-07-14
CmpDate: 2025-07-14

Li P, Wu Z, Liu T, et al (2025)

The defensome of prokaryotes in aquifers.

Nature communications, 16(1):6482.

Groundwater harbors a pristine biosphere where microbes co-evolve with less human interference, yet the ancient and ongoing arms race between prokaryotes and viruses remains largely unknown in such ecosystems. Based on our recent nationwide groundwater monitoring campaign across China, we construct a metagenomic groundwater prokaryotic defensome catalogue (GPDC), encompassing 190,810 defense genes, 90,824 defense systems, 139 defense families, and 669 defense islands from 141 prokaryotic phyla. Over 94% of the defense genes in GPDC are novel and contribute vast microbial immune resources in groundwater. We find that candidate phyla radiation (CPR) bacteria possess higher defense system density and diversity against intense phage infection, while microbes as a whole exhibit an inverse relationship between defense systems and adaptive traits like resistance genes in groundwater. We further identify five first-line defense families covering 69.2% of the total defense systems, and high-turnover accessory immune genes are mostly conveyed to defense islands by mobile genetic elements. Our study also reveals viral resistance to microbial defense through co-localized anti-defense genes and interactions between CRISPR-Cas9 and anti-CRISPR protein. These findings expand our understanding of microbial immunity in pristine ecosystems and offer valuable immune resources for potential biotechnological applications.

RevDate: 2025-07-14
CmpDate: 2025-07-14

Viswanatha R, Entwisle S, Hu Y, et al (2025)

Higher resolution pooled genome-wide CRISPR knockout screening in Drosophila cells using integration and anti-CRISPR (IntAC).

Nature communications, 16(1):6498.

CRISPR screens enable systematic, scalable genotype-to-phenotype mapping. We previously developed a CRISPR screening method for Drosophila melanogaster and mosquito cell lines using plasmid transfection and site-specific integration to introduce single guide (sgRNA) libraries. The method relies on weak sgRNA promoters to avoid early CRISPR-Cas9 activity causing discrepancies between genome edits and integrated sgRNAs. To address this issue and utilize higher strength sgRNA expression, we introduce a method to co-transfect a plasmid expressing anti-CRISPR protein to suppress early CRISPR-Cas9 activity which we term "IntAC" (integrase with anti-CRISPR). IntAC dramatically improves precision-recall of fitness genes across the genome, allowing us to generate the most comprehensive list of cell fitness genes yet assembled for Drosophila. Drosophila fitness genes show strong correlation with human fitness genes and underscore the effects of paralogs on gene essentiality. We also perform a resistance screen to proaerolysin, a glycosylphosphatidylinositol-(GPI)-binding pore-forming toxin, retrieving 18/23 expected and one previously uncharacterized GPI synthesis gene. We also demonstrate that an IntAC sublibrary enables precise positive selection of a transporter under solute overload. IntAC represents a straightforward enhancement to existing Drosophila CRISPR screening methods, dramatically increasing accuracy, and might also be broadly applicable to virus-free CRISPR screens in other cell and species types.

RevDate: 2025-07-14
CmpDate: 2025-07-14

Sewgoolam B, Jim KK, de Bakker V, et al (2025)

Genome-wide antibiotic-CRISPRi profiling identifies LiaR activation as a strategy to resensitize fluoroquinolone-resistant Streptococcus pneumoniae.

Nature communications, 16(1):6491.

Streptococcus pneumoniae is a human pathogen that has become increasingly resistant to synthetic fluoroquinolone antibiotics that target bacterial topoisomerases. To identify pathways essential under fluoroquinolone stress and potential novel targets to revitalize use of this antibiotic class, we perform genome-wide CRISPRi-seq screens and generate antibiotic-gene essentiality signatures. Expectedly, genes involved in DNA recombination and repair become more important under fluoroquinolone-induced DNA damage, including recA, recJ, recF, recO, rexAB, and ruvAB. Surprisingly, specific downregulation of the gene encoding the histidine kinase LiaS caused fluoroquinolone hypersensitivity. LiaS is part of the LiaFSR (VraTSR) three-component regulatory system involved in cell envelope homeostasis. We show that LiaS keeps the response regulator LiaR inactive, and that liaS deletion causes LiaR hyperphosphorylation and upregulation of the LiaR regulon. We use RNA-seq to refine the LiaR regulon, highlighting the role of heat-shock response and pleiotropic regulator SpxA2 in fluoroquinolone sensitivity. Activating the LiaR-regulon by the cell envelope-targeting antibiotic bacitracin synergized with ciprofloxacin and levofloxacin, restoring sensitivity in fluoroquinolone-resistant strains in vitro. Furthermore, bacitracin/levofloxacin combination therapy is effective in vivo and improved treatment of fluoroquinolone-resistant S. pneumoniae infection in a zebrafish meningitis model. These findings offer a starting point for identification and validation of potent combination therapies to treat antibiotic-resistant pneumococcal infections.

RevDate: 2025-07-14

Storz U (2025)

The CRISPR Cas patent files, part 3: Prime Editing and integrase-based variants.

Journal of biotechnology pii:S0168-1656(25)00169-5 [Epub ahead of print].

The epic patent disputes regarding CRISPR Cas9 and, to a lesser extent, CRISPR Cas12a, have somehow overcast a new patent debate that is materializing at the horizon, namely the one that relates to Prime Editing and its integrase-based siblings. While these techniques offer great promise for the precise integration of large DNA stretches into a host genome, it appears that a new chain of dependencies is about to unfold that makes the establishment of Freedom to Operate complicated for interested parties.[[1]].

RevDate: 2025-07-14
CmpDate: 2025-07-14

Sekiba K, Miyake N, Miyakawa Y, et al (2025)

CRISPR-mediated proximity labeling unveils ABHD14B as a host factor to regulate HBV cccDNA transcriptional activity.

Hepatology communications, 9(8): pii:02009842-202508010-00014.

BACKGROUND: The long-term goal of chronic hepatitis B research is a functional cure (HBsAg seroclearance). Although currently used nucleos(t)ide analogs can efficiently inhibit viral replication, they do not reduce viral RNAs or proteins produced from covalently closed circular DNA (cccDNA), and rarely achieve a functional cure. To overcome this situation, revealing the mode of the existence of cccDNA is required, including identifying the interreacting proteins with cccDNA. Here, we aimed to identify novel proteins that interact with cccDNA.

METHODS: Using an in vitro HBV infection model and a sequence-specific proximity labelling method consisting of dead Cas9 and biotin identification (BioID2), we comprehensively determined proteins that possibly interact with cccDNA. After identifying the candidate proteins, the HBV RNA transcription levels were examined by knocking out the associated genes.

RESULTS: We identified ABHD14B as a protein that interacts with cccDNA and inhibits HBV RNA transcription from cccDNA. ABHD14B decreases the acetylation levels of histone proteins that control the transcription levels of HBV RNA in cccDNA. Moreover, ABHD14B interacts with TFII-I, which binds directly to cccDNA in a sequence-dependent manner. These results suggest that the host protein, ABHD14B, is recruited to cccDNA via the TFII-I protein, inhibiting HBV RNA transcription from cccDNA by deacetylating cccDNA histones.

CONCLUSIONS: ABHD14B was newly identified as a suppressor of HBV RNA transcription from cccDNA, which may improve our understanding of the mode of existence of cccDNA, providing a basis for development of a functional cure.

RevDate: 2025-07-14

Akram F, Safdar M, Shabbir I, et al (2025)

Insight into the eminent biotechnological applications of xylanolytic enzymes for sustainable bioprocessing.

3 Biotech, 15(8):249.

Xylan is one of the most abundant polysaccharides in nature and presents a structural complexity characterized by a heterogeneous polymer composition. Comprising various sugar subunits and associated acids linked through a diverse array of bonds, xylan poses challenges for complete degradation. This review article provides a comprehensive overview of xylan's structure, the role of xylanolytic enzymes in its degradation, and the industrial applications of xylanases in sectors, such as paper and pulp, food, textiles, and pharmaceuticals. Furthermore, it also discusses the use of advanced biotechnology tools, such as nano-biotechnology and genetic engineering, particularly through CRISPR/CAS technology, for enhancing the thermostability of xylanases. This article also provides insights into emerging trends in xylanase research, including bioprospecting novel thermostable xylanases from metagenomes, protein engineering, synthetic biology, and the integration of biorefinery. Finally, it highlights the importance of regulatory frameworks and standardization initiatives for ensuring the quality and the sustainability of xylanase-based technologies. Overall, this review offers valuable insights into the multifaceted role of xylanases in biotechnology and industrial bioprocessing while outlining future directions for research and innovation in this field.

RevDate: 2025-07-14

Okesanya OJ, Ayeni RA, Amadin P, et al (2025)

Advances in HIV Treatment and Vaccine Development: Emerging Therapies and Breakthrough Strategies for Long-Term Control.

AIDS research and treatment, 2025:6829446.

Since its identification in 1981, HIV has posed a global public health challenge, witnessing transformative advancements in treatment and prevention. This review summarizes recent novel therapeutic and preventive approaches for long-term HIV control, management, and elimination, and how global collaboration and technological innovations may advance HIV control efforts. This study highlights the progress and challenges in HIV treatment, emphasizing the effectiveness of current antiretroviral therapy (ART) in suppressing viral replication, reducing transmission, and preventing end-organ damage. However, adherence remains a significant barrier due to pill burden, side effects, and psychosocial factors affecting patients. ART-related toxicities include neuropathy, hepatotoxicity, metabolic disorders, and neuropsychiatric effects. Long-acting ART (LA-ART) offers a promising alternative to daily dosing; however, challenges such as injection site reactions persist. Broadly neutralizing antibodies (bNAbs) have shown enhanced efficacy in viral suppression and immune response activation, offering potential for treatment and vaccine design. Innovative gene-editing tools, such as CRISPR-Cas systems, are being explored for their ability to excise or silence proviral DNA; however, their clinical application is limited by off-target effects and delivery challenges. Latency-targeting strategies like "shock and kill" and "block and lock" remain experimental with limited clinical success, and nanotechnology-based drug delivery systems offer targeted, sustained, and less toxic treatment options. Despite the challenges posed by the virus's rapid mutation rate and immune evasion mechanisms, novel vaccine approaches, such as mRNA technology, vector-based platforms, and epitope-targeting strategies, are being explored. In addition, artificial intelligence and machine learning are enhancing the design of vaccines, predictive modeling, and fast-tracking progress in this area. Socio-economic bottlenecks in HIV control, such as stigma, gender disparities, and inequitable healthcare access, exacerbate the epidemic, particularly in sub-Saharan Africa. Enhancing global collaboration, providing sustainable funding, and integrating emerging and innovative technologies are critical for advancing HIV prevention and management. Achieving an AIDS-free generation and ultimately eliminating the epidemic will depend on effectively addressing the social, structural, and scientific barriers that hinder progress in this regard. Trial Registration: ClinicalTrials.gov identifier: NCT02120352, NCT02938520, NCT03639311, NCT03497676, NCT03635788.

RevDate: 2025-07-14

Jhalora V, R Bist (2025)

A Comprehensive Review of Molecular Mechanisms Leading to the Emergence of Multidrug Resistance in Bacteria.

Indian journal of microbiology, 65(2):844-865.

UNLABELLED: Multidrug resistance (MDR) in bacteria poses a serious global health threat, compromising the effectiveness of antibiotics. MDR causes approximately 700,000 deaths annually, with MDR tuberculosis alone claiming 230,000 lives. While bacteria inherently possess intrinsic resistance, acquired resistance stands out as the primary culprit in MDR development. Acquired resistance mechanisms mediated by the bacterial cell wall, nucleic acids, and proteins play a pivotal role in the genesis of MDR. Bacteria can modify their cell wall structure, produce resistant enzymes, exhibit mutations in antibiotic-targeted genes, and acquire resistant genes through horizontal gene transfer. Bacteria can produce proteins that act as enzymes, chemically modifying or directly degrading the antibiotic molecules, leading to the loss of their functionality. Apart from these mechanisms, biofilms also play a pivotal role in MDR expansion. Despite the development of several antibiotics since the discovery of penicillin, continuous structural and molecular modifications in bacteria render these antibiotics ineffective against MDR. The most recent approaches such as clustered regularly interspaced short palindromic repeats (CRISPR) and CRISPR-associated proteins (CRISPR-Cas), nanotechnology, a combination of CRISPR-Cas, and nanoparticles, show promise in treating MDR. Thus, this review delves deep into the molecular mechanisms of MDR, emphasizing the limitations of current antibiotics due to bacterial evolution and highlighting current strategies in the fight against MDR bacteria. This will drive comprehensive research to uncover additional resistance mechanisms and develop innovative strategies to combat resistant bacteria effectively.

SUPPLEMENTARY INFORMATION: The online version supplementary material available at 10.1007/s12088-024-01384-6.

RevDate: 2025-07-14

Taranenko D, Kotovskaya O, Kuznedelov K, et al (2025)

A census of anti-CRISPR proteins reveals AcrIE9 as an inhibitor of Escherichia coli K12 Type IE CRISPR-Cas system.

bioRxiv : the preprint server for biology pii:2025.05.07.652737.

CRISPR-Cas adaptive immunity systems provide defense against mobile genetic elements and are often countered by diverse anti-CRISPR (Acr) proteins. The Type IE CRISPR-Cas of Escherichia coli K12 has been a model for structural and functional studies and is a part of the species' core genome. However, this system is transcriptionally silent, which has fueled questions about its true biological function. To clarify the role of this system in defense, we carried out a census of Acr proteins found in Enterobacterales and identified AcrIE9 as a potent inhibitor of the E. coli K12 Type IE CRISPR-Cas system. While sharing little sequence identity, AcrIE9 proteins from Pseudomonas and Escherichia both interact with the Cas7 subunit of the Cascade complex, thus preventing its binding to DNA. We further show that AcrIE9 is genetically linked to AcrIE10, forming the most widespread anti-CRISPR cluster in Enterobacterales , and this module often co-occurs with a novel HTH-like protein with unusual architecture.

RevDate: 2025-07-14

Xu Y, Le H, Wu Q, et al (2025)

Advancements in CRISPR/Cas systems for disease treatment.

Acta pharmaceutica Sinica. B, 15(6):2818-2844.

The clustered regularly interspaced short palindromic repeats (CRISPR)-Cas (CRISPR-associated proteins) is an adaptive immune system present in most bacteria and archaea, protecting them from infection by exogenous genetic elements. Due to its simplicity, cost-effectiveness, and precise gene editing capabilities, CRISPR/Cas technology has emerged as a promising tool for treating diseases. The continuous refinement of derivative systems has further broadened its scope in disease treatment. Nevertheless, the heterogeneous physiopathological nature of diseases and variations in disease onset sites pose significant challenges for in vivo applications of CRISPR systems. The efficiency of CRISPR systems in disease treatment is directly influenced by the performance of the delivery system. Additionally, concerns such as off-target effects present crucial hurdles in the clinical implementation of CRISPR systems. This review provides a comprehensive overview of the development of CRISPR systems, vector technologies, and their applications in disease treatment, while also addressing the challenges encountered in clinical settings. Furthermore, future research directions are outlined to pave the way for advancements in CRISPR-based therapies.

RevDate: 2025-07-14
CmpDate: 2025-07-14

Steiner KK, Young AC, Patterson AR, et al (2025)

Mitochondrial fatty acid synthesis and MECR regulate CD4+ T cell function and oxidative metabolism.

Journal of immunology (Baltimore, Md. : 1950), 214(5):958-976.

Imbalanced effector and regulatory CD4+ T cell subsets drive many inflammatory diseases. These T cell subsets rely on distinct metabolic programs, modulation of which differentially affects T cell fate and function. Lipid metabolism is fundamental yet remains poorly understood across CD4+ T cell subsets. Therefore, we performed targeted in vivo CRISPR/Cas9 screens to identify lipid metabolism genes and pathways essential for T cell functions. These screens established mitochondrial fatty acid synthesis genes Mecr, Mcat, and Oxsm as key metabolic regulators. Of these, the inborn error of metabolism gene Mecr was most dynamically regulated. Mecrfl/fl; Cd4cre mice had normal naïve CD4+ and CD8+ T cell numbers, demonstrating that MECR is not essential in homeostatic conditions. However, effector and memory T cells were reduced in Mecr knockout and MECR-deficient CD4+ T cells and proliferated, differentiated, and survived less well than control T cells. Interestingly, T cells ultimately showed signs of mitochondrial stress and dysfunction in the absence of MECR. Mecr-deficient T cells also had decreased mitochondrial respiration, reduced tricarboxylic acid intermediates, and accumulated intracellular iron, which appeared to contribute to increased cell death and sensitivity to ferroptosis. Importantly, MECR-deficient T cells exhibited fitness disadvantages and were less effective at driving disease in an in vivo model of inflammatory bowel disease. Thus, MECR-mediated metabolism broadly supports CD4+ T cell proliferation and survival in vivo. These findings may also provide insight to the immunological state of MECR- and other mitochondrial fatty acid synthesis-deficient patients.

RevDate: 2025-07-13
CmpDate: 2025-07-13

Kouvela A, Jaramillo Ponce JR, Giarimoglou N, et al (2025)

Coupling tRNAGly gene redundancy with staphylococcal cell wall integrity, antibiotic susceptibility, and virulence potential.

Nucleic acids research, 53(13):.

Redundancy in transfer RNA (tRNA) gene copies across species remains poorly understood and, in many cases, largely unexplored. In Staphylococcus aureus, multiple tRNAGly genes encode isoacceptors involved in protein synthesis and cell wall formation, aminoacylated by a sole glycyl-tRNA synthetase (GlyRS) which is under the transcription regulation of a species-specific glyS T-box riboswitch. The T-box can interact with all tRNAGly isoacceptors to adopt species-specific conformations and affect both pathways. Using CRISPR/Cas9 editing, we ablated a gene copy corresponding to the proteinogenic P1 tRNAGlyGCC. Surprisingly, the growth and the overall translational activity of the edited strain were found unaffected, suggesting functional compensation by the remaining tRNAGly genes. On the other hand, transcriptomics and proteomics analyses combined with functional assays revealed nutrient-dependent stress responses with surprisingly impaired cell wall integrity and increased susceptibility to cell wall-targeting antibiotics. Additionally, the edited strain displayed reduced biofilm formation but retained the ability to invade human cells in vitro. Overall, the present study underscores the critical role of tRNA gene redundancy in the physiology of S. aureus and highlights tRNAs as regulators of metabolic homeostasis in pathogenic bacteria.

RevDate: 2025-07-13

Zhang S, Kim JC, J Ahn (2025)

Phage engineering strategies to expand host range for controlling antibiotic-resistant pathogens.

Microbiological research, 300:128278 pii:S0944-5013(25)00237-X [Epub ahead of print].

Bacteriophages are known as a promising alternative to control rising bacterial resistance. The adsorption phase is critical for the successful infection of phages, as it determines their ability to recognize and attach to specific bacterial host cells. However, their limited host ranges due to narrow host specificity significantly limit their potential applications and overall effectiveness. Receptor-binding proteins (RBPs) are crucial in the recognition process, and modifying these proteins provides a valuable opportunity to broaden host ranges and enhance adsorption rates. Therefore, gaining a more comprehensive understanding of the interactions between phages and their bacterial hosts is essential. To overcome this challenge, various in vivo and in vitro engineering platforms have been developed, including recombineering, clustered regularly interspaced short palindromic repeats (CRISPR)-CRISPR-associated proteins (Cas) systems, yeast-based technologies, and cell-free systems. These methods provide diverse strategies and flexibility for constructing customized phage genomes with desired characteristics, ultimately enhancing phage application efficiency. This review discusses different types of RBPs in phages and their mechanisms of adsorption, highlighting their relevance for adaptable engineering strategies. We also summarize various phage engineering platforms and explore the design of synthetic phages with expanded host ranges. Finally, we highlight the advantages and limitations of current engineering methods, providing insights to guide future research efforts.

RevDate: 2025-07-13
CmpDate: 2025-07-13

Oliver-Caldes A, Mañe Pujol J, Battram AM, et al (2025)

TIGIT blockade in the context of BCMA-CART cell therapy does not augment efficacy in a multiple myeloma mouse model.

Oncoimmunology, 14(1):2529632.

BCMA-directed CAR-T therapies have shown promising results in multiple myeloma (MM). However, patients continue to relapse. T cell exhaustion with increased TIGIT expression is a resistance mechanism which was confirmed in CAR-T cells from ARI0002h trial, an academic CAR-T developed in our institution. We aimed to analyze the impact of blocking TIGIT on the efficacy of ARI0002h. We used three different strategies to block TIGIT: (1) Addition of an external blocking anti-TIGIT-antibody (Ab), (2) Modify ARI0002h into a 4[th] generation CAR-T, named ARITIGIT, capable of secreting a soluble TIGIT-blocking scFv and (3) TIGIT knock-out in ARI0002h using CRISPR/Cas9. Each strategy was evaluated in vitro and in vivo. Adding a TIGIT-blocking Ab to ARI0002h improved in vitro cytotoxicity, but failed to enhance mice survival. The new 4[th] generation CAR-T, ARITIGIT, was also unable to achieve better survival outcomes despite favoring the in vivo model by using a myeloma cell line with high expression of the TIGIT ligand PVR. Interestingly, when mice were challenged with a second infusion of tumor cells, mimicking a relapse model, a trend for improved survival with ARITIGIT was observed (p = 0.11). Finally, TIGIT-knock-out on ARI0002h (KO-ARI0002h) using CRISPR/Cas9 showed similar in vitro activity to ARI0002h. In an in vivo stress model, TIGIT KO-ARI0002h prolonged survival (p = 0.02). However, this improvement was not significant compared to ARI0002h (p = 0.07). This study failed to demonstrate a significant benefit of TIGIT-blockade on ARI0002h cells despite using three different approaches, suggesting that targeting a single immune checkpoint may be insufficient.

RevDate: 2025-07-13
CmpDate: 2025-07-13

Ye X, Jia H, Y Zu (2025)

lmod2a mutations affect F-actin and SRF pathway leading to cardiac dysfunction in zebrafish.

Developmental biology, 525:306-316.

Leiomodin 2 (LMOD2), a critical pathogenic gene associated with human dilated cardiomyopathy (DCM), is essential in regulating thin filament length during cardiac development. This study generated a homozygous knockout zebrafish line (lmod2a[-/-]) using CRISPR/Cas9 genome editing. lmod2a[-/-] embryos exhibited impaired locomotor activity alongside irregular heart rhythms, reduced cardiac output, compromised contractility, and delayed calcium transients, as revealed by high-speed imaging and calcium optical mapping. Immunofluorescence staining demonstrated a marked reduction in filamentous actin (F-actin), corroborated by QPCR data showing downregulation of the F-actin marker gene acta1b. Moreover, expression levels of key downstream targets of the serum response factor (SRF) signaling pathway were markedly reduced in mutants. These findings indicate that lmod2a deficiency disrupts F-actin homeostasis and SRF-mediated gene regulation, ultimately leading to defective cardiac performance. This study establishes a novel zebrafish model for investigating LMOD-associated cardiomyopathies and provides valuable insights for future therapeutic interventions targeting actin-related cardiac disorders.

RevDate: 2025-07-13
CmpDate: 2025-07-13

Ferrari K, Gurung S, Loges LN, et al (2025)

Zebrafish Kelch-like family member 4 is required for vasculogenesis and hematopoiesis.

Developmental biology, 525:1-12.

Molecular mechanisms regulating vascular development and hematopoiesis are still incompletely understood. The KLHL (Kelch-like) family of proteins function as adapters to target proteins for ubiquitination. However, their role in vascular development has not been previously analyzed. Here we have characterized a novel regulator of vascular development, kelch-like family member 4 (klhl4) in zebrafish. We show that zebrafish klhl4 is expressed in early vascular endothelial and hematopoietic progenitors, while its expression is restricted to vascular endothelial cells during later developmental stages. To determine the functional role of klhl4, we generated loss-of-function zebrafish mutants using CRISPR/Cas9 genome editing. klhl4 mutant embryos were viable, yet they exhibited delayed sprouting of intersegmental vessels (ISVs), which correlated with reduced expression of vascular endothelial and erythroid specific molecular markers. Time-lapse imaging showed that vascular endothelial and hematopoietic progenitor cells exhibit delayed migration towards the midline and undergo increased apoptosis and reduced proliferation in klhl4 mutants. Expression of npas4l and etv2/etsrp, two master regulators of endothelial and hematopoietic development, was reduced in klhl4 mutants, suggesting that some vascular defects could be caused by the reduction of npas4l and etv2 expression. However, npas4l or etv2 overexpression failed to rescue ISV sprouting defects in klhl4 mutants, suggesting that klhl4 may promote vasculogenesis by additional mechanisms. In summary, our findings demonstrate a novel role for zebrafish klhl4 in regulating vascular endothelial and hematopoietic development during embryogenesis. Because the Klhl4 protein sequence is highly conserved between different vertebrates, it is likely that it may play a similar role in other organisms.

RevDate: 2025-07-12

Arutselvan R, Kumar S, Akash AU, et al (2025)

Deciphering the complex signaling networks in phytophthora infected plants: Insights into microbiome interactions and plant defense mechanisms.

Plant physiology and biochemistry : PPB, 228:110222 pii:S0981-9428(25)00750-8 [Epub ahead of print].

Phytophthora species are destructive plant pathogens that cause severe economic losses in agriculture and natural ecosystems, known for their rapid spread through soil and water and resistance to conventional control methods. Understanding the complex signaling networks activated in plants during Phytophthora infection is crucial for developing effective management strategies. This review summarizes research findings on Phytophthora-plant interactions, with special emphasis on Phytophthora-plant microbiome interactions. Initially, molecular mechanisms involved in the plant response to Phytophthora infection are discussed, further emphasizing key signaling pathways activated by Phytophthora in host plants. The role of phytohormones in imparting resistance to Phytophthora infections is explored in depth. Additionally, the interaction and effects of Phytophthora and the plant immune system with the plant microbiome are examined, highlighting how these interactions facilitate disease and/or aid in plant defense. Various biotechnological approaches for enhancing plant resistance to Phytophthora, including recent technologies like CRISPR-Cas systems, are also reviewed. The conclusion addresses the need for further research into signaling networks within Phytophthora-plant-microbiome interactions and their future implications for crop protection.

RevDate: 2025-07-12
CmpDate: 2025-07-12

Faber A, Politan RJ, Stukenberg D, et al (2025)

Expanding genetic engineering capabilities in Vibrio natriegens with the Vnat Collection.

Nucleic acids research, 53(13):.

Vibrio natriegens, with its exceptionally fast growth rate, has great promise as a revolutionary chassis for synthetic biology, yet the realization of its full potential has been limited by the lack of robust, standardized genetic tools. Here, we present the Vnat Collection, a comprehensive, modular toolkit specifically engineered to overcome these limitations. Leveraging optimized Golden Gate cloning strategies, we introduce improved junction sequences and a highly efficient dropout part system, achieving up to a 300-fold increase in assembly efficiency. Our toolkit significantly expands the synthetic biology toolbox by providing a wide array of characterized inducible promoters, enabling precise, orthogonal gene regulation, and novel operon connectors to streamline the construction of multi-gene pathways critical for metabolic engineering. Furthermore, we enhance genome editing workflows through refined NT-CRISPR methods, incorporating homology-flanked targeting constructs and demonstrating a simplified protocol that eliminates intermediate purification steps. With over 220 rigorously validated modular components, the Vnat Collection establishes an advanced standard for genetic engineering of V. natriegens, empowering researchers to efficiently harness this organism's unparalleled potential for diverse biotechnology applications.

RevDate: 2025-07-12
CmpDate: 2025-07-12

Chi H, McMahon S, Daniel-Pedersen L, et al (2025)

SAM-AMP lyases in type III CRISPR defence.

Nucleic acids research, 53(13):.

Type III CRISPR systems detect non-self RNA and activate the enzymatic Cas10 subunit, which generates nucleotide second messengers for activation of ancillary effectors. Although most signal via cyclic oligoadenylate, an alternative class of signalling molecule SAM-AMP, formed by conjugating ATP and S-adenosylmethionine, was described recently. SAM-AMP activates a trans-membrane effector of the CorA magnesium transporter family to provide anti-phage defence. Intriguingly, immunity also requires SAM-AMP degradation by means of a specialized CRISPR-encoded NrN family phosphodiesterase in Bacteroides fragilis. In Clostridium botulinum, the nrn gene is replaced by a gene encoding a SAM-AMP lyase. Here, we investigate the structure and activity of C. botulinum SAM-AMP lyase, which can substitute for the nrn gene to provide CorA-mediated immunity in Escherichia coli. The structure of SAM-AMP lyase bound to its reaction product 5'-methylthioadenosine-AMP reveals key details of substrate binding and turnover by this PII superfamily protein. Bioinformatic analysis revealed a phage-encoded SAM-AMP lyase that degrades SAM-AMP efficiently in vitro, consistent with an anti-CRISPR function.

RevDate: 2025-07-12
CmpDate: 2025-07-12

Madariaga-Marcos J, Baltramonaitis M, Henkel-Heinecke S, et al (2025)

Structural and mechanistic insights into the sequential dsDNA cleavage by SpCas12f1.

Nucleic acids research, 53(13):.

Miniature CRISPR-Cas12f1 effector complexes have recently attracted considerable interest for genome engineering applications due to their compact size. Unlike other Class 2 effectors, Cas12f1 functions as a homodimer bound to a single ∼200 nt RNA. While the basic biochemical properties of Cas12f1, such as its use of a single catalytic center for catalysis, have been characterized, the orchestration of the different events occurring during Cas12f1 reactions remained little explored. To gain insights into the dynamics and mechanisms involved in DNA recognition and cleavage by Cas12f1 from Syntrophomonas palmitatica (SpCas12f1), we solved the structure of SpCas12f1 bound to target DNA and employed single-molecule magnetic tweezers measurements in combination with ensemble kinetic measurements. Our data indicate that SpCas12f1 forms 18 bp R-loops, in which local contacts of the protein to the R-loop stabilize R-loop intermediates. DNA cleavage is catalyzed by a single SpCas12f1 catalytic center, which first rapidly degrades a ∼11 bp region on the nontarget strand by cutting at random sites. Subsequent target strand cleavage is slower and requires at least a nick in the nontarget strand.

RevDate: 2025-07-12
CmpDate: 2025-07-12

Samuels M, Besta S, Betrán AL, et al (2025)

CRISPR screening approaches in breast cancer research.

Cancer metastasis reviews, 44(3):59.

The emergence of CRISPR-Cas9 technology has transformed functional genomics, offering unmatched opportunities to dissect and understand biological pathways and identify novel therapeutic targets in cancer. Breast cancer is a complex, heterogeneous disease and remains a major cause of morbidity and mortality in women, particularly when diagnosed at advanced or metastatic stages where effective treatments are limited. High-throughput CRISPR screening is undoubtedly a powerful tool to discover novel drug targets, uncover synthetic lethal interactions, and identify vulnerabilities in cancer. This review focuses on advances in our understanding of breast cancer developed through CRISPR-based screening technology, particularly in identifying drivers of breast cancer progression, growth, and metastasis, as well as in identifying potential new therapeutic targets and combination therapies. We discuss recent discoveries, current challenges, and limitations of this approach and explore how advancements in CRISPR technology could have a profound impact on the future of breast cancer treatment.

RevDate: 2025-07-12
CmpDate: 2025-07-12

Gao Z, Long T, Guo P, et al (2025)

The Nuclear Transcription Factor SlNF-YC9 Regulates the Protrusion of Tomato Fruit Tip.

International journal of molecular sciences, 26(13): pii:ijms26136511.

NF-Y transcriptional regulators play crucial roles in diverse biological processes in plants, primarily through the formation of NF-Y complexes that bind to specific DNA motifs. These complexes modulate the expression of downstream genes, which influence plant development and growth. In our research, the function of the NF-Y family C subunit member SlNF-YC9 gene in tomato was investigated with the CRISPR/Cas9 method. In contrast to the WT (wild type), the mutant CR-SlNF-YC9 exhibited a prominent protrusion at the fruit tip. The quantitative PCR analysis displayed that the transcription levels of genes associated with auxin transport (PIN4, PIN5, and PIN9) as well as auxin response genes (ARF7 and LAX3) were enhanced in the CR-SlNF-YC9 fruits than in the WT. Analysis of dual-luciferase reporter and EMSA assays showed that the SlNF-YC9-YB13b-YA7a trimer specifically binds the FUL2 promoter and represses its expression. In conclusion, our results suggest that SlNF-YC9 is crucial in influencing tomato fruit shape by the formation of NF-Y heterotrimeric complexes.

RevDate: 2025-07-12
CmpDate: 2025-07-12

Kovalev MA, Mamaeva NY, Kristovskiy NV, et al (2025)

Epigenome Engineering Using dCas Systems for Biomedical Applications and Biotechnology: Current Achievements, Opportunities and Challenges.

International journal of molecular sciences, 26(13): pii:ijms26136371.

Epigenome engineering, particularly utilizing CRISPR/dCas-based systems, is a powerful strategy to modulate gene expression and genome functioning without altering the DNA sequence. In this review we summarized current achievements and prospects in dCas-mediated epigenome editing, primarily focusing on its applications in biomedicine, but also providing a wider context for its applications in biotechnology. The diversity of CRISPR/dCas architectures is outlined, recent innovations in the design of epigenetic editors and delivery methods are highlighted, and the therapeutic potential across a wide range of diseases, including hereditary, neurodegenerative, and metabolic disorders, is examined. Opportunities for the application of dCas-based tools in animal, agricultural, and industrial biotechnology are also discussed. Despite substantial progress, challenges, such as delivery efficiency, specificity, stability of induced epigenetic modifications, and clinical translation, are emphasized. Future directions aimed at enhancing the efficacy, safety, and practical applicability of epigenome engineering technologies are proposed.

RevDate: 2025-07-12
CmpDate: 2025-07-12

Jung YJ, Kim JY, Cho YG, et al (2025)

CRISPR/Cas9-Mediated Knockout of OsbZIP76 Reveals Its Role in ABA-Associated Immune Signaling in Rice.

International journal of molecular sciences, 26(13): pii:ijms26136374.

The basic leucine zipper (bZIP) transcription factors are involved in a wide range of physiological processes in plants, including hormone signaling, stress responses, and growth and development regulation. They play a key role in abscisic acid (ABA)-mediated immune regulation. However, the immune-related function of OsbZIP76 in rice remains poorly understood. In this study, we generated OsbZIP76 knockout (KO) lines using CRISPR/Cas9-mediated genome editing and examined their phenotypic responses to the bacterial pathogen Xanthomonas oryzae pv. oryzae (Xoo) and the fungal pathogen Magnaporthe oryzae. The KO lines showed increased susceptibility to both pathogens compared to wild-type (WT) plants. Furthermore, qRT-PCR analysis revealed that, upon pathogen infection, the expression of pathogenesis-related genes such as PR1a, PR5, and NPR1 was significantly suppressed in the KO lines. ABA treatment experiments showed that KO lines were hypersensitive to exogenous ABA, indicating a role for OsbZIP76 in ABA perception and signaling. Notably, the expression of the OsbZIP76 gene itself was strongly induced by both ABA treatment and pathogen infection, supporting its role as a positive regulator in ABA-associated immune signaling. Overall, this study demonstrates that OsbZIP76 functions as an important immune regulator by integrating defense gene expression with ABA signaling, providing new insights into the molecular crosstalk between hormonal signaling and pathogen defense mechanisms.

RevDate: 2025-07-12
CmpDate: 2025-07-12

Becchi G, Whitehead M, Harvey JP, et al (2025)

CRISPRa-Mediated Increase of OPA1 Expression in Dominant Optic Atrophy.

International journal of molecular sciences, 26(13): pii:ijms26136364.

Dominant Optic Atrophy (DOA) is the most common inherited optic neuropathy and presents as gradual visual loss caused by the loss of retinal ganglion cells (RGCs). Over 60% of DOA cases are caused by pathogenic variants in the OPA1 gene, which encodes a mitochondrial GTPase essential in mitochondrial fusion. Currently, there are no treatments for DOA. Here, we tested the therapeutic potential of an approach to DOA using CRISPR activation (CRISPRa). Homology directed repair was used to introduce a common OPA1 pathogenic variant (c.2708_2711TTAGdel) into HEK293T cells as an in vitro model of DOA. Heterozygous c.2708_2711TTAGdel cells had reduced levels of OPA1 mRNA transcript, OPA1 protein, and mitochondrial network alterations. The effect of inactivated Cas9 fused to an activator (dCas9-VPR) was tested with a range of guide RNAs (gRNA) targeted to the promotor region of OPA1. gRNA3 and dCas9-VPR increased OPA1 expression at the RNA and protein level towards control levels. Importantly, the correct ratio of OPA1 isoform transcripts was maintained by CRISPRa. CRISPRa-treated cells showed an improvement in mitochondrial networks compared to untreated cells, indicating partial rescue of a disease-associated phenotype. Collectively, these data support the potential application of CRISPRa as a therapeutic intervention in DOA.

RevDate: 2025-07-12
CmpDate: 2025-07-12

El Hazzouri S, Al-Rifai R, Surges N, et al (2025)

FVIII Trafficking Dynamics Across Subcellular Organelles Using CRISPR/Cas9 Specific Gene Knockouts.

International journal of molecular sciences, 26(13): pii:ijms26136349.

Factor VIII (FVIII) interacts with Endoplasmic Reticulum (ER) chaperones Calnexin (CANX) and Calreticulin (CALR) and with ER-Golgi Intermediate Compartment (ERGIC) transporters, Lectin, mannose-binding 1 (LMAN1) and Multiple Coagulation Deficiency 2 (MCFD2). We previously reported that the Gamma-aminobutyric Acid Receptor-associated proteins (GABARAPs) also influence FVIII secretion. Here, we further investigated the intracellular dynamics of FVIII using single and double CRISPR/Cas9 Knockout (KO) models of the abovementioned chaperones as well as the GABARAP proteins in HEK293 cells expressing FVIII. Cellular pathways were manipulated by Brefeldin A (BFA), Chloroquine (CQ), a Rab7 inhibitor, and subjected to glucose starvation. The effect of each KO on FVIII secretion and organelle distribution was assessed by a two-stage chromogenic assay and immunofluorescence (IF) microscopy, prior and upon cell treatments. Using these approaches, we first observed distinct effects of each studied protein on FVIII trafficking. Notably, intracellular localization patterns revealed clustering of FVIII phenotypes in GABARAP[KO], CANX[KO], and CALR[KO] cells together under both basal and treated conditions, an observation that was also reflected in their respective double KO combinations. Besides, a clear involvement of additional components of the endomembrane system was evident, specifically at the trans-Golgi space, as marked by FVIII colocalization with the Ras-like proteins in brain (Rab8 and Rab7) and with the Vesicle-Associated Membrane Protein (VAMP8), along with the observed impact of the selected cell treatments on FVIII phenotypes. These outcomes enhance our understanding of the molecular mechanisms regulating FVIII and pave the way for new perspectives, which could be further projected into FVIII replacement, cell and gene therapies.

RevDate: 2025-07-12
CmpDate: 2025-07-12

Cattaneo M, Giagnorio E, Lauria G, et al (2025)

Therapeutic Approaches for C9ORF72-Related ALS: Current Strategies and Future Horizons.

International journal of molecular sciences, 26(13): pii:ijms26136268.

Amyotrophic lateral sclerosis (ALS) is a fatal neurodegenerative disease characterized by the loss of upper and lower motor neurons. One of its major genetic causes is C9ORF72, where mutations lead to hexanucleotide repeat expansions in the C9ORF72 gene. These expansions drive disease progression through mechanisms, including the formation of toxic RNAs and the accumulation of damaged proteins such as dipeptide repeats (DPRs). This review highlights these pathogenic mechanisms, focusing on RNA foci formation and the accumulation of toxic DPRs, which contribute to neuronal damage. It also discusses promising targeted therapies, including small molecules and biological drugs, designed to counteract these specific molecular events. Small molecules such as G-quadruplex stabilizers, proteasome and autophagy modulators, and RNase-targeting chimeras show potential in reducing RNA foci and DPR accumulation. Furthermore, targeting enzymes involved in repeat-associated non-AUG (RAN) translation and nucleocytoplasmic transport, which are crucial for disease pathogenesis, opens new therapeutic avenues. Even some anti-viral drugs show encouraging results in preclinical studies. Biological drugs, such as antisense oligonucleotides and gene-editing technologies like CRISPR-Cas, were explored for their potential to specifically target C9ORF72 mutations and modify the disease's molecular foundations. While preclinical and early clinical data show promise, challenges remain in optimizing delivery methods, ensuring long-term safety, and improving efficacy. This review concludes by emphasizing the importance of continued research and the potential for these therapies to alter the disease trajectory and improve patient outcomes.

RevDate: 2025-07-12
CmpDate: 2025-07-12

Reddy KD, Rathnayake SNH, Idrees S, et al (2025)

A Novel Regulatory Role for RPS4Y1 in Inflammatory and Fibrotic Processes.

International journal of molecular sciences, 26(13): pii:ijms26136213.

Asthma is a chronic inflammatory respiratory disease well-known to demonstrate sexual dimorphism in incidence and severity, although the mechanisms causing these differences remain incompletely understood. RPS4X and RPS4Y1 are X and Y-chromosome-linked genes coding ribosomal subunits previously associated with inflammation, airway remodelling and asthma medication efficacy. Particularly, RPS4Y1 has been under-investigated within the context of disease, with little examination of molecular mechanisms and pathways regulated by this gene. The ribosome, a vital cellular machinery, facilitates the translation of mRNA into peptides and then proteins. Imbalance or dysfunction in ribosomal components may lead to malfunctioning proteins. Using CRISPR-Cas9 knockout cellular models for RPS4Y1 and RPS4X, we characterised the function of RPS4Y1 in the context of the asthma-relevant processes, inflammation and fibrosis. No viable RPS4X knockouts could be generated. We highlight novel molecular mechanisms such as specific translation of IL6 and tenascin-C mRNA by RPS4Y1 containing ribosomes. Furthermore, an RPS4Y1-centric gene signature correlates with clinical lung function measurements, specifically in adult male asthma patients. These findings inform the current understanding of sex differences in asthma, as females do not produce the RPS4Y1 protein. Therefore, the pathologically relevant functions of RPS4Y1 may contribute to the complex sexually dimorphic pattern of asthma susceptibility and progression.

RevDate: 2025-07-12
CmpDate: 2025-07-12

Chang TY, Lin LC, Kao CY, et al (2025)

Study of lug Operon, SCCmec Elements, Antimicrobial Resistance, MGEs, and STs of Staphylococcus lugdunensis Clinical Isolates Through Whole-Genome Sequencing.

International journal of molecular sciences, 26(13): pii:ijms26136106.

Staphylococcus lugdunensis is a coagulase-negative staphylococcus known for its significant pathogenic potential, often causing severe infections such as endocarditis and bacteremia, with virulence comparable to S. aureus. Despite general susceptibility to most antibiotics, the emergence of oxacillin-resistant strains is increasingly concerning. This study conducted whole-genome sequencing on 20 S. lugdunensis isolates from Chang Gung Memorial Hospital to explore their genetic diversity, antimicrobial resistance mechanisms, and mobile genetic elements. The lugdunin biosynthetic operon, essential for antimicrobial peptide production, was present in multilocus sequence typing (MLST) types 1, 3, and 6 but absent in STs 4, 27, and 29. Additionally, IS256 insertion elements, ranging from 7 to 17 copies, were identified in four strains and linked to multidrug resistance. CRISPR-Cas systems varied across STs, with type III-A predominant in ST1 and ST6 and type IIC in ST4, ST27, and ST29; notably, ST3 lacked CRISPR systems, correlating with a higher diversity of SCCmec elements and an increased potential for horizontal gene transfer. Phage analysis revealed stable phage-host associations in ST1, ST6, and ST29, whereas ST4 displayed a varied prophage profile. Phenotypic resistance profiles generally aligned with genomic predictions, although discrepancies were observed for aminoglycosides and clindamycin. These findings highlight the complex genetic landscape and evolutionary dynamics of S. lugdunensis, emphasizing the need for genomic surveillance to inform clinical management and prevent the spread of resistant strains.

RevDate: 2025-07-12

Fan X, Zhang Y, Gu P, et al (2025)

Epitranscriptomic Control of Drought Tolerance in Rice: The Role of RNA Methylation.

Plants (Basel, Switzerland), 14(13): pii:plants14132002.

Drought stress is a predominant abiotic constraint adversely affecting global rice (Oryza sativa) production and threatening food security. While the transcriptional and post-transcriptional regulation of drought-responsive pathways has been widely investigated, the emerging field of epitranscriptomics, particularly RNA chemical modifications such as N6-methyladenosine (m[6]A), adds a new dimension to gene regulation under stress. The most prevalent internal modification in eukaryotic messenger RNA influences RNA metabolism by interacting dynamically with enzymes that add, remove, or recognize the modification. Recent studies in rice reveal that m[6]A deposition is not static but dynamically regulated in response to water-deficit conditions, influencing transcript stability, splicing, nuclear export, and translation efficiency of key drought-responsive genes. This review critically synthesizes current findings on the distribution and functional implications of m[6]A and other epitranscriptomic marks (e.g., 5-methylcytosine [m[5]C], pseudouridine [Ψ]) in modulating rice responses to drought. We discuss the regulatory circuitry involving m[6]A effectors such as OsMTA, OsFIP37, and YTH domain proteins and their integration with known drought-signaling pathways including ABA and reactive oxygen species (ROS) cascades. We also highlight emerging high-resolution technologies such as m[6]A-seq, direct RNA sequencing, and nanopore-based detection that facilitate epitranscriptomic profiling in rice. Finally, we propose future directions for translating epitranscriptomic knowledge into crop improvement, including CRISPR/Cas-based modulation of RNA modification machinery to enhance drought tolerance.

RevDate: 2025-07-12

Sutula M, Tussipkan D, Kali B, et al (2025)

Molecular Mechanisms Underlying Defense Responses of Potato (Solanum tuberosum L.) to Environmental Stress and CRISPR/Cas-Mediated Engineering of Stress Tolerance.

Plants (Basel, Switzerland), 14(13): pii:plants14131983.

Environmental stresses, such as drought, salinity, and pathogen attacks, significantly affect potato growth, development, and yield by disrupting key physiological and biochemical processes. Plant responses to these stresses are mediated by changes in gene expression, transcriptional regulation, and the activity of various functional proteins, all of which contribute to the molecular mechanisms of stress tolerance. Genome editing using the CRISPR/Cas9 system has been effectively used to enhance the resistance of potato to environmental stresses and to improve its nutritional value. This article provides a comprehensive review of recent studies retrieved from academic databases focusing on the effects of various environmental stressors on potato growth, yield, and postharvest storage. It also examines the influence of these stresses on the production of secondary metabolites and their associated molecular pathways. Finally, the review highlights advancements in the application of CRISPR/Cas-based genome editing technologies between 2021 and 2025 to improve stress tolerance and nutritional traits in potato plants.

RevDate: 2025-07-12

Khan R, Phely L, Ehrenfeld S, et al (2025)

Modeling the t(2;5) Translocation of Anaplastic Large Cell Lymphoma Using CRISPR-Mediated Chromosomal Engineering.

Cancers, 17(13): pii:cancers17132226.

BACKGROUND/OBJECTIVES: ALK+ Anaplastic Large Cell Lymphoma (ALCL) is an aggressive T-cell lymphoma that is characterized by expression of the Anaplastic Lymphoma Kinase (ALK), which is induced by the t(2;5) chromosomal rearrangement, leading to the expression of the NPM-ALK fusion oncogene. Most previous preclinical models of ALK+ ALCL were based on overexpression of the NPM-ALK cDNA from heterologous promoters. Due to the enforced expression, this approach is prone to artifacts arising from synthetic overexpression, promoter competition and insertional variation.

METHODS: To improve the existing ALCL models and more closely recapitulate the oncogenic events in ALK+ ALCL, we employed CRISPR/Cas-based chromosomal engineering to selectively introduce translocations between the Npm1 and Alk gene loci in murine cells.

RESULTS: By inducing precise DNA cleavage at the syntenic loci on chromosome 11 and 17 in a murine IL-3-dependent Ba/F3 reporter cell line, we generated de novo Npm-Alk translocations in vivo, leading to IL-3-independent cell growth. To verify efficient recombination, we analyzed the expression of the NPM-ALK fusion protein in the recombined cells and could also show the t(11;17) in the IL-3 independent Ba/F3 cells. Subsequent functional testing of these cells using an Alk-inhibitor showed exquisite responsiveness towards Crizotinib, demonstrating strong dependence on the newly generated ALK fusion oncoprotein. Furthermore, a comparison of the gene expression pattern between Ba/F3 cells overexpressing the Npm-Alk cDNA with Ba/F3 cells transformed by CRISPR-mediated Npm-Alk translocation indicated that, while broadly overlapping, a set of pathways including the unfolded protein response pathway was increased in the Npm-Alk overexpression model, suggesting increased reactive changes induced by exogenous overexpression of Npm-Alk. Furthermore, we observed clustered expression changes in genes located in chromosomal regions close to the breakpoint in the new CRISPR-based model, indicating positional effects on gene expression mediated by the translocation event, which are not part of the older models.

CONCLUSIONS: Thus, CRISPR-mediated recombination provides a novel and more faithful approach to model oncogenic translocations, which may lead to an improved understanding of the molecular pathogenesis of ALCL and enable more accurate therapeutic models of malignancies driven by oncogenic fusion proteins.

RevDate: 2025-07-12

Sidabraite A, Mosert PL, Ahmed U, et al (2025)

Advancing Cholangiocarcinoma Diagnosis: The Role of Liquid Biopsy and CRISPR/Cas Systems in Biomarker Detection.

Cancers, 17(13): pii:cancers17132155.

Background/Objectives: Cholangiocarcinoma (CCA) is a highly heterogeneous malignancy of the biliary tract with limited diagnostic tools for early detection. Current serum markers, such as CA19-9, lack specificity and sensitivity, particularly in early-stage disease, which hinders the effectiveness of curative interventions. This narrative review evaluates the limitations of existing diagnostic approaches and explores the potential of combining liquid biopsy (LB) technologies with CRISPR/Cas-based systems for precise, minimally invasive biomarker detection. Methods: A narrative review was conducted, synthesizing literature from 2018 to 2025 across PubMed, MDPI, Web of Science, Google Scholar, and Embase using MeSH terms such as "cholangiocarcinoma," "liquid biopsy," "miRNA," and "CRISPR/Cas." Results: Circulating microRNAs (e.g., miR-21, miR-16, miR-877) exhibit high diagnostic accuracy. The RACE (Rolling Circle Amplification-assisted CRISPR/Cas9 Cleavage) platform shows promise for detecting extracellular vesicle (EV)-derived miRNAs with high sensitivity and single-nucleotide specificity. When paired with liquid biopsy, CRISPR-based assays enable real-time, cost-effective, and multiplexed detection of tumor-specific biomarkers. Conclusions: The introduction of LB combined with CRISPR/Cas systems could potentially revolutionize the early and accurate diagnosis of CCA, thereby advancing the overall treatment strategy. However, this method is still under development and requires further testing before it can be incorporated into routine diagnostics.

RevDate: 2025-07-12

Nascimento APS, AN Barros (2025)

Sustainable Innovations in Food Microbiology: Fermentation, Biocontrol, and Functional Foods.

Foods (Basel, Switzerland), 14(13): pii:foods14132320.

The growing demand for more sustainable food systems has driven the development of solutions based on food microbiology, capable of integrating safety, functionality, and environmental responsibility. This paper presents a critical and up-to-date review of the most relevant advances at the interface between microbiology, sustainability, and food innovation. The analysis is structured around three main axes: (i) microbial fermentation, with a focus on traditional practices and precision technologies aimed at valorizing agro-industrial waste and producing functional foods; (ii) microbial biocontrol, including the use of bacteriocins, protective cultures, bacteriophages, and CRISPR-Cas (Clustered Regularly Interspaced Short Palindromic Repeats-CRISPR-associated)-based tools as alternatives to synthetic preservatives; and (iii) the development of functional foods containing probiotics, prebiotics, synbiotics, and postbiotics, with the potential to modulate the gut microbiota and promote metabolic, immune, and cognitive health. In addition to reviewing the microbiological and technological mechanisms involved, the paper discusses international regulatory milestones, scalability challenges, and market trends related to consumer acceptance and clean labeling. Finally, emerging trends and research gaps are addressed, including the use of omics technologies, artificial intelligence, and unexplored microbial resources. Food microbiology, by incorporating sustainable practices and advanced technologies, is positioned as a strategic pillar for building a healthy, circular, science-based food model.

RevDate: 2025-07-12

Han P, Wang Y, H Sun (2025)

Impact of Temperature Stresses on Wheat Quality: A Focus on Starch and Protein Composition.

Foods (Basel, Switzerland), 14(13): pii:foods14132178.

With climate change, maintaining wheat quality has become essential for the functional properties, end-use, commodity value, and nutritional benefits of wheat flour. Temperature indirectly influences wheat quality by modulating grain size, starch and protein content, and the balance between these components. This review systematically analyzes temperature-mediated alterations in wheat grain quality, with particular emphasis on the two core components: starch and protein. Specifically, daytime warming generally increases protein content while reducing starch accumulation; however, temperatures exceeding 30 °C diminish key protein quality parameters (UPP%, Glu/Gli ratio, HMW-GS/LMW-GS ratio). Nighttime warming enhances protein quality but compromises starch content and yield potential. Conversely, under low-temperature conditions, starch content declines, whereas protein content is primarily influenced by genotypes and treated temperatures. Furthermore, the underlying mechanisms driving temperature-induced changes in wheat quality traits are discussed. However, the mechanisms of temperature effects have not been fully elucidated, and the results often vary between regions or over years. Thus, identifying conserved high/low-temperature resistance genes, QTLs, epialleles, and epiQTL, as well as developing corresponding molecular markers and epi-markers, is an urgent priority. Meanwhile, genome-editing tools such as CRISPR/Cas could serve as a powerful approach for creating new wheat germplasm with durable high/low-temperature resistance.

RevDate: 2025-07-12

Han H, Zhang D, Hao W, et al (2025)

Parallel and Visual Detections of ASFV by CRISPR-Cas12a and CRISPR-Cas13a Systems Targeting the Viral S273R Gene.

Animals : an open access journal from MDPI, 15(13): pii:ani15131902.

African swine fever virus (ASFV) causes a highly contagious and lethal hemorrhagic disease and significantly threatens the pig industry. There is no commercially effective vaccine available currently, making the detection of ASFV critical for control and prevention. Previously, we established the CRISPR-LbCas12a and LwCRSIRP-Cas13a visual detections of ASFV, separately, targeting the structural p17 gene D117L. In this study, we performed the parallel detections of ASFV based on the conserved viral protease gene S273R using CRISPR-LbCas12a and CRISPR-LbuCas13a systems. Our results showed that both systems are able to specifically detect ASFV as low as two copies of the S273R gene, and effectively detect clinical samples with minimal DNA purification. The work promotes CRISPR-Cas systems for the application of on-site detection in the field.

RevDate: 2025-07-11
CmpDate: 2025-07-11

Liu Y, Liu H, Wang G, et al (2025)

Dual-Check CRISPR-SERS strategy for sensitively detecting Monkeypox DNA and its single-base mutated DNA.

Mikrochimica acta, 192(8):497.

This study presents a convenient and efficient dual-check strategy for detecting Monkeypox DNA utilizing the SERS (Surface-enhanced Raman Spectroscopy)-CRISPR (Clustered Regularly Interspaced Short Palindromic Repeats) system. The Monkeypox plasmid DNA (mpDNA) is recognized by the CRISPR RNA (crRNA)-Cas12a protein complex, where crRNA encompasses a targeting complementary sequence. Upon recognition, the trans-cleavage activity of Cas12a is activated and trans-cleaves the probe DNA (Cy3-ssDNA) which is modified on Au nanoparticles (AuNPs). As the ssDNA strand is cleaved, Cy3 molecules are released in the solution, while the amount of Cy3 modified on the AuNPs decreases. The free Cy3 molecules are collected from the supernatant, and their SERS intensities are measured using the silver nanopillar (AgNRs) substrate. The mpDNA with varying concentration from 5 nM to 0.5 fM can be quantitatively determined based on the SERS signals of free Cy3 and the collected nanotag. This strategy allows the detection of mpDNA with a concentration of 50 fM within 60 min. Moreover, the strategy can successfully detect single-base mutated mpDNA. Owing to the non-specific trans-cleavage activity of the protein, this strategy can be adapted to various nucleic acid detection scenarios by designing complementary RNA and DNA sequences.

RevDate: 2025-07-11
CmpDate: 2025-07-11

Jung Y, Seo E, Yang S, et al (2025)

Establishment and rescue of fibroblast cell lines carrying a nonsense mutation of RB1 by CRISPR-based base editing.

Scientific reports, 15(1):25074.

Pathogenic variants of the RB1 gene have commonly been found in many cancer types, including retinoblastoma. Nonsense mutations are the most common mutation type in retinoblastoma; however, few cell lines mimic nonsense mutations in the RB1 gene that are commonly observed in patients. Here, we established retinoblastoma-like cell lines carrying mono- and bi-allelic nonsense mutations in the RB1 gene. We introduced the R552X mutation using target activation-induced cytidine deaminase base editing and successfully constructed cell lines carrying mono- and bi-allelic mutations. The model cell lines showed decreased RB1 expression at both the mRNA and protein levels, and increased cell proliferation. Furthermore, we rescued the nonsense mutation in the RB1 gene in model cell lines by converting stop codon 552 to tryptophan using an adenine base editor. This approach may be applicable for establishing cell lines with pathogenic variants found in patients and suggests a strong potential for the application of gene editing as a therapeutic strategy.

RevDate: 2025-07-11
CmpDate: 2025-07-11

Ching RW, Świst-Rosowska KM, Erikson G, et al (2025)

Forced expression of MSR repeat transcripts above a threshold limit breaks heterochromatin organisation.

Nature communications, 16(1):6420.

Mouse heterochromatin is characterised by transcriptionally competent major satellite repeat (MSR) sequences and it has been proposed that MSR RNA contributes to the integrity of heterochromatin. We establish an inducible dCas9-effector system in mouse embryonic fibroblasts, where we can modulate MSR transcription through the targeting of a dCas9-Repressor or a dCas9-Activator. With this system, we can define a threshold limit of >300-fold deregulation of MSR transcript levels, above which the structural organisation of heterochromatin becomes disrupted. MEF cells expressing MSR RNA above this threshold limit are not viable and the defects in heterochromatin organisation and chromosome segregation cannot be reverted. This study highlights the importance of restricting MSR RNA output to maintain heterochromatin integrity and relates MSR transcript levels to either physiological or pathological conditions. It also reveals that the structural organisation of heterochromatin is governed by the transcriptional chromatin state and associated MSR RNA of the MSR repeats.

RevDate: 2025-07-12
CmpDate: 2025-07-12

Hou Y, Li Y, Zheng R, et al (2025)

Leveraging protein language models for cross-variant CRISPR/Cas9 sgRNA activity prediction.

Bioinformatics (Oxford, England), 41(7):.

MOTIVATION: Accurate prediction of single-guide RNA (sgRNA) activity is crucial for optimizing the CRISPR/Cas9 gene-editing system, as it directly influences the efficiency and accuracy of genome modifications. However, existing prediction methods mainly rely on large-scale experimental data of a single Cas9 variant to construct Cas9 protein (variants)-specific sgRNA activity prediction models, which limits their generalization ability and prediction performance across different Cas9 protein (variants), as well as their scalability to the continuously discovered new variants.

RESULTS: In this study, we proposed PLM-CRISPR, a novel deep learning-based model that leverages protein language models to capture Cas9 protein (variants) representations for cross-variant sgRNA activity prediction. PLM-CRISPR uses tailored feature extraction modules for both sgRNA and protein sequences, incorporating a cross-variant training strategy and a dynamic feature fusion mechanism to effectively model their interactions. Extensive experiments demonstrate that PLM-CRISPR outperforms existing methods across datasets spanning seven Cas9 protein (variants) in three real-world scenarios, demonstrating its superior performance in handling data-scarce situations, including cases with few or no samples for novel variants. Comparative analyses with traditional machine learning and deep learning models further confirm the effectiveness of PLM-CRISPR. Additionally, motif analysis reveals that PLM-CRISPR accurately identifies high-activity sgRNA sequence patterns across diverse Cas9 protein (variants). Overall, PLM-CRISPR provides a robust, scalable, and generalizable solution for sgRNA activity prediction across diverse Cas9 protein (variants).

The source code can be obtained from https://github.com/CSUBioGroup/PLM-CRISPR.

RevDate: 2025-07-12
CmpDate: 2025-07-12

Huang L, Song Y, Li N, et al (2025)

Deletion of bikaverin and fusarubin biosynthesis gene clusters via CRISPR/Cas9 system in Fusarium fujikuroi and its effect on GA3 biosynthesis.

Journal of biotechnology, 405:229-237.

Gibberellic acid (GA3) is a critical plant hormone with significant agricultural applications, yet its production in Fusarium fujikuroi is constrained by competition for metabolic precursors, particularly acetyl-CoA, which is essential for GA3 biosynthesis. The genome of F. fujikuroi harbors numerous secondary metabolite biosynthetic gene clusters that divert acetyl-CoA away from the GA3 pathway, thereby limiting its yield. To address this challenge, we employed the CRISPR/Cas9 system to delete the bikaverin and fusarubin biosynthesis gene clusters, which are known to compete with GA3 biosynthesis for acetyl-CoA. This genetic intervention resulted in a substantial increase in GA3 production, with the ΔBIKΔFSR strain yielding 31.67 % more GA3 compared to the wild-type strain. Notably, the deletion of these gene clusters not only enhanced GA3 biosynthesis but also improved mycelial growth and carbon assimilation, as evidenced by increased consumption of reducing sugars during fermentation. We further employed qRT-PCR to assess comparative expression levels of genes associated with the glycohydrolysis, glycolysis, and the TCA pathway in engineered strain. Results indicated that removing by-product gene clusters enhances the glycohydrolase system, accelerating carbon assimilation. Given the presence of dozens of secondary metabolite biosynthetic gene clusters in the F. fujikuroi genome, the strategy reported here offers a promising avenue for further enhancing GA3 production by targeting additional non-essential gene clusters.

RevDate: 2025-07-12
CmpDate: 2025-07-12

Shimon O, Dean AM, Cohen S, et al (2025)

CRISPR-Cas9 engineering of human T regulatory cells - Design and optimization of a manufacturing process.

Molecular immunology, 184:13-21.

Regulatory T cells (Tregs) are a subset of CD4 + T cells that comprise 5-10 % of the total CD4 + T cell population. Tregs, which are critically important for the maintenance of immune tolerance and immune homeostasis, are distinguished from other subtypes of CD4 + T cells by the expression of the transcription factor FOXP3. Because of the centrality to immunoregulation, Tregs have gained increasing attention as promising targets for clinical applications in autoimmune diseases, transplant rejection and graft-versus-host disease (GvHD). However, the essential role of Tregs in the complex network of the immune system implies their targeting as a promising therapeutic approach also in other medical indications, such as neurodegenerative diseases and cancer. Our group recently published a study showing that genetically modified Tregs are capable of clearing solid malignancies in various mice models, including an aggressive triple negative breast cancer (TNBC) and prostate cancer, which provides the impetus to develop an adoptive cell therapy using Steroid Receptor Coactivator 3 (SRC-3) knock out (KO) Tregs. It is well known that isolation, genetic editing and the expansion of Tregs as a homogenous and healthy population present specific technical challenges. In this context, here we outline the development of a process for the production of SRC-3 KO human Tregs (hTregs), which can subsequently be adapted for Current Good Manufacturing Practice (cGMP) settings to facilitate clinical-scale production.

RevDate: 2025-07-12
CmpDate: 2025-07-12

Gomes D, Rodrigues JL, Scrutton NS, et al (2025)

De novo production of prenylnaringenin compounds by a metabolically engineered Escherichia coli.

Journal of biotechnology, 405:215-228.

Prenylnaringenin (PN) compounds, namely 8-prenylnaringenin (8-PN), 3'-prenylnaringenin (3'-PN), and 6-prenylnaringenin (6-PN), are reported to have several interesting bioactivities. This study aimed to validate a biosynthetic pathway for de novo production of PN in Escherichia coli. A previously optimized E. coli chassis capable of efficiently de novo producing naringenin was used to evaluate eleven prenyltransferases (PTs) for the production of PN compounds. As PT reaction requires dimethylallyl pyrophosphate (DMAPP) as extended substrate that has limited availability inside the cells, clustered regularly interspaced short palindromic repeats (CRISPR) and CRISPR-associated protein 12a (Cas12a) (CRISPR-Cas12a) was used to construct ten boosted DMAPP-E. coli strains. All the PTs, in combination with the naringenin biosynthetic pathway, were tested in these strains. Experiments in 96-well deep well plates identified twelve strains capable of producing PN. E. coli M-PAR-121 with the integration of the 1-deoxy-D-xylulose-5-phosphate synthase (DXS) gene from E. coli (EcDXS) into the lacZ locus of the genome (E. coli M-PAR-121:EcDXS) expressing the soluble aromatic PT from Streptomyces roseochromogenes (CloQ) and the naringenin biosynthetic pathway was selected as the best producer strain. After optimizing the production media in shake flasks, 160.57 µM of 3'-PN, 4.4 µM of 6-PN, and 2.66 µM of 8-PN were obtained. The production was then evaluated at the bioreactor scale and 397.57 µM of 3'-PN (135.33 mg/L) and 25.61 µM of 6-PN (8.72 mg/L) were obtained. To the best of our knowledge, this work represents the first report of de novo production of PN compounds using E. coli as a chassis.

RevDate: 2025-07-12
CmpDate: 2025-07-11

Hegeman CV, Elsharkasy OM, Driedonks TAP, et al (2025)

Modulating binding affinity of aptamer-based loading constructs enhances extracellular vesicle-mediated CRISPR/Cas9 delivery.

Journal of controlled release : official journal of the Controlled Release Society, 384:113853.

The CRISPR/Cas9 toolbox consists of modular nucleases that can be employed to efficiently modify genomic sequences with high specificity. However, delivery of the large Cas9-sgRNA ribonucleoprotein (RNP) complexes remains challenging due to their immunogenicity, size, and overall negative charge. An approach to overcome these limitations is the use of extracellular vesicles (EVs) as intracellular delivery vehicles. EVs exhibit the natural ability to carry and deliver RNA and proteins across biological barriers, and can be engineered to load and deliver a variety of biotherapeutic molecules. Previous studies have shown that efficient EV-mediated cargo delivery does not only require active loading strategies, but also benefits from strategies to release cargo from the EV membrane. Here, we load Cas9 RNP complexes into EVs by expressing sgRNAs containing MS2 aptamers (MS2-sgRNAs), alongside Cas9 and a fusion protein of CD63 and tandem MS2 coat proteins (MCPs). We demonstrate that efficient Cas9 RNP delivery can also be facilitated by modulating the binding affinity between MS2 aptamers and the MCPs. To study the effect of altering the binding affinity between the MS2 hairpin and the MCP on Cas9 RNP delivery, various mutations affecting the binding affinity were made in both the interacting MS2-hairpin and the RNA-binding domain of the MCPs. Comparing Cas9 RNP delivery of the modulated MS2-sgRNAs revealed that adapting binding affinity highly affects functional RNP delivery. Mutations resulting in high affinity did not facilitate efficient RNP delivery unless combined with a photo-inducible release strategy, showing that cargo release was a limiting factor in RNP delivery. Mutations that decreased affinity resolved this issue, resulting in Cas9 RNP delivery without the requirement of additional release strategies. However, further decreasing affinity resulted in decreased Cas9 gene-editing efficiency due to decreased levels of Cas9 RNP loading into EVs. A similar effect on functional delivery was seen after modification of the RNA-binding domain of the MCPs. Our results demonstrate that EVs are capable of functional Cas9-sgRNA complex delivery, and that modulation of binding affinity can be used to increase efficient functional delivery with non-covalent loading constructs, without the need for additional engineering strategies for cargo release.

RevDate: 2025-07-11
CmpDate: 2025-07-11

Cao D, Zhu J, Guo Y, et al (2025)

Dynamically covalent lipid nanoparticles mediate CRISPR-Cas9 genome editing against choroidal neovascularization in mice.

Science advances, 11(28):eadj0006.

As an important modality for choroidal neovascularization (CNV) treatment, intravitreal injection of vascular endothelial growth factor A (VEGFA) inhibitors suffers from undesired response rate, low patient compliance, and ocular damage. Here, dynamically covalent lipid nanoparticles (LNPs) were engineered to mediate VEGFA gene editing and CNV treatment by codelivering Cas9 mRNA (mCas9) and single guide RNA (sgRNA) targeting VEGFA (sgVEGFA). A library of lipidoids bearing iminoboronate ester linkage was developed via facile "one-pot" synthesis, and the top-performing lipidoid-A4B3C7 was formulated into LNP-A4B3C7 with the highest mRNA transfection efficiency. Inside the diseased retinal pigment epithelial cells, LNPs were dissociated upon H2O2-triggered lipidoid degradation, facilitating mRNA/sgRNA release to potentiate the gene editing efficiency. In laser-induced CNV mice, mCas9/sgVEGFA@LNP-A4B3C7 after single intravitreal injection led to pronounced VEGFA disruption and CNV area reduction, outperforming the clinical anti-VEGF drug in eliciting sustained therapeutic effect. This study establishes a robust nonviral platform for mRNA delivery and genome editing and renders a promising strategy for CNV treatment.

RevDate: 2025-07-11
CmpDate: 2025-07-11

Yan J, Dong H, Tian T, et al (2025)

Doublesex and GATAβ4 synergistically regulate the sex-dimorphic expression of storage protein 1 in Bombyx mori.

PLoS genetics, 21(7):e1011762 pii:PGENETICS-D-25-00258.

Sexually dimorphic traits are widespread in organisms and are crucial for reproduction and behavior. These traits are typically controlled by sex-specific genes. However, their regulatory mechanisms are complex and incompletely understood. In Bombyx mori, a group of sex-differential storage proteins (SPs) exists, with storage protein 1 (SP1) expressed exclusively in females. In this study, we used the CRISPR/Cas9 system to knock out the doublesex gene and found that SP1 expression was sharply upregulated in male doublesex mutants and downregulated in female doublesex mutants, which suggests that doublesex is a key factor in the sex-differential expression of SP1. Then, we revealed that the female-specific doublesex isoform (dsxF) bound to and activated the SP1 promoter more strongly than the male-specific isoform (dsxM). Meanwhile, a transcription factor named GATAβ4 was found to be involved in the regulation by doublesex. Overexpression of GATAβ4 in Bombyx mori larvae affected adult reproductive behavior and dramatically upregulated SP1 expression in males. Furthermore, GATAβ4 interacted with both dsxF and dsxM, promoting nuclear translocation of dsxM, which in turn inhibited GATAβ4 binding to the SP1 promoter. In total, we found that dsxM did not directly repress SP1 expression in males but instead cooperated with other transcription factors to regulate downstream gene expression. These findings provide new insights into the regulation of sex-specific genes and the mechanisms controlling dimorphic traits.

RevDate: 2025-07-11
CmpDate: 2025-07-11

Kim YM, Na HJ, Kwon DH, et al (2025)

Generation of NOD SCID mice with near-complete deletions of Il2rg and Prkdc for human cancer and HSC engraftment.

Transgenic research, 34(1):35.

Immunodeficient mouse models are invaluable tools for preclinical research, particularly for cancer therapies and studies of the human immune system. Notably, strains with combined Prkdc (scid) and Il2rg (null) mutations-such as NOG and NSG mice- are widely used due to their profound immunodeficiency, allowing efficient engraftment of various human cells. However, these models were generated by disrupting the Il2rg gene through replacement with a neomycin resistance (Neo) cassette in embryonic stem cells. Incomplete excision of this cassette can inadvertently alter the expression of neighboring genes, thereby introducing potential confounding variables. In addition, they may still express mutant mRNAs that escape nonsense-mediated decay (NMD) and/or produce truncated proteins with residual activity, potentially compromising the interpretation of experimental outcomes. To address this, we developed the N2G mouse strain (NOD-2-Genes KO) where almost all genomic loci of both Prkdc and Il2rg genes are deleted via CRISPR/Cas9 genome editing. N2G mice exhibited tumor growth comparable to NOG mice following the transplantation with several human cancer cell lines. Moreover, human CD34[+] cord blood (CB) cells engrafted into N2G mice showed robust reconstitution of human immune cells, especially T cells in peripheral blood, spleen and bone marrow, compared to NSG mice. These results suggest that N2G mice, lacking residual mutant mRNA and the exogenous Neo resistant gene, offer an advanced model for preclinical studies.

RevDate: 2025-07-11
CmpDate: 2025-07-11

Friberg M, Sharma S, Sitbon F, et al (2025)

Modifying the potato tuber storage protein patatin targeting improved thermal stability.

Planta, 262(2):46.

Gene editing of the patatin gene cluster using a single-guide RNA sequence consistently modifies over 10% of the targeted genes in modified individuals. Patatins have gained recent attention, as a group of highly nutritious proteins with excellent functional properties. Some techniques have been suggested for industrial-scale patatin purification, mostly as a by-product from potato starch processing. The purification process has proved to be a challenge due to the low thermostability of patatins, especially under acidic conditions. One strategy to make patatin more accessible for extraction would be to stabilize the protein structure through the introduction of point mutations. Here, we show that the tuber expression of patatin genes is dominated by a few genes from the extended gene family, most of which were predicted to be catalytically inactive. We have further evaluated the suitability of the patatin gene cluster as a target for clustered regularly interspaced repeat (CRISPR)/Cas9-based mutagenesis. In the mutation study, we show that targeting using a single single-stranded guide RNA (sgRNA) can lead to mutations in over 10% of all alleles. Finally, four patatin variants with amino acid substitutions were designed based on in silico analysis of patatin protein structure. These modified patatins were then heterologously expressed in bacteria and evaluated for increased thermostability. While none of the mutant proteins performed better than a wild-type variant, with regard to their thermal properties, one candidate proved to be less sensitive to shifting pH, making it an interesting candidate for further optimizations.

RevDate: 2025-07-11

Li Y, Tang Y, Li X, et al (2025)

Quorum Sensing Inhibits Type III-A CRISPR-Cas System Activity Through Repressing Positive Regulators SarA and ArcR in Staphylococcus Aureus.

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

CRISPR-Cas is an adaptive immune system that protects prokaryotes from the invasion of foreign genetic elements. The components and immunity mechanisms of CRISPR-Cas have been extensively studied, but the regulation of this system in Staphylococci remains unclear. Here, it is shown that the cell-cell communication, known as quorum sensing (QS), inhibits the expression and activity of the type III-A CRISPR-Cas system in S. aureus. The QS regulator, AgrA, directly binds to the promoters of two transcriptional regulators encoding the genes sarA and arcR to inhibit their expression. However, both SarA and ArcR act as positive regulators that promote the transcription of cas genes by directly binding to a novel promoter Pcas. Furthermore, the Pcas of 300 bp located in cas1 displays as a critical regulatory node to initiate the transcription of cas10 and csm3. Our data reveal a new regulatory mechanism for QS-mediated repression of the Type III-A CRISPR-Cas system, which may allow S. aureus to acquire foreign genetic elements encoding antibiotic resistance or virulence factors specifically at high cell density.

RevDate: 2025-07-11

Hua G, He C, E Zuo (2025)

SuperDecode: A versatile toolkit for mutation analysis in genome editing.

aBIOTECH, 6(2):377-380.

The CRISPR-Cas system has revolutionized modern life sciences, enabling groundbreaking applications ranging from functional genomics to therapeutic development. Despite its transformative potential, significant technical limitations persist in current computational tools for quantifying editing efficiency - particularly concerning data processing capabilities, analytical throughput, and operational flexibility. This research presents SuperDecode, a novel computational framework designed to address these methodological constraints. The SuperDecode offers key advantages, including local processing capabilities, large-size sequencing files, batch-processing, and diversified operational functions.

RevDate: 2025-07-11
CmpDate: 2025-07-11

Du J, Gong X, Huang R, et al (2025)

Harnessing CRISPR/Cas9 to overcome targeted therapy resistance in non‑small cell lung cancer: Advances and challenges (Review).

Oncology reports, 54(3):.

Targeted therapy has markedly improved outcomes for patients with non‑small cell lung cancer (NSCLC). However, the emergence of drug resistance remains a major clinical challenge, limiting long‑term treatment efficacy. Clustered regularly interspaced short palindromic repeats (CRISPR)/Cas9, a revolutionary gene‑editing technology, offers precise and efficient genetic modifications, providing new insights into the mechanisms of drug resistance in NSCLC. The present review explored the application of CRISPR/Cas9 in overcoming resistance associated with key oncogenic drivers, including EGFR, KRAS, ALK, ROS1, MET and BRAF. It summarized recent advances in CRISPR‑based strategies to reverse resistance, enhance targeted therapy effectiveness and develop potential therapeutic interventions. Additionally, it discussed current limitations, including off‑target effects, delivery challenges and ethical concerns, while highlighting future directions for clinical translation. Using CRISPR/Cas9 technology may pave the way for novel, personalized treatment approaches in NSCLC, ultimately improving patient outcome.

RevDate: 2025-07-11
CmpDate: 2025-07-11

Bourel C, Souza-Fonseca-Guimaraes F, S Lesage (2025)

Highlights of 2024: unleashing the power of NK cells-cancer's worst nightmare.

Immunology and cell biology, 103(6):526-529.

In this article for the Highlights of 2024 Series, we discuss strategies to enhance NK cell-based cancer therapies. These include (1) cytokine expression on bacterial membranes to boost NK cell activation in tumors, (2) optimizing CAR-NK cell manufacturing for improved efficacy, (3) using CRISPR-Cas9 to identify and target inhibitory genes, and (4) using tetraspecific engagers to enhance cytotoxicity and cytokine memory-like NK cells strengthening anti-tumor responses. This year's progress holds much promise for cancer treatments exploiting NK cells.

RevDate: 2025-07-10

Dai P, Huang T, Ye X, et al (2025)

K1 Klebsiella pneumoniae is more conserved than K2 for both virulence plasmid and chromosome.

BMC genomics, 26(1):652.

OBJECTIVE: To illustrate the differences between K1 and K2 Klebsiella pneumoniae strains.

METHODS: Totally 68 K1 and 99 K2 K. pneumoniae strains from GenBank were analyzed for virulence genes, sequence types (STs), restriction-modification (R-M) systems, and clustered regularly interspaced short palindromic repeat (CRISPR)-Cas systems. Phylogenetic trees of the virulence plasmids and chromosomes in the strains were built using kSNP4.

RESULTS: Virulence genes peg-344, allS, p-rmpA, p-rmpA2, c-rmpA, iroN, and iucA were more prevalent in K1 strains than K2. K1 strains were categorized into 7 STs with 79.41% being ST23 while K2 strains were categorized into 14 STs with 38.38% being ST14. K1 strains showed higher rates of CRISPR-Cas systems than K2 while lower rates of Type I and II R-M systems were found in K1 strains than K2. More rates of virulence plasmids (52/68 vs. 24/99) were found in K1 strains than K2. Based upon the phylogenetic tree of virulence plasmids, 46 in K1 strains belonged to the same clade while 11 and 7 virulence plasmids in K2 strains constituted the 2 major clades. For the chromosomes, 61 K1 strains belonged to the same clade while 99 K2 strains could be categorized into 4 major clades.

CONCLUSIONS: K1 K. pneumoniae strains are more conserved than K2 for both virulence plasmids and chromosomes. K1 strains are deficient in R-M systems but rich in CRISPR-Cas, which is contrary to K2.

RevDate: 2025-07-10
CmpDate: 2025-07-10

Imburgia C, Organick L, Zhang K, et al (2025)

Random access and semantic search in DNA data storage enabled by Cas9 and machine-guided design.

Nature communications, 16(1):6388.

DNA is a promising medium for digital data storage due to its exceptional data density and longevity. Practical DNA-based storage systems require selective data retrieval to minimize decoding time and costs. In this work, we introduce CRISPR-Cas9 as a user-friendly tool for multiplexed, low-latency molecular data extraction. We first present a one-pot, multiplexed random access method in which specific data files are selectively cleaved using a CRISPR-Cas9 addressing system and then sequenced via nanopore technology. This approach was validated on a pool of 1.6 million DNA sequences, comprising 25 unique data files. We then developed a molecular similarity-search approach combining machine learning with Cas9-based retrieval. Using a deep neural network, we mapped a database of 1.74 million images into a reduced-dimensional embedding, encoding each embedding as a Cas9 target sequence. These target sequences act as molecular addresses, capturing clusters of semantically related images. By leveraging Cas9's off-target cleavage activity, query sequences cleave both exact and closely related targets, enabling high-fidelity retrieval of molecular addresses corresponding to in silico image clusters similar to the query. These approaches move towards addressing key challenges in molecular data retrieval by offering simplified, rapid isothermal protocols and new DNA data access capabilities.

RevDate: 2025-07-10
CmpDate: 2025-07-10

Wang J, Ye X, Liu Y, et al (2025)

Regulating cleavage activity and enabling microRNA detection with split sgRNA in Cas12b.

Nature communications, 16(1):6392.

The CRISPR-Cas12b system has revolutionized molecular diagnostics, yet its reliance on single guide RNAs (sgRNAs) exceeding 100 nt limits precise regulation and applications. We present a split sgRNA strategy for Cas12b, utilizing universal components with customizable Spacer to detect various nucleic acid targets by simply replacing Spacer. Glyoxal labeling of the universal split direct repeat (DR) region represses Cas12b activity, which is restored by elevated temperatures or prolonged incubation, enabling dynamic regulation. Incorporating a photo-cleavable linker into the DR allows UV-mediated modulation, ensuring compatibility with recombinase polymerase amplification. Successful detection of Epstein-Barr virus in clinical plasma samples matched the sensitivity of traditional qPCR. Importantly, microRNAs can replace the Spacer, enabling direct detection without reverse transcription or amplification. Supported by evidence from cultured cells and plasma from healthy individuals and colorectal cancer patients, this method yields consistent results with RT-qPCR while simplifying protocols. This split strategy enhances Cas12b systems, offering a promising approach for clinical nucleic acid analysis.

RevDate: 2025-07-10
CmpDate: 2025-07-10

Ille K, S Melzer (2025)

Efficient and versatile rapeseed transformation for new breeding technologies.

The Plant journal : for cell and molecular biology, 123(1):e70330.

Many gene functions are widely studied and understood in Arabidopsis; however, the lack of efficient transformation systems often limits the application and verification of this knowledge in crop plants. Brassica napus L., a member of the Brassicaceae family, is usually transformed by Agrobacterium-mediated hypocotyl transformation, but not all growth types are equally amenable to transformation. In particular, winter rapeseed, which requires vernalization to initiate flowering, is recalcitrant to in vitro regeneration and transformation. The analysis of gene functions in rapeseed is further complicated by the allotetraploid nature of its genome and the genome triplication within the Brassica genus, which has led to the presence of a large number of gene homologs for each Arabidopsis ortholog. We have established a transformation method that facilitates the regeneration of winter rapeseed by using the WUSCHEL gene from Beta vulgaris. This allowed us to efficiently transform a winter and spring rapeseed genotype in small-scale experiments. As proof of principle, we targeted BnCLV3 and BnSPL9/15 with CRISPR/Cas9 and showed that entire gene families are effectively edited using this transformation protocol. This allowed us to simultaneously study many redundantly acting homologous genes in rapeseed. We observed mutant phenotypes for BnCLV3 and BnSPL9/15 in primary transformants, indicating that biallelic knockouts were obtained for up to eight genes. This allowed an initial phenotypic characterization to be performed already a few months after starting the experiment.

RevDate: 2025-07-10
CmpDate: 2025-07-10

Hajian M, Pirali A, Moghaddam SHH, et al (2025)

Efficient gene editing of BMP15, GDF9, and MSTN-but not the imprinted CLPG gene-in goat embryos via electrotransfection and handmade cloning.

Functional & integrative genomics, 25(1):150.

CRISPR/Cas9 technology represents a powerful tool for advancing livestock breeding by enabling precise, on-target gene edits without the genomic mixing associated with traditional introgression methods. In this study, we employed a dual gRNA-based CRISPR/Cas9 strategy to induce targeted deletions and indel mutations in both reproductive and growth-related genes. These included the metacentric genes bone morphogenetic protein 15 (BMP15) and growth differentiation factor 9 (GDF9), which are associated with increased ovulation rate and litter size, as well as the telomeric genes myostatin (MSTN) and callipyge (CLPG), which are linked to muscle development and enhanced meat production. We employed an optimized electrotransfection protocol consisting of 10-20 µg of each plasmid DNA, 250 µL OptiMEM-GlutaMAX, and one million goat fibroblast cells. The electroporation was performed using a Bio-Rad system in a 4-mm cuvette, with two 10-millisecond pulses at 270 volts, separated by a 10-second interval. This protocol enabled efficient genome editing of goat embryonic fibroblast cells, which were subsequently used to generate cloned embryos via handmade somatic cell nuclear transfer (SCNT), involving manual enucleation and cell-oocyte fusion steps. Sequencing revealed high mutation rates (78-97%) and a predominance of biallelic edits in BMP15, GDF9, and MSTN. Notably, MSTN gRNAs with a 7-bp overlapping sequence at their 3' ends showed a high editing efficiency. In contrast, the imprinted CLPG gene exhibited a significantly lower mutation rate (~ 30%), likely due to epigenetic constraints. While overall mutation rates did not differ significantly between metacentric and telomeric genes, on-target deletions were more frequent in metacentric genes (43%) than in telomeric ones (20%). Embryo development rates from gene-edited cells were comparable to those from non-edited controls. These findings underscore the utility of combining electrotransfection with SCNT for efficient editing of non-imprinted genes and highlight the need for improved strategies to overcome barriers in editing imprinted loci.

RevDate: 2025-07-10
CmpDate: 2025-07-10

Amistadi S, Fontana L, Magnoni C, et al (2025)

Dissecting the epigenetic regulation of the fetal hemoglobin genes to unravel a novel therapeutic approach for β-hemoglobinopathies.

Nucleic acids research, 53(13):.

Beta-hemoglobinopathies are severe genetic diseases caused by mutations affecting the production of the adult β-globin chain. The clinical severity is mitigated by the co-inheritance of mutations that reactivate the production of the fetal β-like γ-globin in adults. However, the epigenetic mechanisms underlying the adult-to-fetal hemoglobin (HbA-to-HbF) switching are still not fully understood. Here, we used epigenome editing technologies to dissect the molecular mechanisms underlying γ- and β-globin gene regulation and to develop novel potential therapeutics for β-hemoglobinopathies. Targeted removal of DNA methylation by dCas9-Tet1 (alone or together with the deposition of histone acetylation by CBP-dCas9) at the fetal promoters led to efficient and durable γ-globin reactivation, demonstrating that DNA methylation is a driver for HbF repression. This strategy, characterized by high specificity and a good safety profile, led to a substantial correction of the pathological phenotype in erythroid cells from patients with sickle cell disease.

RevDate: 2025-07-10
CmpDate: 2025-07-10

Zheng H, Wang B, Dong X, et al (2025)

SIRT7 deletion inhibits Glaesserella parasuis-mediated inflammatory responses in porcine alveolar macrophages.

Frontiers in cellular and infection microbiology, 15:1589199.

Glaesserella parasuis (GPS) infection causes severe inflammatory disorder, resulting in lung injury. SIRT7 is an NAD[+]-dependent deacetylase known to regulate inflammatory responses, but its role in GPS infection remains unclear. Here we found that GPS infection increased SIRT7 expression and induced inflammatory responses. Deficiency of SIRT7 by CRISPR/Cas9 technology significantly inhibited GPS-induced cytopathic effects and inflammatory responses. In addition, RNA-seq analysis showed that differentially expressed genes(DEGs) induced by SIRT7 deficiency were enriched in biological processes such as cell proliferation, actin cytoskeleton formation, lipid synthesis, protein kinase activation regulation, and GTPase activity regulation. Functional enrichment analysis further indicated the involvement of these DEGs in tight junction pathway, PI3K-Akt signaling pathway, actin cytoskeleton regulation, cGMP-PKG signaling pathway, Hippo signaling pathway, and TNF signaling pathway. Finally, we identified some hub genes (GNAI3, GNAI1, JAK1, NDUFS8, CYC1) related to oxidative phosphorylation. In summary, our results demonstrate that SIRT7 is pivotal for GPS-induced inflammatory responses, which represents a promising target resistant to GPS infection.

RevDate: 2025-07-09
CmpDate: 2025-07-10

Wulff JP, Laminack RK, MJ Scott (2025)

Genetic and behavioral analyses suggest that larval and adult stages of Lucilia cuprina employ different sensory systems to detect rotten beef.

Parasites & vectors, 18(1):270.

BACKGROUND: The blowfly Lucilia cuprina is a destructive parasite of sheep that causes flystrike or myiasis. Larvae consume the animal's living flesh, producing large wounds that can lead to death. The main aim of this study was to identify genes that may play important roles in the behavior and physiology of L. cuprina larvae.

METHODS: An RNA-Seq analysis of RNA from whole larvae at different developmental stages and third-instar head and gut tissues was used to identify sensory receptors and other genes relevant to the physiology of L. cuprina larvae. In addition, CRISPR/Cas9 gene editing was used to obtain a loss-of-function mutation for the L. cuprina odorant coreceptor gene (LcupOrco). The response of mutant larvae and adult females to fresh and rotten meat at different temperatures was evaluated.

RESULTS: The RNA-Seq analysis suggested that odorant (OR), gustatory, ionotropic, and Pickpocket receptors may not play a central role in the L. cuprina larval sensory signaling and digestive systems. Rather, ATP-binding cassettes (ABCs) were highly enriched in head and gut RNA, and odorant-binding proteins (OBPs) only in the head. To confirm that ORs are not essential for larval detection of rotten beef, diet-choice assays were performed including larvae and adults homozygous for a null mutation in LcupOrco. While the attraction of adult females to rotten beef was disrupted, LcupOrco mutant larvae showed no change in diet preference.

CONCLUSIONS: The expression pattern of the ABC and OBP gene families suggests a central role in the sensory system of the L. cuprina larva for these receptors. Behavioral assays showed that ORs are essential for the adult female response to rotten beef, but not for larval behavior. These findings are consistent with high levels of expression of LcupOrco in the adult female antenna but very low expression in larvae.

RevDate: 2025-07-09
CmpDate: 2025-07-10

Tian Y, Bao X, Lei S, et al (2025)

In vivo CRISPR screening identifies POU3F3 as a novel regulator of ferroptosis resistance in hepatocellular carcinoma via retinoic acid signaling.

Cell communication and signaling : CCS, 23(1):329.

BACKGROUND: Sorafenib, a ferroptosis agonist, is a first-line treatment for advanced hepatocellular carcinoma (HCC). However, its clinical efficacy is limited due to drug resistance, resulting in modest improvements in patient survival. Hence, the present study has been designed to identify critical molecular targets associated with sorafenib resistance and investigate the potential inhibitors in overcoming this therapeutic challenge.

METHODS: In vivo whole-genome CRISPR/Cas9 library screens were conducted to identify resistance factors to ferroptosis agonists, such as RSL3 and sorafenib, in HCC. The effects and underlying molecular mechanisms of these resistance factors were investigated in HCC cells using ferroptosis detection assays, xenograft tumor models, chromatin immunoprecipitation (ChIP), and dual-luciferase reporter assays. Potential inhibitors targeting these factors were evaluated through computer-aided virtual screening, molecular dynamics simulations, surface plasmon resonance analysis, and functional evaluations.

RESULTS: A retinoic acid metabolism gene cluster, including ADH4, ALDH1A1, ALDH1A3, FABP5, RBP1, and RDH10, was found demonstrating upregulation in HCC cells treated with ferroptosis agonist, sorafenib. This gene cluster contributes to the ferroptosis resistance by producing the strong reducing agent retinoic acid. The transcription factor POU3F3 was identified as a key regulator for the retinoic acid metabolism gene cluster, which simultaneously binds to their promoters, increasing their transcription and promoting retinoic acid production. Knockdown of POU3F3 significantly enhanced the pro-ferroptotic and inhibitory effects of sorafenib on HCC cells by suppressing retinoic acid metabolism. Furthermore, rosarin was identified as a POU3F3 inhibitor, with an equilibrium dissociation constant of 7.57 µM, and demonstrated a synergistic effect with sorafenib against HCC cells both in vitro and in vivo.

CONCLUSIONS: According to the results, POU3F3 acts as a protective regulator against sorafenib-induced ferroptosis in HCC cells by enhancing the transcription of multiple retinoic acid metabolism genes and promoting retinoic acid production. The POU3F3 inhibitor, rosarin, shows potential as an ideal candidate for overcoming sorafenib resistance in HCC.

RevDate: 2025-07-10
CmpDate: 2025-07-10

Sun M, Ni C, Li A, et al (2025)

A biomimetic nanoplatform mediates hypoxia-adenosine axis disruption and PD-L1 knockout for enhanced MRI-guided chemodynamic-immunotherapy.

Acta biomaterialia, 201:618-632.

Malignant melanoma is an extremely aggressive and fatal form of skin cancer due to the limited efficacy of conventional therapies. While immune checkpoint blockade therapy and chemodynamic therapy (CDT) have emerged as promising strategies for melanoma treatment, their effectiveness is compromised by the immunosuppressive and complex tumor microenvironment (TME). Here, cancer cell membrane-camouflaged nanoplatforms (PPMC@CM) were developed to co-deliver the CRISPR/Cas9-PD-L1 system and manganese dioxide nanoparticles (MnO2 NPs) for magnetic resonance imaging (MRI)-guided CDT and enhanced immunotherapy. The formed PPMC@CM could efficiently accumulate at tumor sites by homologous targeting, generate O2 to relieve hypoxia, and deplete glutathione (GSH) to enhance Mn[2+]-mediated Fenton-like reactions for enhanced CDT. Meanwhile, CRISPR/Cas9-mediated PD-L1 knockout effectively suppressed the PD-L1 expression, while hypoxia relief attenuated the immunosuppressive hypoxia-CD39/CD73-adenosine (ADO) pathway, thereby boosting the PD-L1-mediated immunotherapy. In vivo experimental results demonstrated that PPMC@CM nanoplatform could efficiently inhibit the growth and metastasis of melanoma by enhanced CDT and amplified immunotherapy, and provide targeted MRI of tumors. This work presents a novelty strategy to design biomimetic theranostic nanoplatform for melanoma by the combination of CDT and improved immunotherapy with CRISPR/Cas9-PD-L1 system and hypoxia-ADO axis inhibition. STATEMENT OF SIGNIFICANCE: Malignant melanoma is a highly aggressive and treatment-refractory skin cancer, where conventional therapies exhibit limited efficacy and immune checkpoint blockade (ICB) is often compromised by the immunosuppressive tumor microenvironment (TME). To address these challenges, we developed a biomimetic nanoplatform (PPMC@CM) to codeliver MnO2 nanoparticles and the CRISPR/Cas9-PD-L1 gene-editing system for MRI-guided chemodynamic therapy and enhanced immunotherapy. The PPMC@CM nanoplatform could efficiently accumulate at tumor sites by homologous targeting and relieve hypoxia to suppress the hypoxia-CD39/CD73-adenosine immunosuppressive axis. Additionally, the CRISPR/Cas9-mediated PD-L1 knockout significantly suppresses PD-L1 expression, thereby boosting ICB efficacy. Moreover, PPMC@CM could deplete glutathione in the TME to amplify Mn[2+]-mediated Fenton-like reactions for enhanced chemodynamic therapy. This research represents a promising theranostic nanoplatform for melanoma by combining chemodynamic therapy and immunotherapy.

RevDate: 2025-07-10
CmpDate: 2025-07-10

Wang C, Wang Q, Jin Y, et al (2025)

Lambda exonuclease assisted helicase-dependent amplification CRISPR/Cas12a detection of Listeria monocytogenes.

Biochimie, 235:106-112.

We describe the construction of a protospacer adjacent motif-free CRISPR/Cas12a fluorescent biosensor based on lambda exonuclease (λ-exo) and helicase-dependent amplification (HDA) to detect Listeria monocytogenes(L. monocytogenes). The hlyA gene of L. monocytogenes was amplified by HDA. After λ-exo catalyzed cleavage of 5' phosphorylated single-stranded DNA of amplification product double-stranded DNA, the double-stranded DNA formed single-stranded DNA (ssDNA). The ssDNA as a substrate activated the trans-cleavage capability of CRISPR/Cas12a to cleave the reporter gene to produce fluorescence signals. Under optimized experimental conditions, the lower limit of L. monocytogenes detection by the fluorescent biosensor was 11.5 CFU/mL, with a linear range of detection from 10[1] to 10[7] CFU/mL. The fluorescent biosensor permits simple and sensitive detection of L. monocytogenes and provides a promising analysis platform for clinical diagnosis and biomedical research without protospacer adjacent motif sequence ssDNA.

RevDate: 2025-07-09

Asumadu P, Guo Z, Qi S, et al (2025)

Programmable DNA aptamer logic gates: from structural design to integrated systems for intelligent nanoscale biosensors.

Analytical and bioanalytical chemistry [Epub ahead of print].

DNA aptamer-based logic gates represent significant advances in molecular computing, enabling complex biological computations at the nanoscale. These systems leverage the unique programmable properties of DNA aptamers-short, single-stranded oligonucleotides with high specificity and binding affinity for diverse applications across fields such as clinical diagnostics, food/environmental monitoring, and targeted therapeutic delivery, garnering significant research interest in the past few decades. In this review, we first expand on the fundamentals of aptamers, including its SELEX process and post-SELEX modifications. We systematically examine the design principles and operation mechanisms of DNA aptamer-based logic gates, mainly AND, OR, INHIBIT and NOT as reported by researchers. Then, we highlight various logic gates based on different oligonucleotides spanning from intact and split aptamers to DNA origami architectures, DNA nanorobots, and G-quadruplex structural switches, bringing to light their applications across various fields. Recent innovations in multi-input/output gate cascades, CRISPR-Cas-integrated systems and signal amplification approaches are highlighted as key developments in DNA aptamer-based logic gates. Finally, we elucidate challenges relating to DNA aptamer-based systems such as aptamer performance, cross-reactivity in complex multi-input systems and the complexities of merging other systems to amplify output readability, among others, to the end that in addressing these challenges, we will be able to unlock the full potential of this system.

RevDate: 2025-07-09

Thi Pham N, Wang CH, Chen CH, et al (2025)

Integration of CRISPR/Cas12a and a Fiber Optic Particle Plasmon Resonance Sensor for Single Nucleotide Polymorphism Detection in an Aldehyde Dehydrogenase 2 Gene.

ACS sensors [Epub ahead of print].

The highly prevalent single nucleotide polymorphism (SNP, rs671) of the aldehyde dehydrogenase (ALDH2) gene in Asian populations instigates various human pathologies and thus accentuates the urgent need for effective diagnostic tools. In this study, we present an ultrasensitive biosensing method by a combination of clustered regularly interspaced short palindromic repeats (CRISPR)/Cas12a with the fiber optic nanogold-linked sorbent assay (FONLISA) for precise SNP identification. This method leverages the sequence-specific recognition capability of the CRISPR/Cas system and the ultrahigh sensitivity via the dual signal enhancement mechanisms by integrating the trans-cleavage mechanism of Cas12a to amplify the signal from an activity reporter and the subsequent waveguide-enhanced nanoplasmonic absorption by a signaling reporter. In this method, Cas12a targets a double-stranded DNA from the ALDH2 SNP and then activates the degradation of the activity reporter, a free biotin-labeled single-stranded DNA probe (ssDNA[b]), by trans-cleavage. An unhybridized complementary single-stranded DNA probe (ssDNA[c]) labeled with a gold nanoparticle (AuNP) as the signaling reporter (AuNP@ssDNA[c]) is subsequently released and captured by the immobilized ssDNA[b] on the fiber core surface, resulting in a detectable nanoplasmonic absorption signal. The method also utilized an indispensable nanoplasmonic signal generator, carboxymethyl dextran-coated AuNP, to improve the preparation and bioconjugation processes. The CRISPR-FONLISA system demonstrates the ability to analyze the ALDH2 rs671 SNP from double-stranded DNA with a limit of detection of 71 aM. Furthermore, both cell lines and unamplified DNA extracted from blood samples were conducted to verify the system accuracy for ALDH2 rs671 SNP detection.

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

Yi JY, Choi H, Kim M, et al (2025)

High-throughput multiplexed gene and cell doping analysis through CRISPR-Cas12a system integrated with blood direct PCR.

Science advances, 11(28):eadv7234.

Advancements in gene and cell therapies introduce "gene and cell doping," requiring efficient and sensitive detection methods. Here, we report a high-throughput multiplexed gene and cell doping analysis (HiMDA) using CRISPR-Cas12a system integrated with blood direct polymerase chain reaction (PCR). Blood direct PCR enables simultaneous amplification of multiple exogenous genes directly from whole-blood samples. Coupled with sequence-specific DNA recognition and fluorescence reporter system, HiMDA achieves multiplexed, on-target detection of doping genes and cells. Our results demonstrate HiMDA's feasibility with only 5 microliters of blood required for the entire 90-minute process. HiMDA exhibits exceptional sensitivity, detecting as few as 2.5 copies of doping target genes from blood-four times more sensitive than current anti-doping standards-and identifying in vivo doping up to 10 days. These findings highlight HiMDA's robust high-throughput, multiplexed capabilities, satisfying the sensitivity and selectivity demands of anti-doping research. HiMDA offers a flexible solution to meet future doping detection challenges.

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

Pal P, Gao S, Gao H, et al (2025)

Establishment of a reverse genetics system for studying human immune functions in mice.

Science advances, 11(28):eadu1561.

Reverse genetics approaches in mice are widely used to understand gene functions and their aberrations in diseases. However, limitations exist in translating findings from animal models to human physiology. Humanized mice provide a powerful bridge to understanding human physiology and mechanisms of disease pathogenesis while maintaining the feasibility of working with small animals. Methods for generating humanized mouse models that allow scientists to probe contributions of particular genes have been rudimentary. Here, we established an efficient method for generating genetically modified human cord blood-derived CD34[+] cells for transplantation, resulting in humanized mice with near-complete loss of specific gene expression by the human immune system. Mice transplanted with Cas9-edited human CD34[+] cells recapitulate functional consequences of specific gene losses in the human immune system. Our approach enables targeted gene knockouts in humanized mice, offering a valuable tool for human gene function studies in vivo.

RevDate: 2025-07-09

Chao A, Wang J, Xiu L, et al (2025)

CRISPR/Cas-Based Biosensing Strategies for Non-Nucleic Acid Contaminants in Food Safety: Status, Challenges, and Perspectives.

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

Non-nucleic acid targets (non-NATs), such as heavy metals, toxins, and pesticide residues, pose critical threats to food safety. Although CRISPR/Cas systems were initially developed for nucleic acid detection, recent advances have enabled their adaptation to non-NATs analysis by transducing target recognition into nucleic acid signals. Unlike previous reviews categorized by target type, this work establishes a mechanism-centric framework, systematically classifying non-NAT-to-nucleic acid signal conversion methodologies into three paradigms: (1) aptamer-based systems, (2) catalytic nucleic acid-based methods (e.g., DNAzymes), and (3) protein-mediated strategies (e.g., antibodies, transcription factors). When integrated with CRISPR/Cas, these systems achieve rapid, sensitive detection at picomolar (pM) levels without relying on chromatographic or spectroscopic instruments. Furthermore, we critically discuss challenges, including the limited diversity of recognition elements, inefficient signal conversion, and inflexible signal outputs, proposing solutions including synthetic-biology-driven bioreceptor design and artificial-intelligence-based data analysis. By bridging mechanistic principles with applications in complex food matrices, this review provides actionable insights to advance CRISPR-based tools for rapid, on-site, food safety monitoring.

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

Wang S, Zheng J, Zhang X, et al (2025)

Genome-Wide CRISPR-Cas9 Knockout Screening Identifies Genes Modulating Cisplatin-Induced Cytotoxicity in Renal Proximal Tubule Epithelial Cells.

FASEB journal : official publication of the Federation of American Societies for Experimental Biology, 39(13):e70780.

Cisplatin is widely used as a first-line chemotherapy drug for various cancers. However, cisplatin-induced nephrotoxicity (CIN) greatly restricts its application. Renal proximal tubular epithelial cells (RPTECs) can be extensively damaged during CIN. However, it still lacks an ideal method to prevent CIN, because the mechanism and therapeutic targets of CIN remain largely unclear. In the present study, we used a genome-scale CRISPR-Cas9 knock-out method to functionally screen key genes of cisplatin-induced RPTEC injury. We found 815 genes significantly enriched (p < 0.05) from positive selection screening strategy, which may synergistically enhance cisplatin cytotoxicity in RPTECs. Importantly, we identified ERAP2 as a novel molecule associated with CIN. We found that the expression of ERAP2 in RPTECs was significantly up-regulated by cisplatin. Data from CCK-8 assay and flow cytometry showed that inhibition of ERAP2 alleviated cisplatin-induced RPTEC injury. Furthermore, RNA-seq and qPCR results revealed that three necroptosis-associated genes, PLA2G4C, HIST1H2AC, and HIST1H2AM, were downregulated following ERAP2 inhibition, suggesting that ERAP2 may be a novel therapeutic target of CIN through the modulation of necroptosis pathway.

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

Lokya V, Singh S, Chaudhary R, et al (2025)

Emerging trends in transgene-free crop development: insights into genome editing and its regulatory overview.

Plant molecular biology, 115(4):84.

Genome editing tools have revolutionized plant biology research offering unparalleled applications for genome manipulation and trait improvement in crops. Adopting such advanced biotechnological tools is inevitable to meet increasing global food demand and address challenges in food production, including (a)biotic stresses and inadequate nutritional value. Despite reliance on conventional genetic manipulation methods, the CRISPR-Cas-mediated genome editing toolbox allows precise modification of DNA/RNA in a target organism's genome. So far, CRISPR-Cas has been widely used to enhance yield, quality, stress tolerance, and nutritional value in various food crops. However, challenges such as reagent delivery in suitable explants, precise editing with minimal off-target effect, and generating transgene-free plants persist as major bottlenecks in most plant species. Components of CRISPR-Cas construct mainly Cas, guide RNA (gRNA), and selectable marker genes are often integrated into the host genome, which raises regulatory concerns. However, adapting advanced gene-editing strategies, including high-efficiency Cas endonucleases, DNA-independent RNP delivery, morphogenetic regulators, and grafting-mediated editing, are paving the way for transgene-free crop improvement while easing biosafety regulations. Further, regulatory frameworks for genome-edited crops vary globally, with several countries accepting them and others debating their legal status. Hence, the disparity in global regulatory guidelines of genome editing curbs commercialization. The current review highlights the emerging CRISPR-mediated tools or methods and their applications in developing transgene-free designer crops to harness the benefits of advanced genome manipulation.

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

Thomas L, T Abraham (2025)

Disabling iron uptake and pilus assembly in uropathogenic Escherichia coli using CRISPR-Cas9: a step towards antivirulence therapy.

Antonie van Leeuwenhoek, 118(8):110.

Uropathogenic Escherichia coli (UPEC) is the leading cause of urinary tract infections (UTIs), driven by virulence factors such as iron acquisition systems and adhesive pili. In this study, we employed CRISPR-Cas9-mediated genome editing to functionally inactivate two critical virulence genes-iucD, involved in aerobactin-mediated iron uptake, and papC, encoding the outer membrane usher protein essential for P pilus assembly. Using a clinical UPEC isolate, we introduced premature stop codons via homologous repair templates guided by gene-specific single-guide RNAs. Colony PCR and Sanger sequencing confirmed precise site-specific editing, leading to truncated protein variants. In silico analyses using InterPro and Swiss-Model revealed a complete loss of essential domains in both proteins. Molecular docking studies demonstrated a marked reduction in binding affinities of truncated iucD for NAD(P)H and impaired protein-protein interaction between truncated PapC and PapG. This study highlights the utility of CRISPR-Cas9 as a powerful tool for dissecting bacterial pathogenesis and supports the potential of targeting virulence determinants like iucD and papC as part of an antivirulence strategy for managing UPEC infections.

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

He C, Zhu W, Zhang X, et al (2025)

Sensitive and Visualized Detection of Hantavirus Using CRISPR/Cas12a Based on AutoCORDSv2 Design.

Journal of medical virology, 97(7):e70460.

In recent years, detection technologies based on the CRISPR/Cas12a method have been extensively utilized in the fields of nucleic acid, enzyme, and macromolecule detection, thereby reinforcing their significant role in the detection landscape. Enhancing the simplicity of design, efficiency, and automation of the CRISPR/Cas12a detection system is essential for advancing its application in diagnostics. Recently, we developed an automated CRISPR/Cas12a design system named AutoCORDSv2. This system can process published genomic sequences of pathogenic bacteria in a high-throughput manner and automatically generate conserved and highly specific crRNA sequences, along with primer sequences for target amplification. This capability facilitates the specific and precise design of the CRISPR/Cas12a detection system. In this study, crRNAs targeting the Hantaan virus (HTNV) and Seoul virus (SEOV), as well as RT-PCR primers and RT-RPA primers, were designed using AutoCORDSv2. The experimental results demonstrated that the CRISPR/Cas12a system, automatically designed by AutoCORDSv2, was specific for the detection of both the HTNV and SEOV, with no cross-reactivity observed with other pathogens. The detection sensitivity reached 6 copies/μL (equivalent to 111 copies per amplification reaction), whether measured by a microplate reader or directly observed with the naked eye. The detection results for 50 samples were consistent with those obtained from commercial RT-qPCR kits, indicating high precision. Furthermore, the CRISPR/Cas12a system designed by AutoCORDSv2 can also be utilized for the development of a single-tube detection system with a sensitivity of 42 copies per reaction. This system combined with a 5-min extraction step and RT-RPA, further underscoring its potential for application.

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

Pan K, Zeng A, Ruan X, et al (2025)

The apicoplast localized isocitrate dehydrogenase is needed for de novo fatty acid synthesis in the apicoplast of Toxoplasma gondii.

Frontiers in cellular and infection microbiology, 15:1542122.

Toxoplasma gondii (T. gondii), an apicomplexan parasite, infects a wide range of warm-blooded animals and poses significant risks to human health. The fatty acid synthesis II (FASII) pathway in the apicoplast, which is the major source of fatty acids in parasites, is considered a potential drug target. The apicoplast also harbors some enzymes of central carbon metabolism, which are crucial for its survival, but their biological roles remain unclear. In this study, we focused on apicoplast-localized isocitrate dehydrogenase 1 (ICDH1) and deleted it using CRISPR-Cas9 technology. The Δicdh1 mutant tachyzoites displayed markedly impaired growth kinetics, with further suppression under serum-deprived conditions. However, this deletion did not affect the viability or virulence of the Δicdh1 mutant in mice. NADPH, a product of ICDH1-mediated decarboxylation of isocitrate, is an essential cofactor for fatty acid synthesis. Using [13]C6 glucose as a metabolic carbon source, we showed that the mutant strains had reduced incorporation of glucose-derived carbons into medium-chain length fatty acids (C14:0 and C16:0). Additionally, the growth of the mutant was partially restored by supplementation with exogenous C14:0 and C16:0 fatty acids. These results indicate that ICDH1 deletion affects the FASII pathway and parasite growth. Consistent with previous studies, this study confirms that T. gondii has metabolic flexibility in the apicoplast that allows it to acquire fatty acids through various pathways.

RevDate: 2025-07-08
CmpDate: 2025-07-09

Gou F, Liu D, Gong C, et al (2025)

Development of an efficient heterologous protein expression platform in Aspergillus niger through genetic modification of a glucoamylase hyperproducing industrial strain.

Microbial cell factories, 24(1):160.

BACKGROUND: Aspergillus niger is widely used in industrial enzyme production due to its strong secretion capacity and the status of generally recognized as safe (GRAS). However, heterologous protein expression in A. niger is frequently constrained by high levels of background endogenous protein secretion, limited access to native high transcription loci, and limitations in the efficiency of the secretory machinery. To address these limitations, this study genetically engineered a chassis strain based on an industrial glucoamylase-producing A. niger strain AnN1 for constructing the improved heterologous protein expression.

RESULTS: In this study, by using CRISPR/Cas9-assisted marker recycling, we deleted 13 of the 20 copies of the heterologous glucoamylase TeGlaA gene and disrupted the major extracellular protease gene PepA, resulting in the low-background strain AnN2. Compared to the parental strain AnN1, AnN2 exhibited 61% less extracellular protein and significantly reduced glucoamylase activity, while retaining multiple transcriptionally active integration loci. Four diverse proteins were integrated into the high-expression loci originally occupied by the TeGlaA gene in the chassis AnN2. These recombinant protein included a homologous glucose oxidase (AnGoxM), a thermostable pectate lyase A (MtPlyA), a bacterial triose phosphate isomerase (TPI), and a medical protein Lingzhi-8 (LZ8). All target proteins were successfully expressed and secreted within 48-72 h, with yields ranging from 110.8 to 416.8 mg/L in 50 mL shake-flasks cultivation. The enzyme activities of AnGoxM, MtPlyA and TPI reached ~ 1276 - 1328 U/mL, ~ 1627. 43 - 2105.69 U/mL, and ~ 1751.02 to 1906.81 U/mg after 48 h, respectively. Additionally, Overexpression of Cvc2, a COPI vesicle trafficking component, further enhanced MtPlyA production by 18%, highlighting the benefit of combining transcriptional and secretory pathway engineering.

CONCLUSIONS: Our results demonstrated that the chassis AnN2 served as a robust, modular, and time-efficient platform for heterologous protein expression in A. niger. Through site-specific integration of target genes into native high-expression loci and strategic modulation of the secretory pathway, we successfully enabled the rapid production of functional enzymes and bioactive proteins from diverse origins. This dual-level optimization strategy, which integrates rational genomic engineering with targeted enhancement of the secretory pathway, enabled high-yield expression while minimizing background interference. Together, these findings offer a practical framework for constructing versatile fungal expression systems and highlight the potential of combining genetic and cellular engineering to improve recombinant protein production in filamentous fungi.

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

Sreekanth V, Jan M, Zhao KT, et al (2025)

A Molecular Glue Approach to Control the Half-Life of CRISPR-Based Technologies.

Journal of the American Chemical Society, 147(27):23844-23856.

Cas9 is a programmable nuclease that has furnished transformative technologies, including base editors and transcription modulators (e.g., CRISPRi/a), but several applications of these technologies, including therapeutics, mandatorily require precision control of their half-life. For example, such control can help avert any potential immunological and adverse events in clinical trials. Current genome editing technologies to control the half-life of Cas9 are slow, have lower activity, involve fusion of large response elements (>230 amino acids), utilize expensive controllers with poor pharmacological attributes, and cannot be implemented in vivo on several CRISPR-based technologies. We report a general platform for half-life control using the molecular glue, pomalidomide, that binds to a ubiquitin ligase complex and a response-element bearing CRISPR-based technology, thereby causing the latter's rapid ubiquitination and degradation. Using pomalidomide, we were able to control the half-life of large CRISPR-based technologies (e.g., base editors and CRISPRi) and small anti-CRISPRs that inhibit such technologies, allowing us to build the first examples of on-switch for base editors. The ability to switch on, fine-tune, and switch-off CRISPR-based technologies with pomalidomide allowed complete control over their activity, specificity, and genome editing outcome. Importantly, the miniature size of the response element and favorable pharmacological attributes of the drug pomalidomide allowed control of activity of base editor in vivo using AAV as the delivery vehicle. These studies provide methods and reagents to precisely control the dosage and half-life of CRISPR-based technologies, propelling their therapeutic development.

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

Butti P, Bellusci F, Brambilla E, et al (2025)

Genomically integrated cassettes swapping: bringing modularity to the strain level in Saccharomyces cerevisiae.

FEMS yeast research, 25:.

A large variety of synthetic biology toolkits for the introduction of multiple expression cassettes is available for Saccharomyces cerevisiae. Unfortunately, none of these tools is designed to allow the modification - exchange or removal - of the cassettes already integrated into the genome in a standardized way. The application of the modularity principle therefore ends to the steps preceding the final host engineering, making microbial cell factories construction stiff and strictly sequential. In this work, we describe a system that easily allows CRISPR-mediated swapping or removal of previously integrated cassettes, thus bringing the modularity to the strain level, enhancing the possibility of modifying existing strains with a reduced number of steps. In the system, each cassette is tagged with specific barcodes, which can be used as targets for CRISPR nucleases (Cas9 and Cas12a), allowing the excision of the construct from the genome and its substitution with another expression cassette or the restoration of the wild type locus in one single standardized step. The system has been applied to the previously developed Easy-MISE toolkit and tested by swapping fluorescent protein expression cassettes with an efficiency of ∼90% quantified by PCR and flow cytometry.

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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.

ESP Support

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.

ESP Rationale

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.

ESP Usage

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.

ESP Plans

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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CRISPR-Cas

By delivering the Cas9 nuclease, complexed with a synthetic guide RNA (gRNA) into a cell, the cell's genome can be precisely cut at any desired location, allowing existing genes to be removed and/or new ones added. That is, the CRISPR-Cas system provides a tool for the cut-and-paste editing of genomes. Welcome to the brave new world of genome editing. R. Robbins

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Papers in Classical Genetics

The ESP began as an effort to share a handful of key papers from the early days of classical genetics. Now the collection has grown to include hundreds of papers, in full-text format.

Digital Books

Along with papers on classical genetics, ESP offers a collection of full-text digital books, including many works by Darwin and even a collection of poetry — Chicago Poems by Carl Sandburg.

Timelines

ESP now offers a large collection of user-selected side-by-side timelines (e.g., all science vs. all other categories, or arts and culture vs. world history), designed to provide a comparative context for appreciating world events.

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Biographical information about many key scientists (e.g., Walter Sutton).

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Bibliographies on several topics of potential interest to the ESP community are automatically maintained and generated on the ESP site.

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