Search Results (330)

Engineering of a bifunctional enzyme that combines DNA-dependent DNA polymerase and reverse transcriptase (RT) activities is a highly promising biotechnological goal, as it would enable one-enzyme RT-PCR. For this purpose, we selected the high-fidelity Pyrococcus furiosus (Pfu) DNA polymerase as engineering scaffold. The selection of amino acid residues for replacement was carried out based on a multi-sequence alignment of diverse DNA polymerases and literature data, which allowed us to target amino acids, which presumably are triggers of the RT activity appearance. Six mutant variants of the Pfu enzyme were created and their activity was analyzed. Through enzymatic screening, we identified the Pfu-M6 variant, which exhibits dual DNA-dependent and RNA-dependent DNA polymerase activity. This thermostable enzyme retains its inherent DNA polymerase function and has acquired the ability to catalyze reverse transcription under standard PCR conditions, which allows the created mutant form to be used for efficient amplification of DNA starting from an RNA template. Full article

(1) Background: This study aims to systematically identify key candidate genes and the regulatory networks governing ovarian development in sheep breeds with divergent fecundity. Focusing on elucidating the central regulatory roles of these factors during distinct ovarian developmental stages in highly prolific breeds, the research seeks to reveal the mechanism by which multilevel regulatory networks synergistically determine ewe reproductive capacity. (2) Methods: This study utilized the ovaries from the low-fecundity sheep breed Ujumqin sheep, the high-fecundity breed small-tailed Han sheep, and various developmental stages of small-tailed Han sheep as research subjects. Through whole-transcriptome sequencing analysis, differentially expressed mRNAs(DEGs) and non-coding RNAs (ncRNAs) were screened, and a ceRNA regulatory network was constructed and subjected to bioinformatic analysis. The dual-luciferase reporter gene detection system was employed to validate the targeting relationships within the obtained key circRNA-miRNA-mRNA networks. Finally, qRT-PCR was used to verify the accuracy of the sequencing results. (3) Results: Our analysis constructed two distinct ceRNA networks: one from different fecundity groups (116 DECs, 46 DEMs, 82 DEGs) and another from different ovarian stages (186 DECs, 143 DEMs, 338 DEGs). Functional enrichment revealed key reproduction-related pathways, including Mitogen-Activated Protein Kinase(MAPK), Janus Kinase-Signal Transducer and Activator of Transcription(JAK-STAT), and WNT signaling in the fecundity comparison, and MAPK, Ras, WNT, Hippo signaling in the developmental stage comparison. Integrated analysis identified a core circRNA-miRNA-mRNA network, pinpointing circRNA2058-miR-9226-5p-MET as a central regulatory axis. The dual-luciferase assay confirmed that circRNA2058 acts as a sponge for miR-9226-5p, thereby mediating MET expression. qRT-PCR validation of randomly selected RNAs confirmed the sequencing reliability. (4) Conclusions: this study deciphers a synergistic regulatory network and identifies, for the first time, the pivotal circRNA2058-miR-9226-5p-MET ceRNA axis as an potential critical molecular switch driving follicular dominance in sheep. This discovery provides a molecular foundation for targeting core regulators of ovine reproductive efficiency and offers significant insights for innovative strategies in enhancing sheep reproduction. Full article

In 2019, bacterial canker caused by Pseudomonas syringae pv. actinidiae was first identified in Actinidia arguta. This disease has led to significant yield reduction, plant mortality, and substantial economic losses in A. arguta cultivation. Its emergence poses a novel challenge to the sustainable global production of kiwifruit. Currently available treatments for bacterial canker caused by P. syringae pv. actinidiae are scarce. Moreover, the environmental toxicity of copper-based compounds and emerging antibiotic resistance issues necessitate the development of eco-friendly control strategies. Disease management strategies based on biocontrol bacteria have shown broad application prospects. In this study, the isolate CHHM-1 with significant antagonistic activity against P. syringae pv. actinidiae was isolated from the rhizosphere soil of healthy A. arguta. It was identified as Pseudomonas koreensis through 16S rRNA gene and whole-genome sequencing. Genomic analysis revealed that the isolate CHHM-1 harbors various genes related to biocontrol, plant growth promotion, and antibiotic resistance, suggesting strong environmental adaptability and functional potential. Furthermore, the strain exhibited multiple plant growth-promoting traits, such as nitrogen fixation, phosphate solubilization, siderophore production, and synthesis of indole-3-acetic acid (IAA). In vitro antagonism assays confirmed the strong antagonistic activity of the isolate CHHM-1 against P. syringae pv. actinidiae. A dual-culture plate assay showed an average inhibition zone of 4.36 cm, while preventive application on plants significantly reduced lesion length to 1.3 mm (vs. 6.2 mm control) in shoots and lesion area to 10% (vs. 80% control) in leaf discs. Further antibacterial tests revealed that its inhibitory mechanism is attributed to secreted antimicrobial substances. These findings provide a promising candidate for developing novel biopesticides to combat P. syringae pv. actinidiae variants, reduce chemical dependency, and foster sustainable A. arguta production. Full article

Single-cell RNA sequencing (scRNA-seq) has revolutionized genomic investigations by enabling the exploration of gene expression heterogeneity at the individual cell level. However, the complexity of scRNA-seq data analysis remains a challenge for many researchers. Here, we present OmniCellX, a browser-based tool designed to simplify and streamline scRNA-seq data analysis while addressing key challenges in accessibility, scalability, and usability. OmniCellX features a Docker-based installation, minimizing technical barriers and ensuring rapid deployment on local machines or clusters. Its dual-mode operation (analysis and visualization) integrates a comprehensive suite of analytical tools for tasks such as preprocessing, dimensionality reduction, clustering, differential expression, functional enrichment, cell–cell communication, and trajectory inference on raw data while enabling alternative interactive and publication-quality visualizations on pre-analyzed data. Supporting multiple input formats and leveraging the memory-efficient data structure for scalability, OmniCellX can efficiently handle datasets spanning millions of cells. The platform emphasizes user flexibility, offering adjustable parameters for real-time fine-tuning, alongside extensive documentation to guide users at even beginner levels. OmniCellX combines an intuitive interface with robust analytical power to perform single-cell data analysis and empower researchers to uncover biological insights with ease. Its scalability and versatility make it a valuable tool for advancing discoveries in cellular heterogeneity and biomedical research. Full article

Dysregulated microRNA-mediated control of matrix metalloproteinase-2 (MMP-2) plays a pivotal role in lung cancer (LC) progression, though the inflammatory signaling mechanisms governing its regulation remain poorly understood. This study reveals how S100A4-activated RAGE signaling modulates MMP-2 expression through microRNA-125b-5p (miR-125b-5p) in human LC cells. Potential miRNA target genes were computationally predicted using TargetScan algorithms. Functional interaction between miR-125b-5p and MMP-2 3′UTR was experimentally validated through dual-luciferase reporter assays incorporating full-length MMP-2 3′UTR sequence. Further validation was performed through transfection with miRNA inhibitors or mimics. To delineate the underlying mechanisms, key pathways were inhibited using small-molecule antagonists targeting p38-MAPK and NF-κB. Our analysis identified a conserved miR-125b-5p binding site in the MMP-2 3′UTR. In A549 cells, S100A4 induced reciprocal regulation, simultaneously upregulating MMP-2 and downregulating miR-125b-5p, with luciferase assays confirming direct targeting. Pre-miR-125b-5p transfection effectively reduced endogenous MMP-2 levels, while p38-MAPK/NF-κB activation mediated this regulation by suppressing miR-125b-5p consequently elevating MMP-2 expression. These findings were further validated in another human LC cell, SHP-77. These findings provide the first evidence demonstrating that miR-125b-5p directly regulates MMP-2 in LC, establishing S100A4-RAGE⟶p38/NF-κB⟶miR-125b-5p⟶MMP-2 axis as a novel regulatory pathway. The results position miR-125b-5p as a dual-action biomarker and therapeutic target against MMP-2-driven LC metastasis, offering new insights into critical inflammation-to-cancer connections. Full article

High temperatures are one of the most important abiotic stressors affecting the survival and growth of American shad (Alosa sapidissima). Building on previous omics sequencing studies of A. sapidissima liver and gills under high temperature stress, this study focused on investigating the regulatory role of miR-1236-3p and its target gene hsp90b1. The results indicate that the full-length cDNA of the hsp90b1 gene is 2023 bp and comprises a 5’ end of 58 bp, a 3’ end of 84 bp, and a coding region of 1881 bp, encoding 626 amino acids. Sequence alignment and phylogenetic tree analysis reveal that the hsp90b1 sequence is highly conserved across species. In situ hybridization showed that hsp90b1 is mainly localized in the cytoplasm. Software prediction identified a potential binding site between miR-1236-3p and hsp90b1. Through the construction of wild-type and mutant 3’UTR hsp90b1 dual luciferase reporter plasmids, the targeted relationship between the two was confirmed. In addition, the spatiotemporal expression levels of the hsp90b1 was found to be highest in the multicellular stage and liver tissue at a cultivation temperature of 27 °C; miR-1236-3P was highly expressed in the hatching stage and heart tissue at 30 °C. These findings provide a theoretical foundation for further investigating the regulatory role of non-coding RNA in A. sapidissima heat stress and offer data for subsequent molecular breeding studies. Full article

Background: Acute lung injury (ALI) is a life-threatening respiratory condition and one of the leading causes of mortality worldwide, accounting for approximately 20% of global annual deaths. Despite its high prevalence and severity, effective therapeutic options remain limited. Eupatorium lindleyanum DC., a traditional medicinal herb, has demonstrated therapeutic potential against pulmonary diseases, particularly ALI, in both clinical and experimental settings. However, the protective effects and underlying mechanisms of its characteristic sesquiterpene lactone components against ALI remain unclear. Objective: This study aimed to evaluate the protective effects of sesquiterpene lactones from Eupatorium lindleyanum DC. (SLEL) against lipopolysaccharide (LPS)-induced ALI both in vivo and in vitro. Furthermore, it sought to elucidate the underlying mechanisms by integrating network pharmacology, multi-omics approaches (transcriptomics, metabolomics, and 16S rRNA sequencing), and various molecular biology techniques. Results: SLEL significantly attenuated inflammatory injury in alveolar epithelial cells and alleviated pulmonary edema, hemorrhage, and inflammatory infiltration in rats, accompanied by reduced TNF-α, IL-6, and IL-1β levels and improved lung injury indices. Mechanistically, SLEL exerted dual suppression of the PI3K-Akt and MAPK-NF-κB pathways. Network pharmacology, molecular docking, and UPLC-MS analyses identified Eupalinolide A and Eupalinolide K as potential bioactive constituents, which were further validated to inhibit phosphorylation of key signaling proteins, thereby partially accounting for SLEL’s pharmacological effects. Multi-omics integration further revealed that SLEL restored bile acid metabolism, reshaped gut microbial diversity, and reconstructed the microbiota–metabolite–inflammatory cytokine network, thereby maintaining gut–lung axis homeostasis and enhancing anti-inflammatory effects. Conclusions: SLEL alleviates ALI through multi-component synergistic actions that suppress pro-inflammatory signaling and modulate the gut–lung axis. These findings highlight the potential of SLEL as a promising therapeutic candidate for the treatment of ALI. Full article

Hepatocellular carcinoma (HCC) ranks among the most prevalent malignancies globally. Although treatment strategies have improved, the prognosis for patients with advanced HCC remains unfavorable. Tumor-associated macrophages (TAMs) play a dual role, exhibiting both anti-tumor and pro-tumor functions. In this study, we analyzed single-cell RNA sequencing data from 10 HCC tumor cores and 8 adjacent non-tumor liver tissues available in the dataset GSE149614. Using dimensionality reduction and clustering approaches, we identified six major cell types and nine distinct TAM subtypes. We employed Monocle2 for cell trajectory analysis, hdWGCNA for co-expression network analysis, and CellChat to investigate functional communication between TAMs and other components of the tumor microenvironment. Furthermore, we estimated TAM abundance in TCGA-LIHC samples using CIBERSORT and observed that the relative proportions of specific TAM subtypes were significantly correlated with patient survival. To identify TAM-related genes influencing patient outcomes, we developed a high-dimensional, gene-based transformer survival model. This model achieved superior concordance index (C-index) values across multiple datasets, including TCGA-LIHC, OEP000321, and GSE14520, outperforming other methods. Our results emphasize the heterogeneity of tumor-associated macrophages in hepatocellular carcinoma and highlight the practicality of our deep learning framework in survival analysis. Full article

Heat stress induces metabolic adaptations in fish, including the regulation of triglyceride (TG) synthesis/degradation to preserve cellular lipid balance and energy homeostasis. Diacylglycerol acyltransferase (DGAT) catalyzes the final step in TG synthesis. However, the molecular mechanisms by which DGAT regulates TG metabolism in heat-stressed fish remain unexplored. Our previous study suggested that miR-10c regulates dgat2 expression in genetically improved farmed tilapia (GIFT, Oreochromis niloticus) under heat stress. Here, we characterized the GIFT miR-10c precursor as a 65-nucleotide transcript yielding a 22 nt mature miRNA (oni-miR-10c). A phylogenetic analysis revealed a high level of miR-10c sequence conservation across species. A dual-luciferase reporter assay confirmed dgat2 as a direct target of miR-10c. Overexpression of miR-10c in vivo down-regulated dgat2 transcripts and DGAT2 protein. SiRNA-knockdown of dgat2 resulted in upregulation of cpt1α, fas, and lpl and downregulation of hsl, thereby reprogramming lipid metabolism in GIFT hepatocytes. Thus, the miR-10c-dgat2 regulatory axis facilitates TG hydrolysis and promotes fatty acid metabolism under heat stress. Our findings highlight miR-10c’s potential as a dgat2 inhibitor and its function in regulating lipid metabolism in heat-stressed GIFT. Our study reveals a key molecular pathway mediating thermal adaptation of energy metabolism in fish, providing novel targets for preventing heat-induced metabolic disorders. Full article

Elevated cholesterol levels play important mitogenic roles. Pseurotin A (PsA) is a fermentation product that has recently been reported as a dual inhibitor of proprotein convertase subtilisin/kexin type 9 (PCSK9) secretion and protein-protein interaction (PPI) with the LDLR. PsA showed a high acute safety profile and therapeutic potential against metastatic castration-resistant prostate cancer (mCRPC). The study aims to uncover the chronic safety, distribution, and anti-mCRPC genomic and molecular mechanistic insights of PsA. A 90-day chronic safety assessment of PsA up to 80 mg/kg in Swiss albino mice showed no signs of hematological, biochemical, or major organ toxicity. PsA demonstrated rapid intravenous distribution and elimination in Swiss albino mice. PsA is biodistributed to multiple key organs but was not detected in the brain, indicating its inability to cross the blood-brain barrier. PsA effectively suppressed the recurrence of nude mice xenografted mCRPC, which was subjected to a neoadjuvant docetaxel and enzalutamide regimen, followed by surgical excision. Collected PsA and vehicle control-treated recurrent tumors were subjected to RNA-sequencing and pathway enrichment analysis (PEA) of differentially expressed genes (DEGs). PsA-treated tumors revealed multiple significantly enriched pathways associated with promoting tumor apoptosis and inhibiting both invasion and migration. The PPI network analyses for the downregulated DEGs displayed prominent networks of genes associated with the ubiquitin-proteasome system. Results provide comprehensive mechanistic and preclinical validations for PsA’s potential as a novel PC recurrence suppressive lead entity. Full article

As nutrient allocation trade-offs occur between reproductive and vegetative development in crops, optimizing their partitioning holds promise for improving agricultural productivity and quality. Herein, we characterize the phenotypic diversity of the fruitfulness trait and identify associated genes in tea plants (Camellia sinensis). Over three consecutive years, we monitored the fruitfulness of an F₁ hybrid population (n = 206) derived from crosses of ‘Emei Wenchun’ and ‘Chuanmu 217’. A marked variation was observed in the yield of individual plants, ranging from complete sterility (zero fruits) to exceptionally high fertility (1612 fruits). Using the high-resolution genetic linkage map and the fruitfulness data, we identified a stable major QTL designated as qFN5. To fine-map the underlying gene(s), artificial pollination experiments were conducted with extreme phenotype individuals (with the highest vs. lowest fruit numbers). Bulked segregant RNA sequencing (BSR-Seq) with ovules collected at two and seven days post-pollination (DPP) identified the genomic intervals that exhibit a high degree of overlap with qFN5. Analysis of expression dynamics combined with functional genomics data revealed a prominent candidate gene, CsETR2 (TGY048509), which encodes an ethylene receptor protein. When CsETR2 was overexpressed in Arabidopsis thaliana, the transgenic lines exhibited significantly decreased reproductive performance relative to the wild-type plants. Relative to the wild type, the transgenic lines exhibited a significant decline in several key traits: the number of effective panicles decreased by 72.5%, the seed setting rate dropped by 67.7%, and the silique length shortened by 38%. These findings demonstrate its role in regulating plant fruitfulness. Furthermore, yeast one-hybrid and dual-luciferase assays verified that CsMYB15 (TGY110225) directly binds to the CsETR2 promoter, thus repressing its transcription. In summary, our findings expand the understanding of genetic regulation underlying fruitfulness in tea plants and provide candidate target loci for breeding. Full article

In recent years, symptoms suggestive of viral infection have commonly occurred in Gynura bicolor in China. However, no viral genome infecting G. bicolor has been reported. This study applied high-throughput sequencing to plant samples with chlorotic spots in Sanya, Hainan. Viral sequences were confirmed using RT-PCR and RACE. Complete genomes of vanilla distortion mosaic virus (VDMV, Potyvirus vanillae) and an unknown virus were obtained. Sequence analysis indicated that the VDMV isolate from the G. bicolor is a novel variant. It shares 81.13% identity with its closest known strain. The unknown virus is phylogenetically related to maculaviruses but shares less than 76% nucleotide identity with other tymovirids. According to the ICTV, it should be classified as a new member of the genus Maculavirus. In this study, we provisionally designated the virus as gynura bicolor maculavirus (GBMV). Transmission electron microscopy revealed both filamentous and icosahedral virions in stems, but only filamentous virions in leaves. Quantitative RT-PCR showed high RNA accumulation of both viruses in the stems. GBMV levels were significantly lower in leaves. Dodder-mediated mechanical transmission successfully transferred VDMV and GBMV to Nicotiana occidentalis, Oenothera biennis, and Chenopodium amaranticolor. O. biennis developed chlorotic symptoms 15 days after dual infection. Full article

Oxidative stress has a dual role in breast cancer, promoting growth at moderate levels while causing cell death at higher levels, such as during therapeutic interventions that increase reactive oxygen species production. Oncogenic microRNAs miR-526b and miR-655 promote aggressive cancer traits—such as proliferation, migration, invasion, hypoxia response, cancer stem cell properties, and metastasis—via COX-2/EP4/PI3K pathways. These miRNAs and oxidative stress appear to engage in a self-amplifying loop, where miRNA overexpression increases ROS levels, and moderate oxidative stress, in turn, enhances miRNA expression—although the mechanisms are not yet fully understood. This study investigates how overexpressing miR-526b, miR-655, and COX-2 influences breast cancer cell responses to oxidative stress induced by H₂O₂. We examined cell viability, DNA damage, and transcriptomic changes in MCF7, MCF7-miR526b, MCF7-miR655, and MCF7-COX2 cell lines. Overexpression of COX-2 provided the most significant protection against oxidative stress, decreasing apoptosis and promoting cell cycle progression. Cells with miR-526b and miR-655 exhibited distinct yet overlapping stress responses, including decreased expression of DNA damage markers and alterations in p53 signaling. RNA-sequencing and network analyses identified hub genes involved in redox balance, immune, and metabolic pathways, which may have clinical significance (OAS2, TNF, CACNA1C, CALML5). Overall, these findings suggest that miR-526b, miR-655, and COX-2 play novel roles in promoting resistance to oxidative stress through transcriptional reprogramming in breast cancer; the identified markers could serve as potential biomarkers or therapeutic targets. Full article

Background: Intermittent fasting (IF) is emerging as a promising non-pharmacological intervention in oncology, with the potential to modulate key biological processes including metabolic reprogramming, inflammation, autophagy, and immune function, particularly through the PI3K/AKT/mTOR pathway. However, translating IF into clinical practice requires robust tools to monitor its biological impact and therapeutic effectiveness. Objective: This narrative review aims to present and critically evaluate current diagnostic and monitoring strategies that can support the safe and effective integration of IF into oncological care. Methods: A comprehensive literature search was conducted across PubMed/Medline, Science Direct, Scopus, Wiley Online Library, and Google Scholar using a combination of free-text and MeSH terms related to intermittent fasting, oncology, biomarkers, immunophenotyping, metabolic pathways, gut microbiome, and diagnostic imaging. Results: Two principal categories of monitoring objectives were identified. The first—mechanistic monitoring—focuses on elucidating IF-induced biological effects, including modulation of insulin/IGF-1 signaling, oxidative stress reduction, autophagy activation, immune reprogramming, and microbiome alterations. Advanced research tools such as single-cell RNA sequencing, proteomics, metabolomics, and circulating tumor DNA (ctDNA) assays offer high-resolution insights but currently remain limited to preclinical or translational settings due to cost and complexity. The second—clinical response monitoring—assesses IF’s impact on treatment outcomes, including chemotherapy and immunotherapy response, toxicity reduction, tumor dynamics, and maintenance of nutritional and functional status. This requires clinically validated, accessible, and interpretable diagnostic tools. Conclusions: A dual-layered monitoring framework that integrates both mechanistic insights and clinical applicability is essential for the personalized implementation of IF in oncology. Although preliminary findings are promising, large-scale randomized trials with standardized protocols are necessary to confirm the efficacy, safety, and feasibility of IF in routine oncological care. The integration of IF with modern diagnostics may ultimately contribute to a more individualized, biologically informed cancer treatment paradigm. Full article

Mitoviral-derived sequences are frequently detected in plant genomes, encoding an RNA-dependent RNA polymerase (RdRp). These sequences share many similarities with mitoviruses that are known to commonly infect plant mitochondria. However, the functional characterization of nuclear-encoded mitoviral-RdRp remains unclear. This study elucidates the critical role of mRdRp (AT2G07749) in maintaining mitochondrial homeostasis and embryo viability, highlighting the dual role of viral-derived genes in plant development and stress response. Phylogenetic analysis reveals that mRdRp shares 96.8% identity with the mitoviral RdRp encoded by mitochondrial-genomes, suggesting that this nuclear mRdRp gene originated from horizontal transfer events following ancestral plant-mitovirus infections. To dissect mRdRp function, we generated a mRdRp knockout mutant via CRISPR-Cas9 or knockdown mutant by RNA interference (RNAi). These mRdRp mutants exhibited severe developmental defects, including dwarfism, embryo lethality, and sterility. Phenotypic assays further showed that mRdRp mutants displayed heightened susceptibility to ABA and rotenone, indicating impaired adaptive capacity to both hormonal and metabolic stress. Loss of mRdRp led to fragmented mitochondrial networks and a significant reduction in mitochondrial abundance in both leaf protoplasts and root meristematic cells. Additionally, mitochondrial-derived small RNA (sRNA) aberrantly accumulated in mRdRp mutants, which potentially disrupts endogenous RNA-silencing pathways that rely on sRNA-mediated gene regulation. Collectively, these results provide mechanistic insights into the function integration of a virus-derived gene into plant cellular networks, advancing our understanding of host–virus coevolution and the role of horizontally transferred viral genes in shaping plant physiology. Full article