Search Results (1,499)

Fusarium oxysporum-induced root rot severely threatens global soybean production, yet limited understanding of resistance mechanisms constrains breeding progress. This study conducted comparative transcriptomic analysis between highly resistant (Xiaoheiqi) and susceptible (L83-4752) soybean accessions following pathogen inoculation across four time points (8–17 days post-infection). RNA-seq analysis identified 1496 differentially expressed genes following pathogen challenge. KEGG pathway enrichment analysis revealed significant enrichment in MAPK signaling pathway (12 genes) and plant–pathogen interaction pathway (13 genes). Eight genes co-occurred in both pathways, with GmCML (Glyma.10G178400) exhibiting the most dramatic differential expression among these candidates. This gene encodes a 151-amino acid calmodulin-like protein showing 185-fold higher expression in resistant plants at 17 days post-inoculation, confirmed by qRT-PCR validation. Functional validation through transgenic hairy root overexpression demonstrated that GmCML significantly enhanced disease resistance by coordinately activating antioxidant defense systems. Overexpression of GmCML in transgenic soybean enhanced resistance to F. oxysporum by modulating the activity of antioxidant enzymes (superoxide dismutase, SOD; peroxidase, POD; catalase, CAT) and the accumulation of osmoregulatory substances (proline and soluble sugars). Population genetic analysis of 295 diverse soybean accessions revealed three GmCML haplotypes based on promoter region polymorphisms. Two favorable variants (Hap2 and Hap3) conferred significantly lower disease indices and exhibited evidence of positive selection during domestication, indicating evolutionary importance in disease resistance. This research provides the first comprehensive characterization of GmCML’s role in soybean–Fusarium interactions, establishing this calmodulin-like protein as a regulatory hub linking calcium signaling to coordinated defense responses. The identified natural variants and functional mechanisms offer validated targets for both marker-assisted breeding and genetic engineering approaches to enhance soybean disease resistance. Full article

Sarcomyxa edulis is a characteristic edible and medicinal mushroom found in Northeast China that is highly valued by consumers for its tender texture, pleasant flavor, and high nutritional value. To gain a deeper understanding of the molecular mechanisms underlying the development of S. edulis fruiting bodies, this study utilized the Illumina NovaSeq platform to perform transcriptome sequencing at three growth and development stages of S. edulis strain SE8, namely primordia (SE8–P), fruiting body differentiation (SE8–F), and mature fruiting body (SE8–M). A total of 54.67 Gb of clean data was obtained, with a GC content of around 51%. After assembly, 36,423 Unigenes were obtained. Functional annotation was performed on the Unigenes, resulting in 21,206 Unigene annotation results. Differential expression gene analysis showed that 79,606 and 523 DEGs were annotated in at least one database during the SE8–P vs. SE8–F, SE8–F vs. SE8–M, and SE8–P vs. SE8–M processes, respectively. Among these, the genes encoding aldehyde dehydrogenase and fungal hydrophobins were consistently downregulated, playing a negative regulatory role in the growth and development of S. edulis. The genes encoding glycoside hydrolase and AB hydrolase superfamily proteins were consistently upregulated, playing a positive regulatory role in growth and development. Among these, the genes encoding aldehyde dehydrogenase were annotated to the Tryptophan metabolism (ko00380) pathway through KEGG, suggesting that aldehyde dehydrogenase regulates indoacetate formation in the fruiting body of S. edulis. The accuracy of RNA–Seq and DEG analysis was validated using quantitative PCR. This study enriches our knowledge of the genetic information and provides a theoretical basis for the molecular mechanisms of fruiting body development of S. edulis. Full article

Aeromonas veronii is a major pathogen threatening freshwater aquaculture, yet the molecular mechanisms of Pelteobagrus vachellii’s immune response to this infection remain unclear. This study integrated histopathology, mRNA-seq and small RNA-seq to investigate P. vachellii’s response to A. veronii at 48 h post-challenge. Histopathologically, infection induced gill epithelial detachment, hepatocyte swelling with cytoplasmic vacuolation, and melanomacrophage centers (MMCs) in the mid-kidney (histological assessment of the head kidney was not feasible due to sampling limitations associated with its small size). Transcriptomic analysis identified 1,210 differentially expressed genes (DEGs) in the head kidney (819 downregulated, 391 upregulated), significantly enriched in 11 immune pathways (e.g., NF-κB, Th17 cell differentiation, Complement and coagulation cascades), with key immune genes (e.g., IL-1β, TCRα, CCL4) upregulated. Gene Set Enrichment Analysis (GSEA) revealed activation of the proteasome, ribosome and oxidative phosphorylation pathways, and suppression of the autophagy-animal, FoxO and AMPK pathways. Small RNA-seq identified 544 known and 958 novel miRNAs in the head kidney, with 42 downregulated and 36 upregulated differentially expressed miRNAs (DE miRNAs). The miRNA-mRNA network showed that DE miRNAs (e.g., miR-101-y/z, miR-132-z, miR-3167-y) negatively regulated immune-related target genes (IL-1R1, IRF4, IκBα) in core immune pathways. Collectively, this study clarifies the pathological and miRNA-mRNA regulatory modules of P. vachellii head kidney against A. veronii infection, providing valuable information that enables the further analyses of the defense mechanisms of P. vachellii against A. veronii infection. Full article

In numerous coffee-producing areas, coffee plants are routinely exposed to a low chilling temperature on a seasonal cycle. Despite the well-established significance of NAC transcription factors in mediating plant responses to abiotic stresses, their functions in Coffea arabica remain underexplored. This study identified 161 CaNAC genes and classified them into 15 distinct subgroups distributed across 22 chromosomes, with chromosome 11 harboring the largest number of these genes. Furthermore, a total of 1077 cis-elements were detected in the promoter regions of the 161 CaNAC genes. Among these, MYB-binding sites and ABA-responsive elements (ABREs) were the most prevalent. RNA-seq analysis under chilling stress revealed 16,767 differentially expressed genes, which were grouped into four clusters. GO enrichment analysis highlighted biological processes such as the abscisic acid-activated signaling pathway, response to cold, and response to salicylic acid, providing fundamental insights into the transcriptional response of C. arabica to chilling stress. Expression pattern analysis of CaNACs under chilling stress showed that 38 CaNACs were differentially expressed; 15 genes, including CaNAC46/49/116/125, were downregulated, while 12 genes, including CaNAC56/64, were upregulated. This study enhances our understanding of the CaNAC gene family’s role in cold responses, potentially bolstering molecular breeding programs for C. arabica. Full article

Background/Objectives: Chlorhexidine (CHX)-based mouthwashes are the most commonly used chemical methods as adjuvants for the treatment of peri-implant diseases, but there is a lack of information on their effect on the peri-implant microbiota. The objective of this study was to evaluate the impact of short-time (15 days) self-administered 0.05% and 0.12% commercial chlorhexidine mouthwashes on the peri-implant pocket microbiota of patients with peri-implantitis. Methods: In this pilot study, we analyzed the microbial composition of peri-implant lesions in 22 patients before and after a 15-day regimen of thrice-daily use of two commercial chlorhexidine mouthwashes containing 0.05% (n = 11) and 0.12% chlorhexidine (n = 11). Microbial samples were collected using paper points, and the taxonomic composition was determined through sequencing of 16S rRNA gene amplicons using Illumina MiSeq. Results: Although individual responses to chlorhexidine mouthwash treatment varied significantly, neither concentration produced a statistically significant change in the microbial diversity associated with peri-implantitis, suggesting limited treatment penetration into peri-implant lesions. Similarly, changes in the abundance of specific odontopathogens were not statistically significant. Conclusions: We found no significant differences in the effect of mouthwashes with different chlorhexidine concentrations on the peri-implant microbiota in short-period applications. Even though more extensive studies are required, the observed patient-dependent outcomes of both chlorhexidine mouthwashes on the peri-implant microbiota and their limited effect in controlling the abundance of oral pathogens indicate that prescription of chlorhexidine mouthwashes for the treatment of peri-implantitis should be carried out with caution. Novel presentations of chlorhexidine with better penetration capacities should be developed, as they could offer enhanced benefits in managing peri-implant diseases. Full article

This research reports ruminal and fecal microbiota composition of lactating dairy cows enrolled in a study aimed at investigating the effects of a fermentation extract derived from Bacillus licheniformis (BLFE), monensin (Rumensin^®; R), and their interactions on feed efficiency (FE, FE = milk yield/DMI). In a completely randomized design, 48 Holstein cows at 108 ± 35 days in milk were matched for parity and assigned to monensin (0 or 17.6 g/kg of DM) and BLFE (0 or 166 mg/kg of DM) in a 2 × 2 factorial arrangement. Treatments were fed daily for 63 d, including a 21 d adaptation period followed by a 42 d measurement period (P2). On d 38 and d 39 of P2, rumen-fluid (RF) and fecal samples were collected. DNA from RF and feces was sequenced using 16S rRNA gene-amplicon sequencing on an Illumina MiSeq platform. Fecal and RF volatile fatty acid (VFA) concentrations were analyzed, and propionate/acetate (P: A) was determined. The BLFE increased milk yield (3.3 kg/d) and FE (1.20 to 1.28), when fed alone rather than with monensin, while monensin increased energy-corrected milk yield (2.5 kg/d, p < 0.05), regardless of the BLFE in the diet. The BLFE tended to increase ruminal Firmicutes/Bacteroidetes (F: B) when fed alone, while alpha and beta diversities remained unmodified. The BLFE increased the abundances of Bifidobacterium (p = 0.02) and Erysipelotrichaceae_UCG-002 (p = 0.01) in RF, whereas monensin increased and decreased the abundances of Oscillospirales_ge (p = 0.02) and an unclassified Clostridia genus (p = 0.03), respectively. The monensin-suppressed Clostridia were negatively associated with ruminal P: A (r = −0.66; p < 0.01) and feed efficiency (r = −0.30; p = 0.04). The BLFE and monensin interactively affected several fecal genera (p < 0.05), but they had negligible or weak correlations with fecal P: A and FE. Overall, the results showed the ability of dietary supplementations of monensin and BLFE to increase milk production performance and FE by modulating ruminal rather than lower-gut microbiota composition, this is predominantly attributed to the ratio between the Firmicutes and Bacteroidetes abundances in lactating dairy cows. Full article

Background/Objective: Larazotide acetate (LA) is a synthetic octapeptide under development as a therapeutic candidate for celiac disease, acting to reduce intestinal permeability and regulate tight junctions (TJs). Although several studies have shown barrier-protective effects, the cellular mechanisms underlying LA’s actions in the intestinal epithelium remain unclear. This study aimed to elucidate the mechanistic roles of LA in maintaining intestinal epithelial integrity during cellular injury. Methods: C2BBe1 and leaky IPEC-J2 cell monolayers were pretreated with 10 mM LA and subjected to anoxia/reoxygenation (A/R) injury. Transepithelial electrical resistance (TEER), TJ protein localization, and phosphorylation of myosin light chain-2 (MLC-2) were analyzed. In addition, RNA sequencing was conducted to identify differentially expressed genes and signaling pathways affected by LA treatment. Results: LA pretreatment significantly increased TEER and preserved TJ protein organization during A/R injury. Transcriptomic analysis revealed enrichment of genes related to barrier regulation, small GTPase signaling, protein phosphorylation, proliferation, and migration. LA pretreatment markedly reduced MLC-2 phosphorylation, likely through modulation of the ROCK pathway, consistent with RNA-seq findings. Moreover, LA enhanced cellular proliferation, validating transcriptomic predictions. Conclusions: LA exerts a protective effect on intestinal epithelial integrity by stabilizing tight junctions, reducing MLC-2 phosphorylation, and promoting epithelial proliferation. These findings highlight a novel mechanism for LA and support its therapeutic potential in treating gastrointestinal disorders associated with “leaky gut” and mucosal injury. Full article

The morphological traits of Vaccinium uliginosum L., including plant height, leaf area, and fruit weight, have changed significantly across an elevational gradient in the Changbai Mountains. To elucidate the molecular mechanisms underlying these morphological variations, RNA-Seq technology was employed to identify differentially expressed genes (DEGs), key metabolic pathways, and associated biological functions of V. uliginosum at seven elevations in the Changbai Mountains. A total of 1190 DEGs significantly associated with morphological variations were identified. These genes are mainly involved in lipid synthesis, carbohydrate metabolism, energy metabolism, and signal transduction. Redundancy analysis (RDA) revealed that fatty acyl-ACP thioesterase B (FATB) and ribulose-bisphosphate carboxylase small subunit (cbbS) exhibited a significant association with morphological variation. Integrated analysis indicated that high-altitude plants likely enhance lipid synthesis and cell wall stability while also inhibiting photosynthesis and carbohydrate metabolism. The regulatory mechanisms underlying hormone signal transduction may be relatively complex, as evidenced by the enhanced activity of gibberellin and reduced biological effects of auxin, abscisic acid, and ethylene. This study is the first to provide transcriptomic evidence elucidating the genetic basis of altitudinal morphological adaptation in V. uliginosum, integrating phenotypic traits with gene expression profiles across an elevational gradient. Full article

The original purpose of this study was to compare human and pig scRNA-seq data to determine why pigs do not have brown adipocytes. However, during the experiment, we identified brown adipocytes in pigs. Therefore, we aimed to confirm that these adipocytes were brown adipocytes via a comparative analysis using typical mouse brown adipose tissue sections. We found that swine brown adipocytes were distributed in an island-like pattern, with three typical characteristics: (1) numerous mitochondria and small lipid droplets, (2) a cellular volume smaller than that of white adipocytes, and (3) expression of specific marker genes (EBF2 and ATP2B4). The expression levels of the thermogenesis-related genes UCP2/3 were not significantly increased. Thus, we conducted ceRNA network analysis, revealing that high expression of the key microRNA miR-10383 increased the thermogenic efficiency of UCP3 in the cold exposure group. In addition, the epigenetic memory of UCP3 was disrupted. Chromatin accessibility and Whole-Transcriptome Sequencing of Groin Adiposesibility results revealed peaks in the promoter regions of the UCP2/3 genes. In our discussion of the study’s limitations, we explain how to repeat the experiment to significantly increase the UCP2/3 protein content. This study fills a research gap regarding brown fat in pigs and can provide a reference for future studies on fat metabolism. Full article

Background/Objectives: Neurodegenerative diseases (NDs) such as Alzheimer’s (AD), Parkinson’s (PD), Huntington’s (HD), and Amyotrophic Lateral Sclerosis (ALS) are clinically distinct but share overlapping molecular mechanisms. Methods: To identify conserved systemic signatures, we analyzed blood RNA-Seq datasets using Weighted Gene Co-Expression Network Analysis (WGCNA), differential expression, pathway enrichment, and miRNA–mRNA network mapping. Results: Two modules, the red and turquoise, showed strong preservation across diseases. The red module was enriched for cytoskeletal and metabolic regulation, while the turquoise module involved immune, stress-response, and proteostatic pathways. Discussion: Key hub genes, such as HMGCR, ACTR2, MYD88, PTEN, EP300, and regulatory miRNAs like miR-29, miR-132, and miR-146a, formed interconnected networks reflecting shared molecular vulnerabilities. The absence of classical heat shock proteins in preserved blood modules highlights tissue-specific expression differences between blood and neural systems. Several hub genes overlap with known pharmacological targets, suggesting potential in translational relevance. Conclusions: Together, these findings reveal conserved blood-based transcriptional modules that suggest parallel central neurodegenerative processes and may support future biomarker development and possible therapeutic exploration. Full article

Background: Tumor-associated macrophages (TAMs) are essential regulators of the glioblastoma (GBM) microenvironment; their functional heterogeneity and interaction networks are not fully elucidated. We identify RNF135 as a novel TAM-enriched gene associated with immune activation and adverse prognosis in GBM. Methods: To evaluate RNF135’s expression profile, prognostic significance, and functional pathways, extensive transcriptome analyses from TCGA and CGGA cohorts were conducted. The immunological landscape and cellular origin of RNF135 were outlined using single-cell RNA-seq analyses and bulk RNA-seq immune deconvolution (MCP-counter, xCell and ssGSEA). Cell–cell communication networks between tumor cells and RNF135-positive and -negative tumor-associated macrophage subsets were mapped using CellChat. Results: RNF135 predicted a poor overall survival and was markedly upregulated in GBM tissues. Functional enrichment analyses showed that increased cytokine signaling, interferon response, and innate immune activation were characteristics of RNF135-high samples. Immune infiltration profiling showed a strong correlation between the abundance of T cells and macrophages and RNF135 expression. According to the single-cell analyses, RNF135 was primarily expressed in TAMs, specifically in proliferation, phagocytic, and transitional subtypes. RNF135-positive TAMs demonstrated significantly improved intercellular communication with aggressive tumor subtypes in comparison to RNF135-negative TAMs. This was facilitated by upregulated signaling pathways such as MHC-II, CD39, ApoE, and most notably, the CCL signaling axis. The CCL3/CCL3L3–CCR1 ligand–receptor pair was identified as a major mechanistic driver of TAM–TAM crosstalk. High RNF135 expression was also linked to greater sensitivity to Selumetinib, a selective MEK1/2 inhibitor that targets the MAPK/ERK pathway, according to drug sensitivity analysis. Conclusions: RNF135 defines a TAM phenotype in GBM that is both immunologically active and immunosuppressive. This phenotype promotes inflammatory signaling and communication between cells in the tumor microenvironment. Targeting the CCL–CCR1 axis or combining RNF135-guided immunomodulation with certain inhibitors could be a promising therapeutic strategies for GBM. Full article

Background/Objectives: Dysbiosis of the vaginal microbiota, particularly the loss of Lactobacillus spp. dominance, is linked to female infertility. While community state types (CSTs) I–III and V have been studied extensively, CST IV remains underexplored. The aim of this prospective study was to compare vaginal microbiota composition—specifically CST IVA and IVB—between fertile and infertile women. Methods: Vaginal samples were collected from 22 women (15 infertile, 7 fertile) using cervical brushes and analyzed via 16S rRNA gene sequencing. DNA was extracted, and V3–V4 regions were sequenced using the Illumina MiSeq platform. Taxonomic classification was performed with QIIME 2 and the Greengenes database. Differences in microbial composition were assessed using the Wilcoxon rank-sum test (p < 0.05) in SPSS v21.0. Results: Infertile women showed lower relative abundances of Lactobacillus spp. (31.54% vs. 42.32%) and Oscillospira spp. relative to fertile women. CST IV was more frequent in the infertile group (29.75% vs. 21.61%). Within CST IV, CST IVA accounted for a higher proportion in infertile women (7.0% vs. 0.94%), with Prevotella spp. representing 95.18% of CST IVA in infertile subjects, as opposed to the figure of 69.77% in fertile counterparts. No clear differences in CST IVB were observed between groups. Conclusions: Increased prevalence of Prevotella spp. in CST IVA may contribute to an unfavorable vaginal environment in infertile women, potentially affecting sperm viability. The presence of Oscillospira spp. in fertile women suggests it is associated with a healthy vaginal microbiota profile. Full article

Earle’s balanced salt solution (EBSS) is a classical autophagy inducer that provides a special culture environment lacking amino acids and serum, causing cell starvation. However, the production of relevant omics data surrounding EBSS-induced autophagy is still in the early stage. The objective of this study was to identify new potential functional proteins in the autophagy process through omics analysis. We selected EBSS-induced autophagy as our research object and uncovered autophagy-regulatory proteins using RNA-seq analysis. Western blotting showed that EBSS increased LC3B-II protein levels in NRK cells, reaching the maximum amount at 2 h of culture. Then, we used next-generation sequencing to obtain quantified RNA-seq data from cells incubated with EBSS and the bowtie–tophat–cufflinks flow path to analyze the transcriptome data. Using significant differences in the FPKM values of genes in the treated group compared with those in the control group to indicate differential expression, 470 candidate genes were selected. Subsequently, GO and KEGG analyses of these genes were performed, revealing that most of these signaling pathways were closely associated with autophagy, and to better understand the potential functions and connections of these genes, protein–protein interaction networks were studied. Considering all the conclusions of the analysis, 27 candidate genes were selected for verification, where the knockdown of Txnrd1 decreased LC3B-II protein levels in NRK cells, consistent with the results of confocal experiments. In conclusion, we uncovered autophagy-regulatory proteins using RNA-seq analysis, with our results indicating that TXNRD1 may play a role in regulating EBSS-induced autophagy via an unknown pathway. We hope that our research can provide useful information for further autophagy omics research. Full article

Leaf senescence is the final, programmed stage of leaf development, marked by nutrient remobilization and tightly regulated molecular events. Although alternative splicing has emerged as a major regulator of plant development, its role in isoform switching during leaf aging remains poorly understood. To address this, we conducted a genome-wide analysis of isoform switching in Arabidopsis, leveraging publicly available RNA-seq data from mature (16-day-old) and senescent (30-day-old) leaves, analyzed with the IsoformSwitchAnalyzeR package. Between these two developmental stages, we identified 269 genes exhibiting 377 significant isoform switches collectively predicted to alter protein localization, coding potential, and transcript stability. Experimental validation confirmed predicted switching at the PUS3 (Pseudouridine Synthase 3) locus, with sequence analysis revealing an age-dependent shift from mitochondrial-targeted to cytoplasmic isoforms. Gene Ontology enrichment analysis of switching genes revealed 82 significant terms, prominently associated with metabolism, gene expression, developmental regulation, and stress responses. Interestingly, we found nearly one-third of switching genes to overlap with known targets of the splicing factor SR45, with enrichment in pathways related to nucleotide and amino acid metabolism, energy production, and developmental processes. Correspondingly, dark-induced senescence assays revealed accelerated senescence in the sr45 mutant, confirming SR45′s role in regulating leaf aging. Specific complementation of SR45′s two isoforms revealed contrasting functions, with SR45.1 restoring normal senescence timing while SR45.2 failed to complement. Taken together, our findings demonstrate that differential isoform usage, orchestrated by specific splicing regulators, plays a critical role in leaf aging. This insight opens new avenues for manipulating senescence and engineering stay-green traits in crops. Full article

Bovine respiratory disease complex (BRDC) is a leading cause of morbidity and mortality in pre-weaned calves, yet the role of commensal nasal microbiota in outbreak severity remains poorly understood. This study characterized nasal bacterial communities during two BRDC outbreaks of differing severity (moderate vs. severe) and at ~30 days post-treatment. Nasal swabs were collected from calves and analyzed using 16S rRNA gene sequencing (V1–V3 regions, Illumina MiSeq) and quantitative PCR targeting three major BRDC pathogens. Microbial community profiles differed between outbreak groups and across timepoints. Calves in the severe outbreak group exhibited lower microbial diversity compared to those in the moderate outbreak. In both groups, diversity significantly increased from outbreak to post-treatment. At the time of disease, nasal communities were dominated by the genera Mycoplasmopsis, Mesomycoplasma, and Caviibacter, with qPCR confirming Mycoplasma bovirhinis as the predominant species. These findings indicate that BRDC outbreaks in pre-weaned calves are associated with reduced microbial diversity and the dominance of pathogenic Mycoplasma species, with recovery characterized by greater bacterial diversity. Shifts in nasal microbiome composition between outbreak and post-treatment may reflect pathogen-driven disruption during disease and subsequent microbial community rebalancing. Full article