Search Results (7,190)

Soybean (Glycine max) is relatively recalcitrant to genetic manipulations; hence, it is often interrogated with transient means such as virus-induced gene silencing (VIGS). We earlier modified cowpea severe mosaic virus (CPSMV) to develop a soybean-friendly VIGS system referred to as QUIN-FZ. Here we report additional calibrations of this system. We enhanced the intra-bacterial stability of plasmid QUIN, which contained a CPSMV RNA1 cDNA embedded with four introns, by adding a fifth intron, resulting in PENTIN. We separately upgraded the plasmid FZ, which contained a modified CPSMV RNA2 cDNA with a cloning site in the middle of the viral polyprotein, by creating another cloning site within the 3′ untranslated region, leading to ZY. We next used the new PENTIN-ZY system to investigate a putative soybean protein kinase designated QL18. Virus-mediated overexpression of two allelic, 147-amino-acid (aa) protein fragments, derived from two different QL18 orthologs, elicited drastically different responses in soybeans. While the fragment derived from soybean accession OX20-8 prevented the cognate virus from infecting top young leaves in at least 50% of inoculated seedlings, its allelic counterpart derived from soybean accession PI427105B elicited apical necrosis in 100% of soybean seedlings. By examining progeny viruses as well as viruses encoding chimeras of the two fragments, we identified more than a dozen mutations that abrogated these unique phenotypes. Our findings establish the PENTIN-ZY system as a versatile tool for overexpressing small proteins and protein fragments, accelerating their functional characterization. Full article

Diagnostic testing of foot-and-mouth disease virus (FMDV) currently utilizes reverse transcription quantitative PCR (RT-qPCR) to detect the presence of viral RNA and double antibody sandwich ELISAs (DAS-ELISAs) to determine viral serotype. Serotype identification is critical to support informed vaccine selection to combat outbreaks. While DAS-ELISAs are capable of serotype identification, the test suffers from low sensitivity and requires a viral isolate for successful detection. In this study, we developed FMDV-ONTAPS: an Oxford Nanopore Technologies Amplicon P1 Sequencing protocol involving reverse transcription-PCR to amplify P1 of the FMDV genome, and Nanopore sequencing of the amplicons to provide genetic data for serotype and subtype/topotype identification. FMDV isolates representing all seven serotypes were successfully sequenced with this method. Additionally, the protocol successfully provided serotype identification from a variety of specimen matrices obtained from experimentally infected animals that included milk, serum, oral and nasal swabs, tissue suspensions, vesicular fluid, and oral fluid. The limit of detection for FMDV cell culture isolates was comparable for both sequencing and RT-qPCR detection. RT-qPCR Cq values for clinical samples evaluated ranged from 8 to 28.21. Sequencing was successful for all samples except for a single tissue suspension sample (Cq of 28.21). Identification of FMDV serotype in clinical samples is critical for effective outbreak response, and Nanopore sequencing offers a timelier and more sensitive alternative to DAS-ELISAs. Full article

Loss of myelinating oligodendrocytes and myelin impairs motor and cognitive functions. Transplantation of autologous oligodendrocyte precursors (OPCs) holds promise for treatment of such diseases, but a protocol to derive human OPCs from a safe, ethical and accessible cell source with the rapidity required to catch the therapeutic window remains to be found. Although we previously generated myelinating glia from rat bone marrow stromal cells (BMSCs), it remains unknown if clinically sourced human BMSCs (hBMSCs) share the same potential. Moreover, whether the multipotency of BMSCs results from diverse progenitors preexisting in the bone marrow or from a single multipotent progenitor population remains unaddressed. Single-cell RNA sequencing data revealed a CD90^hiEGFR⁺PDGFRA⁺ pre-OPC-like subpopulation within hBMSCs. With a small-molecule-based (virus-free and supporting-cell-free) two-step induction protocol designed to expand this pre-OPC population, we generated functional OPCs with high purity in eight days. These derived OPCs showed phenotypic transcriptomes and immunoprofiles. They were also capable of myelinating naked axons when transplanted into myelin-deficient shiverer mice. Results highlight how targeted enrichment and maturation of specific progenitor subpopulations within hBMSCs allows rapid induction of desired cell types. These results place hBMSCs as a robust source of OPCs, unlocking the possibility for cell transplantation therapy for myelin deficiency in the central nervous system. Full article

Severe Fever with Thrombocytopenia Syndrome (SFTS) is caused by the SFTS virus (SFTSV) and is associated with a high mortality rate. Although previous studies have reported RNA modifications such as m6A on SFTSV RNA, an integrated analysis of native viral transcript architecture and multiple RNA modification types within infected cells remains lacking. Here, we used Oxford Nanopore direct RNA sequencing (DRS) to analyze native SFTSV RNA in infected cells, combining strand-specific alignment, isoform reconstruction through read endpoint clustering, isoform-level quantification, and signal-level modification identification using unmodified in vitro transcripts as a baseline. This approach allowed us to construct detailed maps of the L, M, and bidirectionally encoded S segments at single-molecule, isoform-level resolution. The results reveal a “length-layering” pattern in SFTSV transcription, anchored by recurrent 3′ termination hotspots: only a few full-length transcripts dominate expression, whereas multiple reproducible truncated isoforms were associated with discrete termination windows, a pattern less consistent with random degradation alone and suggestive of regulated transcript termination. At the single-nucleotide level, the modification landscape is predominantly Ψ (pseudouridine), followed by m⁵C (5-methylcytosine), with sparse m⁶A (N6-methyladenosine). Modification hotspots are co-located across isoforms at the same genomic coordinates, exhibiting segmental/strand asymmetry, with sharper peaks on (−) RNA. These patterns provide a testable framework and raise the possibility that transcript-boundary organization and site-constrained Ψ/m5C signals may be associated with variation in viral RNA output. More broadly, isoform proportions around termination hotspots and Ψ/m5C-enriched regions at conserved sites may serve as quantitative features for characterizing viral RNA organization and prioritizing targets for future functional investigation. Our single-molecule integrated map establishes a reproducible methodological framework for studying SFTSV RNA regulation and provides a resource for future work aimed at assessing how transcript boundaries and RNA modification patterns may relate to polymerase activity and virus–host interaction. Full article

Cytotoxic CD8 T lymphocytes are crucial in antiviral immune responses. However, their recruitment to infection sites renders them at risk of viral infection, which could affect their effector activity. CD8 T lymphocytes express RIG-I, which detects cytosolic viral RNA and subsequently induces antiviral gene expression. We investigated how Influenza A virus infection and synthetic triphosphorylated double-stranded RNA, a specific RIG-I ligand, influence TCR-dependent effector responses in primary human CD8 T cells. Cells were isolated from healthy donors and either infected with the reassortant virus RG-PR8-Brazil78 (H1N1) or transfected with the synthetic RNA. Proliferation, degranulation, and cytokine production upon anti-CD3/CD28 stimulation were assessed using flow cytometry and intracellular cytokine staining. Type I IFN production and downstream signaling were measured using IFN-I reporter assay and Western blotting. CRISPR/Cas9 gene editing was employed to knock out RIG-I and STAT2 to evaluate their roles in antiviral responses. Influenza A virus infection of CD8 T cells stimulated RIG-I and activated downstream pathways, including TBK1 and NF-κB, resulting in type-I interferon secretion. Transfection of cytotoxic CD8 T lymphocytes with synthetic RIG-I ligands not only stimulated these pathways but also enhanced the proliferation of CD8 T cells in vitro and protected them from influenza A virus infection. In line with a positive effect on CD8 effector function, both influenza A virus infection and RIG-I ligand transfection enhanced CD8 T cell degranulation and cytokine secretion. Conversely, activation of CD8 T lymphocytes via CD3/CD28 crosslinking increased their susceptibility to influenza A virus infection. We demonstrated that RIG-I stimulation by virus infection or RIG-I ligand transfection promotes intrinsic antiviral pathways and enhances CD8 T-cell effector functions and proliferation. This suggests that RIG-I agonists could enhance and prolong the effector function of cytotoxic CD8 T lymphocytes in immunotherapy. Full article

Vesicular stomatitis virus (VSV), a member of the Vesiculovirus genus within the Rhabdoviridae family, is a widespread pathogen affecting all hoofed livestock species, leading to reduced animal growth and productivity. To date, no effective therapeutic treatment for VSV infection has been developed. Natural medicinal compounds with immunomodulatory properties represent a promising supportive strategy for infection control. Ginsenoside Rh1, a primary bioactive component of ginseng plants, has been reported to possess broad pharmacological and immunoregulatory activities. Nevertheless, its potential antiviral effects against VSV remain unexplored. In this study, we demonstrate that Ginsenoside Rh1 exhibits considerable antiviral activity against VSV in cellular models. Mechanistically, its antiviral effect is primarily mediated through the inhibition of VSV-induced autophagy, thereby enhancing interferon-mediated antiviral responses. Collectively, our findings identify Ginsenoside Rh1 as a novel antiviral agent active against VSV and potentially related vesiculoviruses, clarify its mechanism of action, and highlight an autophagy-dependent immunomodulatory approach that could be critical for confronting existing and emerging RNA viral infections. Full article

Parainfluenza virus 5 (PIV5) can establish persistent infections in host cells despite encountering innate immune defenses, including the complement (C′) system. The host determinants that enable persistently infected cells (PI) to evade C’-mediated clearance remain largely undefined. Here, we identify the mitochondrial antiviral signaling (MAVS) protein, a central adaptor in double-stranded RNA-triggered antiviral and pro-survival signaling pathways, as a critical mediator of both PIV5 persistence and acquired resistance to C’ lysis. Wild-type (WT) PIV5-infected A549 cells were initially sensitive to C’-directed killing, but these cells rapidly establish a PI in culture with ~25% of the cell population becoming resistant to C’ lysis by day 2 and ~75% by day 4. In contrast, PIV5-infected A549 MAVS-deficient (MAVS KO) cells exhibited elevated viral gene expression, increased deposition of C3 and the membrane attack complex, and were more susceptible than WT cells to C′ killing. PIV5-infected MAVS KO cells showed rapid cytopathic effects and never established a stable PI. While pharmacological suppression of viral gene expression with ribavirin (RBV) restored the survival of PIV5-infected MAVS KO cells into a long-term PI-like state, these RBV-induced PI cells remained sensitive to C’ lysis. Collectively, these findings demonstrate a role of MAVS in modulating a PIV5 infection in culture, to facilitate both the conversion of a PIV5 acute infection to a PI and development of resistance to C’ killing. Full article

Chryseobacterium indologenes MA9 is a causative agent of root rot disease in Panax notoginseng (P. notoginseng), with its high incidence being a major manifestation of continuous cropping barriers, severely hindering the sustainable development of the P. notoginseng industry. In this study, a novel lytic bacteriophage, MA9V-3, was isolated from wastewater, targeting C. indologenes MA9. The phage produced clear plaques, ranging from 1 to 3 mm in diameter, with a surrounding halo. Phage MA9V-3 achieved an adsorption rate of up to 80% after 30 min of contact with C. indologenes MA9, a latent period of approximately 40 min, and an average burst-size if 160 PFU/cell. Transmission electron microscopy revealed that phage MA9V-3 possesses an icosahedral head and a contractile tail, exhibiting a typical myovirus-like morphology. According to the latest ICTV taxonomy, MA9V-3 belongs to the class Caudoviricetes, and the phage’s biocontrol efficacy and inhibitory capacity were evaluated at different multiplicity of infection (MOI s). The results showed that the highest titer recorded at 1.6 × 10¹⁰ PFU/mL. Whole-genome sequencing revealed that MA9V-3 is a double-stranded circular DNA virus, with a genome length of 103,203 bp, GC content of 34.29%, and 150 open reading frames (ORFs), one of which is related to tRNA. Only 13 of these ORFs encode known functional sequences, likely due to the limited available gene data for such phages in the database, with additional details on hypothetical proteins yet to be uncovered. Comparative database analysis confirmed that the phage genome contains no antibiotic resistance or toxin-related genes. Phage therapy experiments were performed using MA9V-3 and two other phages screened in our laboratory. The experimental results showed that phage MA9V-3 may be a potential candidate for effectively controlling the infection of Panax notoginseng by C. indologenes MA9, and offering valuable insights into the potential application of phage therapy for managing bacterial plant diseases. Full article

Background/Objectives: Epstein–Barr virus (EBV) is associated with a subset of gastric carcinomas characterized by latency programs that promote survival of infected cells. EBV-encoded BamH I A rightward transcript (BART) microRNAs contribute to apoptosis resistance in infected epithelial cells. This study investigated whether dasatinib, a Src family kinase (SFK) inhibitor, selectively targets EBV-positive gastric epithelial cells and examined the molecular mechanisms underlying this effect. Methods: EBV-positive and EBV-negative gastric epithelial cell models were analyzed to evaluate cell viability, apoptosis induction, signaling pathways, and viral gene regulation. BART miRNA expression was quantified by RT-qPCR, and promoter activity was examined using luciferase reporter assays. Downstream target gene expression was analyzed at both the transcript and protein levels. Recombinant EBV lacking BZLF1 or LMP2A was used to assess the contributions of lytic activation and LMP2A-associated signaling. Results: Dasatinib preferentially reduced viability and induced apoptosis in EBV-positive gastric epithelial cells compared with EBV-negative counterparts. Treatment suppressed phosphorylation of Src and ERK and reduced expression of the anti-apoptotic proteins BCL-xL and MCL1. Apoptosis was also observed in cells infected with LMP2A-deficient EBV, suggesting that the effect cannot be fully explained by inhibition of LMP2A-associated signaling. Dasatinib inhibited BART miRNA promoter activity and reduced pri-, pre-, and mature miR-BART levels, accompanied by increased expression of pro-apoptotic target genes including CASZ1a, OCT1, ARID2, TP53INP1, and DAB2. In parallel, dasatinib suppressed BZLF1 promoter activity without evidence of lytic reactivation. Conclusions: Dasatinib promotes apoptosis in EBV-positive gastric epithelial cells in association with coordinated suppression of SFK signaling and EBV-encoded BART miRNA expression, accompanied by derepression of pro-apoptotic cellular genes. These findings reveal a previously underappreciated vulnerability of EBV-positive epithelial cells and suggest that targeting host kinase signaling pathways that regulate viral microRNAs may represent a potential therapeutic strategy for EBV-associated malignancies. Full article

Background and Objectives. Mother-to-child transmission (MTCT) or vertical transmission of human immunodeficiency virus (HIV) is largely preventable in settings where prevention of MTCT (PVT) strategies are consistently implemented. Romania represents a particular epidemiological context, as individuals from the historical pediatric HIV cohort have now reached reproductive age. This study assessed current PVT outcomes in northeastern Romania and explored the remaining circumstances in which transmission still occurs. Materials and Methods. We performed a retrospective observational analysis at the Regional HIV/AIDS Center of Iași (“Sfânta Parascheva” Clinical Hospital of Infectious Diseases), including all pregnant women living with HIV and their HIV-exposed infants followed between 2023 and 2025. Maternal data comprised age, place of residence, origin from the Romanian pediatric cohort, antiretroviral therapy (ART) adherence, and HIV RNA viral load in the third trimester. Obstetric characteristics, delivery mode, neonatal antiretroviral prophylaxis, and infant HIV RNA PCR results during follow-up up to 18–24 months were also evaluated. Results. A total of 61 HIV-positive pregnant women and 53 HIV-exposed infants were included. Viral suppression during pregnancy was documented in 59 women (96.7%), while two cases of detectable viremia in late pregnancy were linked to poor ART adherence. All women delivered by elective cesarean section, and all infants received neonatal antiretroviral prophylaxis, with Raltegravir added in selected higher-risk situations. Overall, MTCT was 3.8% (2/53). No transmission events were recorded in 2023 or 2024; both cases occurred in 2025 (15.4% of infants born that year) and exclusively in the context of maternal viremia. Women originating from the historical pediatric HIV cohort accounted for 31.1% (19/61) of pregnancies, and no transmission was observed among their infants. Conclusions. In northeastern Romania, PVT programs remain highly effective when maternal viral suppression is achieved. Residual transmission was confined to situations of maternal viremia driven by ART non-adherence, highlighting the continued importance of adherence support during pregnancy. Full article

The ongoing panzootic of the highly pathogenic avian influenza (HPAI) H5N1 virus, dominated by clade 2.3.4.4b, constitutes a significant global threat to wildlife, animal health, and public health. Once characterized by sporadic outbreaks, H5N1 has evolved into a sustained, year-round infection with an expanded host range that now includes numerous mammalian species. Its high pathogenicity is primarily driven by the acquisition of a polybasic haemagglutinin cleavage site, enabling systemic viral spread, alongside emerging endothelial and neurotropic properties that contribute to severe disease and high mortality in mammals. Although zoonotic transmission remains limited, H5N1 continues to accumulate mutations associated with mammalian adaptation, particularly within the haemagglutinin and polymerase complex. Notably, recent outbreaks in U.S. dairy cattle highlight the emergence of novel mammalian reservoirs with increased human exposure risk. Concurrently, vaccination strategies are advancing beyond traditional adjuvanted inactivated vaccines toward next-generation platforms, including mRNA and virus-like particle vaccines, designed for rapid deployment and broader immune protection. However, ongoing viral evolution, constrained vaccine availability, and gaps in coordinated surveillance underscore the urgent need for an integrated One Health approach to reduce panzootic risk. Full article

The porcine epidemic diarrhea virus (PEDV) causes a gastrointestinal disease generating mortality rates approaching 100% in piglets worldwide. The S glycoprotein of PEDV is the main target for the development of vaccines. Two vaccines approved by the Ministry of Agriculture and Rural Development are used in Mexico: the first vaccine is based on an inactivated virus isolated more than a decade ago, whereas the second vaccine is based on mRNA technology. The most important tool for controlling PEDV outbreaks is vaccination; however, coronaviruses are characterized by the accumulation of multiple mutations, which compromise the immune response elicited by outdated vaccines. In this work, we classified the Mexican strains of PEDV reported so far in GenBank, according to their genotypes. Subsequently, we searched for B and T cell epitopes conserved in Mexican PEDV strains using bioinformatic tools. In addition, we explored whether these epitopes can induce allergies, autoimmunity, and/or toxic effects. Next, we determined the localization of B cell epitopes in the S glycoprotein using the protein crystal and protein modeling of several S glycoproteins. Finally, we carried out molecular docking analysis to assess whether these T cell epitopes could interact with the peptide-binding groove of the Swine Leukocyte Antigens (SLAs). Five conserved B cell epitopes were found to be exposed on the surface of the S glycoprotein, whereas several promiscuous CTL and HTL epitopes were bound, with low free energy, to the peptide-binding grooves of SLA-I and SLA-II, respectively. The best epitopes were used to generate a plasmid carrying the sequence to produce a recombinant protein. This plasmid was used for transfection experiments in PK-15 cell culture. The B cell epitopes reported here were recognized by the sera from pigs infected with PEDV but not by the sera from uninfected animals. These results justify future evaluations of the ability of these epitopes to stimulate cytokine production by T cells, antibody generation, and their neutralizing activity. Full article

In recent years, pigeon rotavirus A (PiRVA) infection, an important emerging disease, has posed a major threat to the healthy development of the pigeon industry and public health. Therefore, developing an accurate, rapid and convenient detection method for this virus is vital for monitoring and early diagnosis of the disease. In this study, on the basis of the ORF sequence characteristics of the PiRVA VP6 gene, crRNA and reverse transcription recombinase-aided amplification (RT-RAA) primers were designed. On the basis of the CRISPR/Cas12a system, for the first time, the RT-RAA-CRISPR/Cas12a rapid detection method of PiRVA was established by combining RT-RAA and lateral flow strips. This method could specifically detect PiRVA, and there was no cross-reaction with other common viruses originating from pigeons. The minimum detection limit was 16.8 copies/μL, and the results of the intrabatch and interbatch repeated tests were consistent. Moreover, the method established in this study and the previously established common PCR method were used to analyse 56 clinical tissue samples from racing pigeons and domestic pigeons collected in 2025. The positive rates of racing pigeon and domestic pigeon samples detected by PCR were 17.6% and 12.8%, respectively, and the positive rates of racing pigeon and meat pigeon samples detected by the RT-RAA-CRISPR/Cas12a method were 23.5% and 17.9%, respectively, indicating that PiRVA infection occurs in both racing pigeon and domestic pigeon populations in China. In summary, the PiRVA RT-RAA-CRISPR/Cas12a detection method established in this study has good specificity, sensitivity, and reproducibility, and allows visualization of the results, which can be used for field applications. This study provides technical support for epidemiological surveillance and etiological research on PiRVA. Full article

Bluetongue virus (BTV), with a genome of ten double-stranded RNA segments (S1–S10), is an emerging animal pathogen causing major economic losses in livestock worldwide. BTV replication involves RNA-RNA and RNA–protein interactions, with RNA-binding proteins, VP6 and NS2 playing key roles in genome assembly and RNA packaging. To explore the dynamics of RNA segment interactions and the roles of VP6 and NS2 in RNA complex formation, we used RNA fluorescence in situ hybridization chain reaction (HCR), along with site-specific mutagenesis and reverse genetics. We found that RNA segments interact sequentially, from the smallest (S10) to the largest (S1), forming a single complex that includes the entire genome. This process is independent of VP6 or NS2, although NS2 enhances the assembly of larger segments. Additionally, we show that VP6 binds to +ssRNAs before their incorporation into viral assembly factories (inclusion bodies/VIBs). These findings reveal that RNA-RNA interactions, rather than primary replicase proteins, govern the sorting and recruitment of genome segments. Our data offer new insights into BTV RNA packaging, showing that genome segments destined for packaging and dsRNA synthesis are segregated through complex formation, distinct from +ssRNAs used in protein synthesis, including those encoding the replicase complex. Full article

The APOBEC family of cytidine deaminases is part of the innate immune response to infections by multiple RNA- and DNA-containing viruses. Since the activity of these enzymes, typically APOBEC3, often involves mutations that inhibit or block viral replication, viruses have evolved antagonists that limit APOBEC function. The retrovirus mouse mammary tumor virus (MMTV) encodes an APOBEC antagonist, Rem. Surprisingly, Rem appears to inhibit APOBEC3 through proteasomal degradation of a different APOBEC enzyme, AID. Full article