Search Results (162)

Nucleocapsids protect viral genomes and play fundamental roles in viral assembly and infection. While many viruses adopt icosahedral or helical symmetries, negative-strand RNA viruses (NSVs) assemble their nucleocapsids with a distinct translation-based symmetry that is often considered helical because of their curvature. Our study analyzes the structural basis, assembly principles, and functional implications of the linear nucleocapsids. Structural coordinates of viruses were obtained from the Protein Data Bank (PDB) and examined using PyMOL version 1.3 to compare protein folds, RNA–protein interactions, inter-subunit contacts, and curvature properties across multiple nucleocapsids. We found that linear nucleocapsids share a similar 5H + 3H fold in their capsid proteins and encapsidate a fixed number of nucleotides per subunit, though the degree of nucleotide sequestration varies. Their architecture differs in inter-subunit interactions, determining whether empty capsids can assemble and influencing RNase sensitivity. Although these nucleocapsids may appear helical, they lack strict helical symmetry and instead display variable curvature that is modulated by environmental conditions. Relaxation of this curvature is likely required for viral RNA-dependent RNA polymerase to access the sequestered RNA genome during transcription/replication. In conclusion, linear nucleocapsids constitute a class of RNA–protein assemblies with variable curvature. The topologically conserved fold of the capsid protein enables genome protection while regulating exposure of RNA during viral RNA synthesis. Full article

Emerging evidence suggests that polymorphisms in the reverse transcriptase connection (RT-conn) and RNase H domains may contribute to resistance to reverse transcriptase inhibitors (RTIs). Here, we characterised the polymorphic landscape of the RT-conn and RNase H domains in HIV-1 subtype C (HIV-1C) from Botswana across the pre-ART and post-ART eras, including treatment-naïve (TN) and treatment-experienced (TE) individuals. A total of 1571 HIV-1C sequences were analysed: 76 pre-ART (≤2002) and 1495 post-ART (>2002) sequences were obtained from the Los Alamos database and the Botswana Combination Prevention Project (2013–2018). Post-ART sequences were stratified into TN (n = 1282) and TE individuals with virologic failure (TEVF, n = 213). Naturally occurring and ART-associated polymorphisms within RT-conn (aa 321–440) and RNase H (aa 441–560) were assessed. Among TN individuals, 12 polymorphisms exceeded 5% pre-ART, including R461K and L491P, while 31 polymorphisms were observed post-ART, indicating a temporal shift. Several substitutions were significantly higher in TEVF and showed a history of thymidine analogue-, tenofovir- and lamivudine/emtricitabine-based exposure. Covariant analysis identified significant co-occurrence of polymerase mutations (M184V/I, D67N) with RT-conn/RNase H substitutions (p < 0.05). These findings demonstrate HIV-1C evolution within the extended RT domains under ART pressure and support their inclusion in molecular surveillance frameworks in Botswana. Full article

Next-generation sequencing (NGS) and antisense oligonucleotide (ASO) technologies are converging to transform the diagnosis and treatment of rare monogenic disorders. NGS enables comprehensive, single-test molecular diagnoses through targeted panels, whole-exome sequencing, and whole-genome sequencing, which together reveal pathogenic variants across coding, intronic, and structural domains. Integration with transcriptomic analyses, including RNA sequencing, further refines genotype–phenotype correlations and identifies splicing aberrations amenable to correction by ASOs. Therapeutic advances now span RNase H1-dependent gapmers for transcript knockdown, splice-modulating phosphorodiamidate morpholino oligomers (PMOs), and peptide/antibody-conjugated PMOs that enhance muscle and cardiac delivery. These platforms underpin the rise in N-of-1 ASO therapies—customized drugs developed for individual patients with unique pathogenic variants. Landmark cases such as Milasen and Atipeksen illustrate the clinical feasibility and ethical complexities of personalized RNA therapeutics, while updated FDA guidance supports expedited, patient-specific investigational pathways. Despite progress, challenges persist in delivery efficiency, long-term efficacy, and equitable access. Emerging approaches—including long-read sequencing, AI-driven oligo design, and improved delivery—promise to extend ASO precision and reach. This review synthesizes current advances linking genomic diagnosis to individualized RNA-targeted interventions, outlining how integrated NGS-ASO pipelines are reshaping the therapeutic landscape for rare genetic diseases. Full article

Self-incompatibility (SI) is a key reproductive mechanism in angiosperms that prevents self-fertilization and promotes genetic diversity while limiting breeding efficiency. Akebia trifoliata is a recently domesticated economic crop native to East Asia with medicinal, edible, and oil-producing value. However, its late-acting self-incompatibility (LSI) severely limits genetic improvement and commercial development. To investigate the molecular basis of LSI, we conducted comparative transcriptomic analyses of pistils at 48, 96, 144, 192, and 240 h after self- and cross-pollination, identifying 1552, 2954, 1302, 814, and 1978 differentially expressed genes (DEGs), respectively. DEGs were consistently enriched in mitogen-activated protein kinase (MAPK) signaling, plant hormone signal transduction, and ubiquitin-mediated proteolysis pathways, with clear transcriptional differences before and after 96 h. Compared with cross-pollinated pistils, self-pollinated pistils showed restricted pollen tube spread, and genes related to pollen recognition and tube development showed differential expression at 48 and 96 h, indicating that LSI probably occurs within the pollen tube. Collectively, these results indicate that pistils of A. trifoliata exhibit distinct early responses to self- and cross-pollination, and that DEG-enriched pathways are similar to those involved in S-RNase-mediated SI. These results provide new insights into the molecular basis of LSI and suggest potential targets for overcoming the SI barrier. Full article

Background. Eriobotrya seguinii (Lév.) Cardot ex Guillaumin (Rosaceae, Maleae) is native to China and inhabits various altitudes within the subtropical biome of the Yunnan-Guizhou Plateau. The complexity of the plant mitogenome has impeded a systematic description of this species, leading to a limited understanding of its evolutionary position. Methods. In this study, we constructed, annotated, characterized, and compared the complete E. seguinii mitogenome with previously reported Eriobotrya japonica. Results. The E. seguinii mitogenome exhibited a typical circular architecture, spanning 372,899 bp in length, with a GC content of 46%, making it the smallest and highest GC content of any known Eriobotrya species. It encodes 71 unique genes, comprising 47 protein-coding genes, 20 transfer RNA (tRNA) genes, and 4 ribosomal RNA (rRNA) genes. The genome contains rich repetitive sequences, with mononucleotides, A/T bias, and forward and palindromic repeats being the most prevalent. The predominant codons were GCU (Ala) and UAU (Tyr), with frequencies of 1.54 and 1.53, respectively. Thirteen genes (atp9, atp6, atp1, rps14, sdh4, sdh3, rps12, rnaseH, nad1, nad6, nad7, rpl16, and mttB) demonstrated high Pi values, ranging from 0.84 to 1. The evolutionary lineage of E. seguinii was explored using mitogenome data from 19 genera within the Rosaceae family, revealing that Eriobotrya species are monophyletic and closely related to E. japonica (MN481990). Conclusions. Understanding the mitogenome characteristics of E. seguinii enhances our understanding of its genesis and classification based on mitochondrial genome data. This study provides additional evidence for future research on the evolutionary relationships among species in the Rosaceae family. Full article

Agrobacterium tumefaciens, a destructive pathogen causing crown gall disease, results in substantial agricultural losses. Traditional chemical and existing biocontrol methods are limited by environmental pollution, pesticide resistance, and low efficacy, while bacteriophages emerge as a promising alternative due to their high host specificity, environmental compatibility, and low resistance risk. In this study, we isolated and characterized a lytic phage (PAT-A) targeting A. tumefaciens, evaluating its biological traits, genomic features, and biocontrol potential. The host strain A. tumefaciens CL-1 was isolated from cherry crown gall tissue and identified by 16S rDNA sequencing. Phage PAT-A was recovered from orchard soil via the double-layer agar method, showing a tadpole-shaped morphology (60 nm head diameter, 30 nm tail length) under transmission electron microscopy (TEM). Nucleic acid analysis confirmed a double-stranded DNA genome, susceptible to DNase I but resistant to RNase A and Mung Bean Nuclease. PAT-A exhibited an optimal MOI of 0.01, tolerated wide pH and temperature ranges, but was sensitive to UV (titer declined after 15 min of irradiation) and chloroform (8% survival at a 5% concentration). Whole-genome sequencing revealed a 44,828 bp genome with a compact structure, and phylogenetic/collinearity analyses placed it in the Atuphduvirus genus (Autographiviridae). Biocontrol experiments on tobacco plants demonstrated that PAT-A significantly reduced crown gall incidence. Specifically, simultaneous inoculation of PAT-A and A. tumefaciens CL-1 resulted in the lowest tumor incidence (12.0%), while pre-inoculation of PAT-A 2 days before pathogen exposure achieved an incidence rate of 33.3%. In conclusion, PAT-A is a novel strictly lytic phage with favorable biological properties and potent biocontrol efficacy against A. tumefaciens, enriching phage resources for crown gall management and supporting phage-based agricultural biocontrol strategies. Full article

The gut microbiome evolves in response to host development, health state, lifestyle, nutrition, and microbial interactions. The survival of gut microbiota depends on its ability to utilize its host-indigestible complex oligosaccharides. Certain gut microbes produce glycosidases that cleave N-glycoproteins to release N-glycans that are then used as a carbon source. However, commercial glycosidases are inefficient and, thus, require improved deglycosylation strategies to study their functions and scale up their production. Therefore, the main objective of this study was to recombinantly produce and characterize the novel endo-β-N-acetylglucosaminidase 2 (EndoBI-2) from Bifidobacterium longum subsp. infantis (B. infantis) and to evaluate its enzymatic performance for controlled N-glycan release. Furthermore, the optimum reaction conditions for EndoBI-2 were investigated on model glycoprotein RNAse B using model glycoprotein. The released N-glycans were profiled by hydrophilic interaction liquid chromatography-fluorescence detection-quadrupole time-of-flight tandem mass spectrometry (HILIC-FLD-QTOF-MS/MS). We demonstrated that EndoBI-2 possesses a strong temperature tolerance and efficiently cleaves N-glycans under mild reaction conditions, exhibiting high activity at pH 5. These findings highlight EndoBI-2 as a robust and efficient biocatalyst for the production of bioactive N-glycans from diverse N-glycoproteins, with potential applications in glycobiotechnology. Full article

This study describes an optimized plastic surface-based capsid protein adsorption/capturing method for detection of cowpea mild mottle virus (CPMMV) adapted from the direct antigen-capture method reported for the extraction of rose rosette virus (RRV) and other direct virus capturing attempts. Briefly, the method starts with sap incubation, removal of unbound residual tissue and inhibitors by washing, and the viral RNA release using nuclease-free water and heat, in the presence of an RNase inhibitor. The protocol’s efficiency was assessed across different pH conditions, RNaseOUT concentrations, and reverse-transcriptase choices, and its performance was compared with commercial RNA-extraction methods. Three hundred thirty-two positive samples for CPMMV were processed using the optimized protocol (PBS-T, pH 7.4; RNaseOUT at 0.5 U/µL; and M-MLV reverse transcriptase). RT-PCR detection results were consistent with those obtained using the standard method. Cost estimates for tissue trapping indicate reductions of approximately 70% and 90% compared with the Qiagen RNeasy kit (Qiagen, Hilden, Germany) and the Bertheau method, respectively. The tissue-absorption protocol combines simplicity and low cost, making it particularly well suited for field diagnostics; by enabling rapid recovery of viral RNA without commercial kits and substantially reducing processing steps, it represents a practical, cost-effective alternative for routine CPMMV testing. Full article

Antisense inhibition of gene expression is usually achieved using nuclease-resistant oligonucleotide analogs that promote mRNA degradation through RNase H or RNase P, or by steric hindrance of translation. Bridge nucleic acids (BNAs) are nucleotide analogs available in a few chemical variants. We evaluated gapmers composed of an oligodeoxynucleotide flanked by BNA residues in a BNA₅-DNA₈-BNA₄ configuration, using the available variants: the original locked nucleic acid (LNA; 2′-O,4′-methylene bridge), cET (2′-O,4′-ethyl bridge), cMOE (2′-O,4′-methoxyethyl bridge), and BNANC (2′-O,4′-aminomethylene bridge). These gapmers were tested in vitro for their ability to induce cleavage of the model aac(6′)-Ib mRNA. All gapmers complementary to a previously identified region suitable for interaction with antisense oligomers induced RNase H-mediated degradation. Instead, only the LNA-containing gapmer also elicited RNase P-dependent cleavage, demonstrating dual RNA- and DNA-mimicking capability. In vitro coupled transcription–translation assays using cell lysates or reconstituted systems confirmed inhibition of expression and ruled out steric hindrance as the mechanism. In contrast, gapmers targeting the ribosome-binding site strongly inhibited expression by steric hindrance. These findings demonstrate that LNA-containing gapmers can exert their effects through multiple mechanisms, depending on the targeted mRNA region, thereby supporting their potential for synergistic inhibition of gene expression. Full article

In sturgeon aquaculture, all-female production is desirable due to the high value of caviar. Genetic sexing and the production of WW superfemales are important steps toward achieving this. In this study, we identified the WSR and ZSR primers for amplification of W- and Z-specific regions, respectively. WSR primers were designed on the gene W-linked RT RNase H-like domain containing protein (rnhW). The polymerase chain reaction (PCR) bands were obtained with the WSR primer only in phenotypic female sturgeons, indicating that stable genetic sexing was achieved in most species, including those captured around Hokkaido. Moreover, rnhW showed female-specific expression in the gonads during early sex differentiation in kaluga and Amur sturgeon. ZSR primers were developed from the orofacial cleft 1 candidate gene 1 protein homolog. Clear and distinct gel band patterns for ZZ, ZW, and WW genotypes were obtained using WSR and ZSR primers, consistent with genotypic estimations by quantitative PCR. This consistency confirmed the presence of WW superfemales among offspring produced by fertilizing ZW females with ZW pseudomales masculinized using 17α-methyltestosterone. Our findings provide new insights into the mechanisms of sex determination and differentiation in sturgeons, bringing the establishment of an all-female production system within reach. Full article

Transcription–replication conflicts (TRCs) often occur in cells and cause DNA replication fork stalling. In this study, we investigated the interplay of RNA polymerase (RNAP), DNA polymerase, and RNase H1 (RH1) during head-on TRC in vitro with precise control over the reaction conditions. We show that it is a catalytically competent transcription elongation complex (TEC) that interferes with the action of both the Klenow fragment and full-length DNA Pol I. An incompetent RNAP complex with an R-loop stimulates the 3′→5′ exonuclease activity and pauses the DNA polymerase during head-on TRC. As RNAP advances along the DNA template, elongating the RNA, the head-on TRC is slowly overcome in our model system, likely through the reassociation of the displaced DNA polymerase with the nontemplate DNA strand upstream of RNAP. An isolated R-loop containing an 11-nt heteroduplex (R-loop-11) does not interfere with DNA replication by the Klenow fragment. For DNA Pol I, such an R-loop also does not stall replication but stimulates its 3′→5′ exonuclease activity. We demonstrate that a stalled Klenow fragment does not interfere with transcription, whereas a Klenow fragment moving along the TRC substrate towards RNAP alters the kinetics of RNAP. Stalled DNA Pol I does not stop RNAP but stimulates its endonuclease activity. We find that RH1 alone does not displace stalled RNAP from a competent TEC containing R-loop-11 and does not resolve the head-on TRC. On the other hand, RH1 displaces RNAP from the incompetent complex with the TRC substrate. This eliminates the stimulation of the 3′→5′ exonuclease activity of DNA polymerase during head-on TRC. Full article

R-loops are three-stranded nucleic acid structures implicated in genome regulation and stability. In Arabidopsis thaliana, the chloroplast-localized RNase H1 enzyme (AtRNH1C) is important for chloroplast development and genome integrity; however, its molecular activity has not been experimentally verified. In the present study, we characterized the enzymatic activity of recombinant AtRNH1C toward model R-loops of various structures. Using a set of synthetic R-loop substrates, we demonstrate that AtRNH1C cleaves the RNA within DNA/RNA hybrids with a strong preference for purine-rich sequences, most notably at G↓X dinucleotides. Kinetic assays showed that the enzyme’s efficiency is highly dependent on the length of the hybrid duplex but is not affected by a G-quadruplex structure in the single-stranded DNA flap of the R-loop. The most rapid degradation was observed for an R-loop with an 11 nt DNA/RNA hybrid region. This study provides a comparative analysis of chloroplast-localized RNase H1 activity and elucidates its substrate preferences, suggesting that an R-loop with a heteroduplex length closest to the native size found in transcription elongation complexes is the most efficient substrate. These findings suggest that the enzymatic activity of AtRNH1C is sufficient to perform its function in maintaining chloroplast genome stability by the degradation of R-loops in DNA. Full article

Hepatitis B Virus (HBV) continues to pose a significant global health challenge, with over 254 million chronic infections and current therapies being non-curative, necessitating lifelong treatment. The HBV ribonuclease H (RNase H) is essential during HBV reverse transcription by cleaving the viral pregenomic RNA after it has been copied into the (−) polarity DNA strand, enabling the viral polymerase to synthesize the (+) DNA strand. Although RNase H inhibition terminates viral replication and thus viral infectiveness, its targeting as an HBV treatment is unexploited. Its catalytic site contains four carboxylates that bind to two Mg²⁺ ions essential for RNA hydrolysis. As part of our ongoing research on RNase H inhibitors, we developed 23 novel N-hydroxypyridinedione (HPD) analogues. Specifically, 17 HPD imines, 4 HPD oximes, 1 2,6-diamino-4-((substituted)oxy)pyrimidine 1-oxide derivative, and 1 barbituric acid analogue were designed, synthesized, and tested for their anti-HBV activity. The HPD derivatives could be docked in the RNase H active site to coordinate the two Mg²⁺ ions and effectively inhibited viral replication in cellular assays. The 50% effective concentration (EC₅₀) values of these HPD compounds ranged from 0.5 to 73 μM, while the 50% cytotoxic concentration (CC₅₀) values ranged from 15 to 100 μM, resulting in selectivity indexes (SIs) up to 112. Furthermore, the novel HPD derivatives exhibited favourable pharmacokinetic-relevant characteristics, including high cellular permeability, good aqueous solubility, and overall drug-like properties. These findings indicate that HPD imines and oximes possess substantial antiviral potency and selectivity against HBV, underscoring the potential of the HPD scaffold as a promising framework for the development of next-generation anti-HBV agents. Full article

Stachys duriaei (Lamiaceae) remains unexplored despite its pharmacological potential. In this study, for the first time, the antiproliferative, pro-apoptotic, cell cycle arrest, and vasorelaxant effects of the n-butanolic extract (BESD) and a VLC fraction (BF1SD) of Stachys duriaei were investigated. Antiproliferative activity was evaluated on PC3 and MDA-MB-231 cell lines via MTT assay (72 h). Apoptosis (Annexin V-FITC/PI) and cell cycle arrest (PI/RNase) were assessed by flow cytometry (24 h, 250–1000 µg/mL). Vasorelaxant effects were studied ex vivo on rat aortic rings. LC-HRMS/MS was used for phytochemical analysis. BESD showed higher antiproliferative activity (IC₅₀: 196 ± 6 µg/mL for PC3, 182 ± 8 µg/mL for MDA-MB-231) than BF1SD (IC₅₀: 281 ± 6 µg/mL and 273 ± 3 µg/mL, respectively). Apoptosis was dose-dependent, with BF1SD displaying a stronger effect at 1000 µg/mL (67.3 ± 0.5% vs. 49.9 ± 0.7% for BESD). BESD induced G2/M arrest, while BF1SD caused G0/G1 and G2/M arrest. Vasorelaxation was endothelium-dependent, likely mediated by NO. Identified compounds (hyperoside, luteolin-7-glucoside, and rutin) may contribute to these effects. BESD and BF1SD exhibit anticancer and vasorelaxant properties, indicating potential therapeutic use against cancer and cardiovascular diseases. Further studies are needed to isolate active compounds and confirm their effects in vivo. Full article

The peach landrace ‘Liuyefeitao’ exhibits the unique reproductive trait of self-compatibility combined with cross-incompatibility, contrasting with typical Prunus species in this way. In preliminary studies involving controlled pollination assays, we showed complete pollen tube arrest in cross-pollinated styles, whereas self-pollination enabled full tube elongation. S-genotyping identified a homozygous S₂S₂ genotype with intact S₂-RNase but a truncated PpSFB2 due to a frameshift mutation. Transcriptome profiling of the styles revealed 7937 differentially expressed genes (DEGs) between self- and cross-pollination treatments, with significant enrichment in plant MAPK signaling, plant–pathogen interactions, and plant hormone signaling transduction pathways (|Fold Change| ≥ 2, FDR < 0.01). Notably, PpSLFL3 (a pollen F-box gene) showed down-regulation in cross-pollinated styles, as validated by means of qRT-PCR. Protein interaction assays revealed direct binding between PpSLFL3 and S₂-RNase via Y2H and BiFC analysis, suggesting its role in mediating SCF complex-dependent degradation. We propose that insufficient PpSLFL3 expression during cross-pollination disrupts SCF ubiquitin ligase complex-mediated degradation of non-self S₂-RNase, leading to the toxic degradation of RNA in pollen tubes by S₂-RNase. This mechanism is mechanistically similar to unilateral reproductive barriers in Solanaceae but represents a novel regulatory module in Rosaceae. Our findings provide critical insights into the evolution of cross-incompatibility systems and molecular breeding strategies for Prunus species. Full article