Rescue of a Cilevirus from infectious cDNA clones.

Reverse genetics systems represent an important tool for studying the molecular and functional processes of viral infection. Citrus leprosis virus C (CiLV-C) (genus Cilevirus, family Kitaviridae) is the main pathogen responsible for the citrus leprosis (CL) disease in Latin America, one of the most economically important diseases of the citrus industry. Molecular studies of this pathosystem are limited due to the lack of infectious clones. Here, we report the construction and validation of a CiLV-C infectious cDNA clone based on an agroinfection system. The two viral RNA segments (RNA1 and RNA2) were assembled into two binary vectors (pJL89 and pLXAS). Agroinfiltrated Nicotiana benthamiana plants showed a response similar to that observed in the natural infection process with the formation of localized lesions restricted to the inoculated leaves. The virus recovered from the plant tissue infected with the infectious clones can be mechanically transmitted between N. benthamiana plants. Detection of CiLV-C subgenomic RNAs (sgRNAs) from agroinfiltrated and mechanically inoculated leaves further confirmed the infectivity of the clones. Finally, partial particle-purification preparations or sections of CiLV-C-infected tissue followed by transmission electron microscopy (TEM) analysis showed the formation of CiLV-C virions rescued by the infectious clone. The CiLV-C reverse genetic system now provides a powerful molecular tool to unravel the peculiarities of the CL pathosystem.

Current outcomes of SARS-CoV-2 Omicron variant infection in high-risk haematological patients treated early with antivirals.

OBJECTIVES: We aimed to describe the clinical outcomes and duration of viral shedding in high-risk patients with haematological malignancies hospitalized with COVID-19 during Omicron variant predominance who received early treatment with antivirals. METHODS: We conducted a prospective observational study on high-risk haematological patients admitted in our hospital between December 2021 and March 2022. We performed detection techniques on viral subgenomic mRNAs until negative results were obtained to document active, prolonged viral replication. RESULTS: This analysis included 60 consecutive adults with high-risk haematological malignancies and COVID-19. All of these patients underwent early treatment with remdesivir. Thirty-two (53%) patients received combined antiviral strategies, with sotrovimab or hyperimmune plasma being added to remdesivir. The median length of viral replication-as measured by real-time RT-PCR and/or subgenomic RNA detection-was 20 (IQR 14-28) days. Prolonged viral replication (6 weeks after diagnosis) was documented in six (10%) patients. Only two patients had prolonged infection for more than 2 months. Overall mortality was 5%, whereas COVID-19-related mortality was 0%. CONCLUSIONS: Current outcomes of high-risk patients with haematological malignancies hospitalized with COVID-19 during Omicron variant predminance are good with the use of early antiviral strategies. Persistent viral shedding is uncommon.

Cell-penetrating porcine single-chain antibodies (transbodies) against nonstructural protein 1ß (NSP1ß) of porcine reproductive and respiratory syndrome virus inhibit virus replication.

Porcine reproductive and respiratory syndrome virus (PRRSV) causes porcine reproductive and respiratory syndrome (PRRS) worldwide, especially in domestic pigs, with an enormous economic impact, estimated at $664 million in losses every year to the pig industry. Current vaccines confer limited protection, and no direct-acting anti-PRRS treatment is available. Non-structural protein (NSP) 1ß, a cysteine-like protease (CLPro) of PRRSV plays an essential role in viral polyprotein processing, subgenomic RNA synthesis, and evasion of host innate immunity. Therefore, agents that interfere with the bioactivity of NSP1ß would be expected to inhibit virus replication. In this study, a porcine single-chain antibody (scFv)-phage display library was constructed and used as a tool for production of NSP1ß-specific porcine scFvs (pscFvs). The pscFvs to NSP1ß were linked to a cell-penetrating peptide to form cell-penetrating pscFvs (transbodies), which could be internalized and inhibit PRRSV replication in infected cells. A computer simulation indicated that the effective pscFvs used several residues in multiple complementarity determining regions (CDRs) to interact with multiple residues in the CLPro and C-terminal motifs, which might explain the mechanism of pscFv-mediated inhibition of virus replication. Although experiments are needed to determine the antiviral mechanism of the transbodies, the current data indicate that transbodies can potentially be applied for treatment and prevention of PRRSV infection.

The anti-immune dengue subgenomic flaviviral RNA is present in vesicles in mosquito saliva and is associated with increased infectivity.

Mosquito transmission of dengue viruses to humans starts with infection of skin resident cells at the biting site. There is great interest in identifying transmission-enhancing factors in mosquito saliva in order to counteract them. Here we report the discovery of high levels of the anti-immune subgenomic flaviviral RNA (sfRNA) in dengue virus 2-infected mosquito saliva. We established that sfRNA is present in saliva using three different methods: northern blot, RT-qPCR and RNA sequencing. We next show that salivary sfRNA is protected in detergent-sensitive compartments, likely extracellular vesicles. In support of this hypothesis, we visualized viral RNAs in vesicles in mosquito saliva and noted a marked enrichment of signal from 3'UTR sequences, which is consistent with the presence of sfRNA. Furthermore, we show that incubation with mosquito saliva containing higher sfRNA levels results in higher virus infectivity in a human hepatoma cell line and human primary dermal fibroblasts. Transfection of 3'UTR RNA prior to DENV2 infection inhibited type I and III interferon induction and signaling, and enhanced viral replication. Therefore, we posit that sfRNA present in salivary extracellular vesicles is delivered to cells at the biting site to inhibit innate immunity and enhance dengue virus transmission.

Complete genome sequence of a tentative novel capillovirus isolated from Gerbera jamesonii.

The currently named gerbera virus A (GeVA) has been shown to be a novel capillovirus with a complete genome of 6929 nucleotides (nt) (GenBank accession no. OM525829.1). GeVA was detected in Gerbera jamesonii using high-throughput RNA sequencing analysis. The GeVA genome is a single linear RNA with two open reading frames (ORF), similar to those of other capilloviruses. The larger ORF encodes a polyprotein containing four domains, while the smaller ORF encodes a movement protein. The complete genome had 41.0-54.9% nt sequence identity to other those of capilloviruses, while the polyprotein and the movement protein had 26.5-36.4% and 13.1-32.2% amino acid (aa) sequence identity, respectively. Two UUAGGU promoters for subgenomic RNA (sgRNA) transcription were also identified in this study. BLAST analysis demonstrated that the GeVA genome shared the highest sequence similarity with rubber tree capillovirus 1 (MN047299.1) (complete nucleotide sequence identity, 68.54%; polyprotein amino acid sequence identity, 44.53%). Phylogenetic analysis based on complete genome and replication protein sequences placed GeVA alongside other members of the genus Capillovirus in the family Betaflexiviridae. These data suggest that GeVA is a new member of the genus Capillovirus.

Viral target and metabolism-based rationale for combined use of recently authorized small molecule COVID-19 medicines: Molnupiravir, nirmatrelvir, and remdesivir.

The COVID-19 pandemic remains a major health concern worldwide, and SARS-CoV-2 is continuously evolving. There is an urgent need to identify new antiviral drugs and develop novel therapeutic strategies. Combined use of newly authorized COVID-19 medicines including molnupiravir, nirmatrelvir, and remdesivir has been actively pursued. Mechanistically, nirmatrelvir inhibits SARS-CoV-2 replication by targeting the viral main protease (Mpro ), a critical enzyme in the processing of the immediately translated coronavirus polyproteins for viral replication. Molnupiravir and remdesivir, on the other hand, inhibit SARS-CoV-2 replication by targeting RNA-dependent RNA-polymerase (RdRp), which is directly responsible for genome replication and production of subgenomic RNAs. Molnupiravir targets RdRp and induces severe viral RNA mutations (genome), commonly referred to as error catastrophe. Remdesivir, in contrast, targets RdRp and causes chain termination and arrests RNA synthesis of the viral genome. In addition, all three medicines undergo extensive metabolism with strong therapeutic significance. Molnupiravir is hydrolytically activated by carboxylesterase-2 (CES2), nirmatrelvir is inactivated by cytochrome P450-based oxidation (e.g., CYP3A4), and remdesivir is hydrolytically activated by CES1 but covalently inhibits CES2. Additionally, remdesivir and nirmatrelvir are oxidized by the same CYP enzymes. The distinct mechanisms of action provide strong rationale for their combined use. On the other hand, these drugs undergo extensive metabolism that determines their therapeutic potential. This review discusses how metabolism pathways and enzymes involved should be carefully considered during their combined use for therapeutic synergy.

Conserved Structure Associated with Different 3'CITEs Is Important for Translation of Umbraviruses.

The cap-independent translation of plus-strand RNA plant viruses frequently depends on 3' structures to attract translation initiation factors that bind ribosomal subunits or bind directly to ribosomes. Umbraviruses are excellent models for studying 3' cap-independent translation enhancers (3'CITEs), as umbraviruses can have different 3'CITEs in the central region of their lengthy 3'UTRs, and most also have a particular 3'CITE (the T-shaped structure or 3'TSS) near their 3' ends. We discovered a novel hairpin just upstream of the centrally located (known or putative) 3'CITEs in all 14 umbraviruses. These CITE-associated structures (CASs) have conserved sequences in their apical loops and at the stem base and adjacent positions. In 11 umbraviruses, CASs are preceded by two small hairpins joined by a putative kissing loop interaction (KL). Converting the conserved 6-nt apical loop to a GNRA tetraloop in opium poppy mosaic virus (OPMV) and pea enation mosaic virus 2 (PEMV2) enhanced translation of genomic (g)RNA, but not subgenomic (sg)RNA reporter constructs, and significantly repressed virus accumulation in Nicotiana benthamiana. Other alterations throughout OPMV CAS also repressed virus accumulation and only enhanced sgRNA reporter translation, while mutations in the lower stem repressed gRNA reporter translation. Similar mutations in the PEMV2 CAS also repressed accumulation but did not significantly affect gRNA or sgRNA reporter translation, with the exception of deletion of the entire hairpin, which only reduced translation of the gRNA reporter. OPMV CAS mutations had little effect on the downstream BTE 3'CITE or upstream KL element, while PEMV2 CAS mutations significantly altered KL structures. These results introduce an additional element associated with different 3'CITEs that differentially affect the structure and translation of different umbraviruses.

Modulation of Capsid Dynamics in Bromoviruses by the Host and Heterologous Viral Replicase.

The three genomic and a single subgenomic RNA of Cowpea chlorotic mottle virus (CCMV), which is pathogenic to plants, is packaged into three morphologically indistinguishable icosahedral virions with T=3 symmetry. The two virion types, C1V and C2V, package genomic RNAs 1 (C1) and 2 (C2), respectively. The third virion type, C3+4V, copackages genomic RNA3 and its subgenomic RNA (RNA4). In this study, we sought to evaluate how the alteration of native capsid dynamics by the host and viral replicase modulate the general biology of the virus. The application of a series of biochemical, molecular, and biological assays revealed the following. (i) Proteolytic analysis of the three virion types of CCMV assembled individually in planta revealed that, while retaining the structural integrity, C1V and C2V virions released peptide regions encompassing the N-terminal arginine-rich RNA binding motif. In contrast, a minor population of the C3+4V virion type was sensitive to trypsin-releasing peptides encompassing the entire capsid protein region. (ii) The wild-type CCMV virions purified from cowpea are highly susceptible to trypsin digestion, while those from Nicotiana benthamiana remained resistant, and (iii) finally, the matrix-assisted laser desorption ionization-time of flight (MALDI-TOF) analysis evaluated the relative dynamics of C3+4V and B3+4V virions assembled under the control of the homologous versus heterologous replicase. The role of viral replicase in modulating the capsid dynamics was evident by the differential sensitivity to protease exhibited by B3+4V and C3+4V virions assembled under the homologous versus heterologous replicase. Our results collectively conclude that constant modulation of capsid dynamics by the host and viral replicase is obligatory for successful infection. IMPORTANCE Infectious virus particles or virions are considered static structures and undergo various conformational transitions to replicate and infect many eukaryotic cells. In viruses, conformational changes are essential for establishing infection and evolution. Although viral capsid fluctuations, referred to as dynamics or breathing, have been well studied in RNA viruses pathogenic to animals, such information is limited among plant viruses. The primary focus of this study is to address how capsid dynamics of plant-pathogenic RNA viruses, namely, Cowpea chlorotic mottle (CCMV) and Brome mosaic virus (BMV), are modulated by the host and viral replicase. The results presented have improved and transformed our understanding of the functional relationship between capsid dynamics and the general biology of the virus. They are likely to provide stimulus to extend similar studies to viruses pathogenic to eukaryotic organisms.