Viral RNA Replication Research Articles

Dengue Virus Replicative-Form dsRNA Is Recognized by Both RIG-I and MDA5 to Activate Innate Immunity.

RIG-I like receptors (RLRs) are a family of cytosolic RNA sensors that sense RNA virus infection to activate innate immune response. It is generally believed that different RNA viruses are recognized by either RIG-I or MDA5, two important RLR members, depending on the nature of pathogen-associated molecular patterns (PAMPs) that are generated by RNA virus replication. Dengue virus (DENV) is an important RNA virus causing serious human diseases. Despite extensive investigations, the molecular basis of the DENV PAMP recognized by the host RLR has been poorly defined. Here, we demonstrated that the DENV infection-induced interferon response is dependent upon both RIG-I and MDA5, with RIG-I playing a predominant role. Next we purified the DENV PAMP RNA from the DENV-infected cells, and demonstrated that the purified DENV PAMP is viral full-length double-stranded RNA bearing 5'ppp modifications, likely representing the viral replicative-form RNA. Finally, we confirmed the nature of the DENV PAMP by reconstituting the viral replicative-form RNA from in vitro synthesized DENV genomic RNA. In conclusion, our work not only defined the molecular basis of the RLR-PAMP interaction during DENV infection, but also revealed the previously underappreciated recognition of a distinct moiety of the same PAMP by different RLRs in innate immunity against RNA viruses.

Comparison of transcriptome responses in blood cells of Atlantic salmon infected by three genotypes of Piscine orthoreovirus.

Piscine orthoreovirus (PRV) infection is common in aquaculture of salmonids. The three known PRV genotypes (PRV-1-3) have host species specificity and cause different diseases, but all infect and replicate in red blood cells (RBCs) in early infection phase. PRV-1 is the causative agent of heart and skeletal muscle inflammation (HSMI) in farmed Atlantic salmon (Salmo salar), PRV-2 causes erythrocytic inclusion body syndrome (EIBS) in coho salmon (Oncorhynchus kisutch), while PRV-3 induces HSMI-like disease in farmed rainbow trout (Oncorhynchus mykiss). PRV-3 can also infect A. salmon without causing clinical disease and has been shown to cross-protect against PRV-1 infection and HSMI, while PRV-2 or inactivated adjuvanted PRV-1 vaccine only partially reduced HSMI pathologic changes. In the present work, we studied the transcriptional responses in blood cells of A. salmon two- and five-weeks post infection with PRV-1, PRV-2, PRV-3, or post injection with inactivated PRV-1 vaccine. PRV-1 and PRV-3 replicated well in A. salmon blood cells, and both induced the typical innate antiviral responses triggered by dsRNA viruses. Two weeks post infection, PRV-3 triggered stronger antiviral responses than PRV-1, despite their similar viral RNA replication levels, but after five weeks the induced responses were close to equal. PRV-2 and the InPRV-1 vaccine did not trigger the same typical antiviral responses as the replicating PRV-1 and PRV-3 genotypes, but induced genes involved in membrane trafficking and signaling pathways that may regulate physiological functions. These findings propose that the protection mediated by PRV-3 against a secondary infection by PRV-1 occur due to a potent and early activation of the same type of innate immune responses. The difference in the timing of antiviral responses may give PRV-1 an evolutionary edge, facilitating its dissemination to A. salmon heart, a critical step for HSMI development.

Antiviral effects and mechanism of Qi pi pill against influenza viruses.

Qi pi pill (QPP), which contains Renshen, Baizhu, Fuling, Gancao, Chenpi, Shanyao, Lianzi, Shanzha, Liushenqu, Maiya, and Zexie, was recommended for preventing and treating COVID-19 in Shandong Province (China). However, the mechanism by which QPP treats infectious diseases remains unclear. This study aims to investigate the therapeutic effect of QPP invitro and on acute influenza infection in mice, exploring its mechanism of action against influenza A virus (IAV). The invitro activity of QPP was assessed using dose-response curve analysis and titer reduction assay, and its antiviral mechanism was identified invitro by real-time polymerase chain reaction (PCR), time-of-addition, and enzymatic assays. The antiviral efficacy of QPP was further evaluated invivo using BALB/c mice infected with IAV. At the same time, each single Chinese herbal medicine in QPP was evaluated to preliminarily identify those with antiviral effects. In vitro results showed that QPP exhibited a higher potency antiviral effect against both influenza A and B viruses, inhibiting viral RNA replication and release by targeting RNA-dependent RNA polymerase and neuraminidase. Additionally, QPP significantly decreased the expression of inflammatory cytokines in A549 cells. Invivo study revealed that QPP significantly reduced the lung index and viral load in lung tissue of mice infected with IAV. Renshen, Gancao, Zexie, and Lianzi were the Chinese herbal medicines from QPP that showed anti-IAV activity. The antiviral activity of QPP targets IAV replication and release, cytokine modulation in host cells, and provides protection in mice with acute influenza infection.

Influenza A virus NS2 protein acts on vRNA-resident polymerase to drive the transcription to replication switch.

The heterotrimeric RNA-dependent RNA polymerase (RdRp) of influenza A virus catalyzes viral RNA transcription (vRNA→mRNA) and replication (vRNA→cRNA→vRNA) by adopting different conformations. A switch from transcription to replication occurs at a relatively late stage of infection. We recently reported that the viral NS2 protein, expressed at later stages from a spliced transcript of the NS segment messenger RNA (mRNA), inhibits transcription, promotes replication and plays a key role in the transcription-to-replication switch. In this study, we performed comprehensive functional analyses to elucidate how NS2 promotes viral genome replication. Using a cell-based single-step RNP reconstitution assay, we found that NS2 specifically promotes the first-step vRNA-to-cRNA synthesis. Further investigation revealed that this promotion is tightly associated with the intrinsic properties of the 3'-vRNA promoter. Employing a highly sensitive complementation reporter assay, we demonstrated that NS2 associates more strongly with the vRNA-resident RdRp than the cRNA-resident RdRp. These findings were further validated through in vitro replication analyses. We, therefore, propose that influenza A virus NS2 protein targets vRNA-resident RdRp to drive the transcription-to-replication switch during infection.

Dengue virus is particularly sensitive to interference with long-chain fatty acid elongation and desaturation.

Orthoflaviviruses are emerging arthropod-borne pathogens whose replication cycle is tightly linked to host lipid metabolism. Previous lipidomic studies demonstrated that infection with the closely related hepatitis C virus (HCV) changes the fatty acid (FA) profile of several lipid classes. Lipids in HCV-infected cells had more very long-chain and desaturated FAs and viral replication relied on functional FA elongation and desaturation. Here, we systematically analyzed the role of FA elongases and desaturases in infection models of the most prevalent pathogenic orthoflaviviruses, dengue (DENV), Zika (ZIKV), West Nile (WNV), yellow fever (YFV), and tick-borne encephalitis virus (TBEV). Knockdown of desaturases and elongases in Huh7 cells only marginally affected ZIKV, WNV, YFV, and TBEV replication, while DENV titers were strongly reduced. This was most prominent for enzymes involved in very long-chain fatty acid synthesis. In detail, knockdown of the FA elongase ELOVL4, which catalyzes ultra long-chain FA synthesis, significantly reduced DENV titers, decreased the formation of replication intermediates, and lowered viral protein levels in DENV infected hepatoma cells, suggesting a function of ELOVL4 in DENV RNA replication. In contrast, the activity of FA desaturase FADS2, rate-limiting in poly-unsaturated FA biosynthesis, is not involved in viral RNA replication or translation, but is essentially required for formation of infectious DENV particles. Further, in immunocompetent immortalized microglial cells, FADS2 deletion additionally limits viral replication through increased expression of interferon-stimulated genes in response DENV infection. Taken together, enzymes involved in very long-chain FA synthesis are critical for different steps of DENV replication.

Characterization of the First Marine Pestivirus, Phocoena Pestivirus (PhoPeV).

The first marine pestivirus, Phocoena pestivirus (PhoPeV), isolated from harbor porpoise, has been recently described. To further characterize this unique pestivirus, its host cell tropism and growth kinetics were determined in different cell lines. In addition, the interaction of PhoPeV with innate immunity in porcine epithelial cells and the role of selected cellular factors involved in the viral entry and RNA replication of PhoPeV were investigated in comparison to closely and distantly related pestiviruses. While Bungowannah pestivirus (BuPV), a unique porcine pestivirus closely related to PhoPeV, exhibits a broad cell tropism, PhoPeV only infects cells from pigs, cattle, sheep, and cats, as has been described for classical swine fever virus (CSFV). Viral titers correlate with the amount of intracellular PhoPeV-specific RNA detected in the tested cell lines. PhoPeV replicates most efficiently in the porcine kidney cell line SK6. Pestiviruses generally counteract the cellular innate immune response by degradation of interferon regulatory factor 3 (IRF3) mediated by the viral N-terminal protease (Npro). No degradation of IRF3 and an increased expression of the type 1 interferon-stimulated antiviral protein Mx1 was observed in porcine cells infected with PhoPeV whose genome lacks the Npro encoding region. Infection of a CD46-deficient porcine cell line suggested that CD46, which is implicated in the viral entry of several pestiviruses, is not a major factor for the viral entry of PhoPeV. Moreover, the results of this study confirmed that the cellular factor DNAJC14 plays a crucial role in viral RNA replication of non-cytopathic pestiviruses, including PhoPeV.

BEND6 promotes RNA viruses' replication by inhibiting innate immune responses.

Innate immunity serves as a crucial defense mechanism against invading pathogens, yet its negative regulatory network remains under explored. In this study, we identify BEN domain-containing protein 6 (BEND6) as a novel negative regulator of innate immunity through a genome-scale CRISPR knockout screen for host factors essential for viral replication. We show that BEND6 exhibits characteristics of an interferon-stimulated gene (ISG), with its mRNA and protein levels upregulated by RNA virus-induced IFN-β. BEND6 targets IRF3 and inhibits its recruitment by TBK1, thus preventing IRF3 phosphorylation and dimerization. Additionally, BEND6 directly binds to ISRE, thereby hindering the DNA binding activity of IRF3 and blocking the subsequent activation of IFN-β transcription. Taken together, our study reveals the mechanism of BEND6 in promoting the replication of various RNA viruses and provides a potential therapeutic target for RNA virus infection.

The Compound AT13148 Targeting AKT Suppresses Dengue Virus 2 Replication.

Background: Dengue virus (DENV) infection, caused by serotypes DENV 1-4, represents a significant global public health challenge, with no antiviral drugs currently available for treatment. The host Protein kinase B (AKT) signaling pathway is crucial for DENV infection, presenting a potential target for antiviral drug development. Objective: This study aimed to evaluate the antiviral activity of kinase inhibitors that target the AKT pathway, focusing on the compound AT13148. Methods: A mini-screening was conducted to identify kinase inhibitors with antiviral properties against DENV-2. The effects of AT13148 on viral RNA replication and translation were assessed in a dose- and time-dependent manner following DENV-2 entry. The mechanism of action was further investigated by evaluating the impact of AT13148 on AKT kinase activity and phosphorylation status. Results: AT13148 exhibited potent antiviral activity against DENV-2, significantly inhibiting viral RNA replication and translation post-entry. The compound was found to inhibit AKT kinase activity through hyperphosphorylation. Conclusion: The findings indicate that AT13148 effectively targets the AKT pathway, demonstrating potential as an antiviral therapeutic against DENV-2 by interfering with the virus's post-entry processes. Further in vivo studies are warranted to assess the efficacy of AT13148 in controlling DENV infection.

Ubiquitin-like modifier-activating enzyme 1 interacts with Zika virus NS5 and promotes viral replication in the infected cell.

Translation errors, impaired folding or environmental stressors (e.g. infection) can all lead to an increase in the presence of misfolded proteins. These activate cellular responses to their removal, including intracellular protein degradation activities. Protein ubiquitylation is involved in two major degradation pathways, the ubiquitin-proteasome system and selective autophagy. In humans, the ubiquitin-like modifier-activating enzyme 1 (UBA1) is the primary E1 enzyme in the ubiquitin conjugation cascade. Viruses have evolved to exploit protein degradation pathways to complete their infection cycles. Zika virus (ZIKV) is an emerging orthoflavivirus causing serious neurologic disorders in neonates (congenital microcephaly) and adults (Guillain-Barré syndrome). Non-structural protein 5 (NS5), the largest and most conserved protein in the orthoflaviviruses, catalyses the synthesis and capping of new viral genomes. In addition to viral RNA replication in the cytoplasm, ZIKV NS5 is translocated into the nucleus to interfere with host antiviral responses. Here, we demonstrate that ZIKV NS5 co-immunoprecipitates with cellular UBA1. Immunofluorescence assays suggest that this interaction takes place primarily in the nucleus of an infected cell, although colocalization of both proteins is also detected in the cytosol. RNA interference-mediated depletion of UBA1 leads to reduced virus titres in the infected cells, while transient overexpression of UBA1 favours faster replication kinetics, with higher virus titres and protein levels detected. Moreover, UBA1-targeting drugs cause significant drops in virus infectivity. These results support a proviral role for UBA1 during ZIKV infection and encourage the potential use of inhibitors against this enzyme or its NS5-interacting epitopes as potential therapeutic targets.

Annual SZ: An Alternative Immunotherapy for COVID-19 and Long COVID.

Since the outbreak of coronavirus disease 2019 (COVID-19) in late 2019 and early 2020, the identification of drugs to control severe acute respiratory syndrome coro-navirus 2 (SARS-CoV-2) infection and its symptoms has been a pressing focus of research. Cytokine storm and acute respiratory distress syndrome (ARDS) are the leading causes of mortality following infection. In this review, we discuss immune pathogenesis and four medications, including Remdesivir, Tocilizumab, Dexamethasone, and Annual SZ for COVID-19. A comparison of the effectiveness and therapeutic usage of drugs as reported in clinical trials and reports was made at different disease levels as well. Clinical studies indicate that Annual SZ with mild side effects was more affordable and might be more effective than other medications. Additionally, Annual SZ was capable of reducing the lev-els of pro-inflammatory cytokines as well as viral attachment and RNA replication.

Identification of NECTIN1 as a novel restriction factor for flavivirus infection.

NECTIN1, also known as CD111 or PVRL1, has been recognized as the primary receptor for several alpha herpesviruses, including herpes simplex virus (HSV), pseudorabies virus (PRV), and bovine herpesvirus 1 (BHV-1). However, our study revealed a novel role for NECTIN1 in the virus life cycle by influencing BVDV infection. Contrary to its role as a receptor for alpha herpesviruses, NECTIN1 acts as a restriction factor for BVDV by inhibiting viral attachment via competition with CD46 for binding to the domain DD of BVDV E2. We further revealed that the replication of members of the Flaviviridae family was inhibited by NECTIN1, while the replication of other RNA viruses did not significantly differ. Our results demonstrate that NECTIN1 is a novel factor restricting Flaviviridae family virus replication and highlight the complexity of virus-host interactions and the multifaceted nature of host factors involved in viral infection.

Small-molecule inhibition of SARS-CoV-2 NSP14 RNA cap methyltransferase.

Coronavirus disease 2019 (COVID-19) is caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2)1. The rapid development of highly effective vaccines2,3 against SARS-CoV-2 has altered the trajectory of the pandemic, and antiviral therapeutics4 have further reduced the number of COVID-19 hospitalizations and deaths. Coronaviruses are enveloped, positive-sense, single-stranded RNA viruses that encode various structural and non-structural proteins, including those critical for viral RNA replication and evasion from innate immunity5. Here we report the discovery and development of a first-in-class non-covalent small-molecule inhibitor of the viral guanine-N7 methyltransferase (MTase) NSP14. High-throughput screening identified RU-0415529, which inhibited SARS-CoV-2 NSP14 by forming a unique ternary S-adenosylhomocysteine (SAH)-bound complex. Hit-to-lead optimization of RU-0415529 resulted in TDI-015051 with a dissociation constant (Kd) of 61 pM and a half-maximal effective concentration (EC50) of 11 nM, inhibiting virus infection in a cell-based system. TDI-015051 also inhibited viral replication in primary small airway epithelial cells and in a transgenic mouse model of SARS CoV-2 infection with an efficacy comparable with the FDA-approved reversible covalent protease inhibitor nirmatrelvir6. The inhibition of viral cap methylases as an antiviral strategy is also adaptable to other pandemic viruses.

Arabidopsis RNA-binding proteins interact with viral structural proteins and modify turnip yellows virus accumulation.

As obligate intracellular parasites, viruses depend on host proteins and pathways for their multiplication. Among these host factors, specific nuclear proteins are involved in the life cycle of some cytoplasmic replicating RNA viruses, although their role in the viral cycle remains largely unknown. The polerovirus turnip yellows virus (TuYV) encodes a major coat protein (CP) and a 74 kDa protein known as the readthrough (RT) protein. The icosahedral viral capsid is composed of the CP and a minor component RT*, arising from a C-terminal cleavage of the full-length RT. In this study, we identified Arabidopsis (Arabidopsis thaliana) ALY family proteins as interacting partners of TuYV structural proteins using yeast 2-hybrid assays and co-immunoprecipitations in planta. ALY proteins are adaptor proteins of the THO-TREX-1 complex essential to the nuclear export of mature messenger RNAs (mRNAs). Although all 4 ALY proteins colocalized with the CP and the RT protein in the nucleus upon co-expression in agro-infiltrated Nicotiana benthamiana leaves, only the CP remained nuclear and colocalized with ALY proteins in TuYV-infected cells, suggesting that the CP is an essential partner of ALY proteins. Importantly, TuYV-infected A. thaliana 4xaly knock-out mutants showed a significant increase in viral accumulation, indicating that TuYV infection is affected by an unknown ALY-mediated antiviral defense mechanism or impairs the cellular mRNA export pathway to favor viral RNA translation. This finding underpins the crucial role played by nuclear factors in the life cycle of cytoplasmic RNA viruses.

Mitophagosomes induced during EV-D68 infection promote viral nonlytic release.

Enterovirus-D68 (EV-D68) is a plus-strand RNA virus that primarily causes infant respiratory infections. In rare pediatric cases, infection with EV-D68 has been associated with acute flaccid myelitis, a polio-like paralytic disease. We have previously demonstrated that EV-D68 induces nonselective autophagy for its benefit. Here, we demonstrate that EV-D68 induces mitophagy, the specific autophagic degradation of mitochondria. EV-D68 infection induces mitophagosome formation and several hallmarks of mitophagy, including mitochondrial fragmentation, mitochondrial membrane potential loss, and Parkin translocation to the mitochondria were observed in EV-D68 infected cells. The 3C protease of EV-D68 cleaves the mitochondrial fusion protein, mitofusin-2, near the C-terminal HR2 domain to induce mitochondrial fragmentation, and these fragmented mitochondria colocalized with double-stranded RNA (dsRNA), which labels viral RNA replication sites after peak viral RNA replication. Depleting components of mitophagy signaling specifically reduced EV-D68 release without impacting viral intracellular titers. Our results suggest that whereas the machinery of macroautophagy supports various stages of enterovirus replication, including viral genomic RNA replication and capsid maturation, mitophagy is the specific form of autophagy that regulates the nonlytic release of enteroviruses from cells.

Inhibitors of dihydroorotate dehydrogenase synergize with the broad antiviral activity of 4′-fluorouridine

RNA viruses present a constant threat to human health, often with limited options for vaccination or therapy. Notable examples include influenza viruses and coronaviruses, which have pandemic potential. Filo- and henipaviruses cause more limited outbreaks, but with high case fatality rates. All RNA viruses rely on the activity of a virus-encoded RNA-dependent RNA polymerase (RdRp). An antiviral nucleoside analogue, 4'-Fluorouridine (4'-FlU), targets RdRp and diminishes the replication of several RNA viruses, including influenza A virus and SARS-CoV-2, through incorporation into nascent viral RNA and delayed chain termination. However, the effective concentration of 4'-FlU varied among different viruses, raising the need to fortify its efficacy. Here we show that inhibitors of dihydroorotate dehydrogenase (DHODH), an enzyme essential for pyrimidine biosynthesis, can synergistically enhance the antiviral effect of 4'-FlU against influenza A viruses, SARS-CoV-2, henipaviruses, and Ebola virus. Even 4'-FlU-resistant mutant influenza A virus was re-sensitized towards 4'-FlU by DHODH inhibition. The addition of uridine rescued influenza A virus replication, strongly suggesting uridine depletion as a mechanism of this synergy. 4'-FlU was also highly effective against SARS-CoV-2 in a hamster model of COVID. We propose that the impairment of endogenous uridine synthesis by DHODH inhibition enhances the incorporation of 4'-FlU into viral RNAs. This strategy may be broadly applicable to enhance the efficacy of pyrimidine nucleoside analogues for antiviral therapy.

Cryptic phosphoribosylase activity of NAMPT restricts the virion incorporation of viral proteins.

As obligate intracellular pathogens, viruses activate host metabolic enzymes to supply intermediates that support progeny production. Nicotinamide phosphoribosyltransferase (NAMPT), the rate-limiting enzyme of salvage nicotinamide adenine dinucleotide (NAD+) synthesis, is an interferon-inducible protein that inhibits the replication of several RNA and DNA viruses through unknown mechanisms. Here, we show that NAMPT restricts herpes simplex virus type 1 (HSV-1) replication by impeding the virion incorporation of viral proteins owing to its phosphoribosyl-hydrolase (phosphoribosylase) activity, which is independent of the role of NAMPT in NAD+ synthesis. Proteomics analysis of HSV-1-infected cells identifies phosphoribosylated viral structural proteins, particularly glycoproteins and tegument proteins, which are de-phosphoribosylated by NAMPT in vitro and in cells. Chimeric and recombinant HSV-1 carrying phosphoribosylation-resistant mutations show that phosphoribosylation promotes the incorporation of structural proteins into HSV-1 virions and subsequent virus entry. Loss of NAMPT renders mice highly susceptible to HSV-1 infection. Our work describes an additional enzymatic activity of a metabolic enzyme in viral infection and host defence, offering a system to interrogate the roles of protein phosphoribosylation in metazoans.

Targeting PRMT7-mediated monomethylation of MAVS enhances antiviral innate immune responses and inhibits RNA virus replication

RIG-I-like receptors (RLRs)-mitochondrial antiviral signaling protein (MAVS) are crucial for type I interferon (IFN) signaling pathway and innate immune responses triggered by RNA viruses. However, the regulatory molecular mechanisms underlying RNA virus-activated type I IFN signaling pathway remain incompletely understood. Here, we found that protein arginine methyltransferase 7 (PRMT7) serves as a negative regulator of the type I IFN signaling pathway by interacting with MAVS and catalyzing monomethylation of arginine 232 (R232me1) in MAVS. RNA virus infection leads to the downregulation and dissociation of PRMT7 from MAVS as well as the decrease of R232me1 methylation, enhancing MAVS/RIG-I interaction, MAVS aggregation, type I IFN signaling activation, and antiviral immune responses. Knock-in mice with MAVS R232 substituted with lysine (MavsR232K-KI) are more resistant to Vesicular Stomatitis Virus infection due to enhanced antiviral immune responses. PiPRMT7-MAVS, a short peptide inhibitor designed to interrupt the interaction between PRMT7 and MAVS, inhibits R232me1 methylation, thereby enhancing MAVS/RIG-I interaction, promoting MAVS aggregation, activating type I IFN signaling, and bolstering antiviral immune responses to suppress RNA virus replication. Moreover, the clinical relevance of PRMT7 is highlighted that it is significantly downregulated in RNA virus-infected clinical samples, such as blood samples from severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) and Ebola virus, as well as H1N1-infected bronchial epithelial cells. Our findings uncovered that PRMT7-mediated arginine methylation plays critical roles in regulating MAVS-mediated antiviral innate immune responses, and targeting arginine methylation might represent a therapeutic avenue for treating RNA viral infection.

Imaging of Viral Genomic RNA Replication with Nanoprobes.

Viruses are a great threat to human life and health. Different viruses have its unique mechanism to efficiently infect cells, and the entry process and the nucleic acid replication using cell machine are two critical processes related to the fate of virus progeny. Real-time and long-term imaging techniques can be used to thoroughly investigate the viral infection events. This chapter will present the labeling of viral genomic RNA (gRNA) replication by developing new nanoprobes, one-donor-two-acceptors one, for example, in which the synergistic coupling of multiple energy transfer strategy, so as that the journey of viruses in live cells could be monitored and imaged in real time. Methods of labeling as well as that used for fluorescent and dark field scattering imaging are outlined.

Fangchinoline Inhibits Zika Virus by Disrupting Virus Internalization.

The Zika virus (ZIKV) has garnered significant public attention, particularly following the outbreak in Brazil, due to its potential to cause severe damage to the central nervous system and its ability to cross the placental barrier, resulting in microcephaly in infants. Despite the urgency, there remains a lack of targeted therapies or vaccines for the prevention or treatment of ZIKV infection and its related diseases. Fangchinoline (FAN), an alkaloid derived from traditional Chinese medicinal herbs, has a range of biological activities. In this study, we employed both in vitro and in vivo infection models to demonstrate the efficacy of FAN in inhibiting ZIKV. Our findings indicate that FAN effectively suppresses the replication of ZIKV viral RNA and protein, thereby validating its anti-ZIKV capabilities in living organisms. Further analysis through dosing time assays and infectious inhibition assays revealed that FAN exerts its antiviral effects by impeding the early stages of infection, specifically by inhibiting the internalization of ZIKV. These results underscore the potential of FAN as a candidate for anti-ZIKV drug development and offer novel insights into drug design strategies that target the virus's internalization process.

A coronaviral pore-replicase complex links RNA synthesis and export from double-membrane vesicles.

Coronavirus-infected cells contain double-membrane vesicles (DMVs) that are key for viral RNA replication and transcription, perforated by hexameric pores connecting the vesicular lumen to the cytoplasm. How pores form and traverse two membranes, and how DMVs organize RNA synthesis, is unknown. Using structure prediction and functional assays, we show that the nonstructural viral membrane protein nsp4 is the key pore organizer, spanning the double membrane and forming most of the pore lining. Nsp4 interacts with nsp3 on the cytoplasmic side and with the viral replicase inside the DMV. Newly synthesized mRNAs exit the DMV into the cytoplasm, passing through a narrow ring of conserved nsp4 residues. Steric constraints imposed by the ring predict that modified nucleobases block mRNA transit, resulting in broad-spectrum anticoronaviral activity.