Acetylation of the NS3 helicase by KAT5γ is essential for flavivirus replication

UFMylation promotes orthoflavivirus infectious particle production

Post-translational modifications play crucial roles in regulating viral infections, yet roles for many modifications remain unexplored in orthoflavivirus biology. Here, we demonstrate that the UFMylation system, a post-translational modification pathway that catalyzes the transfer of UFM1 onto proteins and promotes infection by multiple orthoflaviviruses, including dengue virus (DENV), Zika virus (ZIKV), West Nile virus, and yellow fever virus. We found that depletion of the UFMylation E3 ligase complex proteins UFL1 and UFBP1, as well as other UFMylation machinery components (UBA5, UFC1, and UFM1), significantly reduces orthoflavivirus infectious virion production. This regulation was specific to orthoflaviviruses as the hepacivirus and member of the broader Flaviviridae family, hepatitis C virus, was not regulated by UFL1. Mechanistically, UFMylation did not regulate viral RNA translation, RNA replication, or virion egress but instead affected the assembly of infectious virions. Furthermore, we identified novel interactions between UFL1 and several viral proteins involved in orthoflavivirus virion assembly, including NS2A, NS2B-NS3, and capsid. These findings establish UFMylation as a previously unrecognized post-translational modification pathway that promotes orthoflavivirus infection through modulation of viral assembly. This work expands our understanding of the post-translational modifications that control orthoflavivirus infection and identifies new potential therapeutic targets.IMPORTANCEOrthoflaviviruses depend on host-mediated post-translational modifications to successfully complete their life cycle, yet many of these critical interactions remain undefined. Here, we describe a role for a post-translational modification pathway, UFMylation, in promoting infectious particle production of ZIKV and DENV. We show that UFMylation is dispensable for initial RNA translation and RNA replication but promotes the assembly of infectious virions. Additionally, we find that regulation of infection by UFMylation extends to other orthoflaviviruses, including West Nile virus and yellow fever virus, but not to the broader Flaviviridae family. Finally, we demonstrate that UFMylation machinery directly interacts with specific DENV and ZIKV proteins during infection. These studies reveal a previously unrecognized role for UFMylation in regulating orthoflavivirus infection.

An integrated proteomics approach identifies phosphorylation sites on viral and host proteins that regulate West Nile virus infection

Upon infection, viruses alter the proteome, creating a hospitable environment for infection. Cells respond to limit viral replication, including through protein regulation by post-translational modifications. We use mass spectrometry to define proteome alterations during West Nile virus (WNV) infection. Our studies identify upregulation of HERPUD1, which restricts WNV replication through a mechanism independent of its role in endoplasmic reticulum (ER)-associated degradation (ERAD). We also identify modifications on viral proteins, including a WNV NS3 phosphorylation site that impacts viral replication. Finally, we reveal activation of two host kinases with antiviral activity. We identify phosphorylation at S108 of AMPKβ1, a non-catalytic subunit that regulates activity of the AMPK complex. We also show activation of PAK2 by phosphorylation at S141, which restricts translation of the viral genome. This work contributes to our understanding of the interplay between host and virus while providing a resource to define the changes to the proteome that regulate viral infection.

TRIM23 mediates cGAS-induced autophagy in anti-HSV defense

The cGAS-STING pathway, well-known to elicit interferon (IFN) responses, is also a key inducer of autophagy upon virus infection or other stimuli. Whereas the mediators for cGAS-induced IFN responses are well characterized, much less is known about how cGAS elicits autophagy. Here, we report that TRIM23, a unique TRIM protein harboring both ubiquitin E3 ligase and GTPase activity, is crucial for cGAS-STING-dependent antiviral autophagy. Genetic ablation of TRIM23 impairs autophagic control of HSV-1 infection. HSV-1 infection or cGAS-STING stimulation induces TBK1-mediated TRIM23 phosphorylation at S39, which triggers TRIM23 autoubiquitination and GTPase activity and ultimately elicits autophagy. Fibroblasts from a patient with herpes simplex encephalitis heterozygous for a dominant-negative, kinase-inactivating TBK1 mutation fail to activate autophagy by TRIM23 and cGAS-STING. Our results thus identify the cGAS-STING-TBK1-TRIM23 axis as a key autophagy defense pathway and may stimulate new therapeutic interventions for viral or inflammatory diseases.

Changes in the motifs in the D0 and SD2 domains of the S protein drive the evolution of virulence in enteric coronavirus porcine epidemic diarrhea virus

Since 2010, highly virulent mutant GII subtype porcine epidemic diarrhea virus (PEDV) strains derived from GI subtype strains have caused significant economic losses in the pig industry. However, the molecular mechanism of PEDV virulence evolution remains unclear. It has been predicted that, compared to the S proteins of GI strains, five N-linked glycosylation sites have changed in the highly virulent GII PEDV strains. To investigate how changes in these sites affect PEDV virulence, we constructed five recombinant strains harboring the above mutation sites using the GII subtype rPEDV-Swt as the backbone, among which rPEDV-Smut62, rPEDV-Smut118, rPEDV-Smut131, and rPEDV-Smut722 were successfully rescued, but rPEDV-Smut235 was not. Compared to infection with rPEDV-Swt (100%), infection with rPEDV-Smut62 and rPEDV-Smut722 resulted in lower mortality in piglets (33%), and although rPEDV-Smut118 and rPEDV-Smut131 resulted in high mortality (100%), death was delayed. All surviving piglets were challenged orally with rPEDV-Swt at 21 days post-infection. The piglets in the rPEDV-Smut62 and rPEDV-Smut722 groups produced high levels of IgG, IgA, and cross-protective neutralizing antibodies, which protected the piglets after rPEDV-Swt challenge. Furthermore, the change in the structures of the rPEDV-Smut62 and rPEDV-Smut722 S proteins predicted with high precision by AlphaFold 3 may be the cause of the attenuated virulence. Our data provide a unique perspective on the molecular mechanism of PEDV virulence evolution from the GI to the GII subtype and identify the targets of PED live attenuated vaccines.

IMPORTANCE

The continuous emergence of novel viral variants in the current landscape poses challenges for disease prevention and control. Before 2010, PED caused by GI strains was only sporadic outbreaks and not large-scale epidemics. Since 2010, highly virulent GII strains derived from GI strains have spread worldwide and caused significant economic losses. However, the molecular mechanism underlying the differences in virulence is still unclear. In this study, the differences in the predicted glycosylation sites of the S protein between the GI and GII strains were taken as the starting point to explore the key sites responsible for the variations in PEDV virulence. The results indicate that the motifs 57ENQGVNST64 and 722NSTF725 of the S protein in the GII strains are involved in the evolution of PEDV virulence. This study provides a new perspective on the molecular mechanism of PEDV virulence evolution.

Towards a Universal Translator: Decoding the PTMs That Regulate Orthoflavivirus Infection

Post-translational modifications (PTMs) serve as critical regulators of protein function across biological systems, including during viral infection. For orthoflaviviruses, including human pathogens like dengue, Zika, and West Nile viruses, PTMs on viral proteins regulate multiple aspects of the viral lifecycle and pathogenesis. Here, we review the mechanisms by which PTMs regulate orthoflavivirus infection in both vertebrate and arthropod hosts. We examine how ubiquitination and glycosylation on the viral envelope proteins facilitate viral entry and how phosphorylation, SUMOylation, and acetylation on non-structural proteins modulate viral RNA replication. Additionally, we describe how PTMs on viral structural proteins dynamically regulate viral assembly and egress. We also describe how PTMs can influence tissue tropism and host-specific pathogenesis, with some modifications showing divergent functions between arthropod vectors and vertebrate hosts, and how the host antiviral response can trigger specific PTMs on viral proteins to restrict infection, highlighting PTMs as key mediators of host-pathogen interactions. While significant progress has been made in identifying PTMs on viral proteins, many questions remain about their temporal dynamics, mechanisms of action, and conservation across the orthoflavivirus genus. Understanding how PTMs regulate orthoflavivirus infection may reveal new therapeutic strategies, particularly given recent advances in targeting specific protein modifications for disease treatment.

Functional Roles and Host Interactions of Orthoflavivirus Non-Structural Proteins During Replication

Orthoflavivirus, a genus encompassing arthropod-borne, positive-sense, single-stranded RNA viruses in the Flaviviridae family, represents clinically relevant viruses that pose significant threats to human and animal health worldwide. With warming climates and persistent urbanization, arthropod vectors and the viruses they transmit continue to widen their geographic distribution, expanding endemic zones. Flaviviruses such as dengue virus, Zika virus, West Nile virus, and tick-borne encephalitis virus cause debilitating and fatal infections globally. In 2024, the World Health Organization and the Pan American Health Organization declared the current dengue situation a Multi-Country Grade 3 Outbreak, the highest level. FDA-approved treatment options for diseases caused by flaviviruses are limited or non-existent, and vaccines are suboptimal for many flaviviruses. Understanding the molecular characteristics of the flavivirus life cycle, virus-host interactions, and resulting pathogenesis in various cells and model systems is critical for developing effective therapeutic intervention strategies. This review will focus on the virus-host interactions of mosquito- and tick-borne flaviviruses from the virus replication and assembly perspective, emphasizing the interplay between viral non-structural proteins and host pathways that are hijacked for their advantage. Highlighting interaction pathways, including innate immunity, intracellular movement, and membrane modification, emphasizes the need for rigorous and targeted antiviral research and development against these re-emerging viruses.

UFMylation promotes orthoflavivirus infectious particle production

Post-translational modifications play crucial roles in viral infections, yet many potential modifications remain unexplored in orthoflavivirus biology. Here we demonstrate that the UFMylation system, a post-translational modification system that catalyzes the transfer of UFM1 onto proteins, promotes infection by multiple orthoflaviviruses including dengue virus, Zika virus, West Nile virus, and yellow fever virus. We found that depletion of the UFMylation E3 ligase complex proteins UFL1 and UFBP1, as well as other UFMylation machinery components (UBA5, UFC1, and UFM1), significantly reduces infectious virion production for orthoflaviviruses but not the hepacivirus, hepatitis C. Mechanistically, UFMylation does not regulate viral RNA translation or RNA replication but instead affects a later stage of the viral lifecycle. We identified novel interactions between UFL1, and several viral proteins involved in orthoflavivirus virion assembly, including NS2A, NS2B-NS3, and Capsid. These findings establish UFMylation as a previously unrecognized post-translational modification system that promotes orthoflavivirus infection, likely through modulation of viral assembly. This work expands our understanding of the post-translational modifications that control orthoflavivirus infection and identifies new potential therapeutic targets.

Understanding Post-Translational Modifications in Porcine Reproductive and Respiratory Syndrome Virus Infection

Porcine reproductive and respiratory syndrome virus (PRRSV) is a highly contagious virus affecting pigs with significant impacts to the swine industry worldwide. This review provides a comprehensive understanding of post-translational modifications (PTMs) associated with PRRSV infection. We discuss the various types of PTMs, including phosphorylation, ubiquitination, SUMoylation, acetylation, glycosylation, palmitoylation, and lactylation, that occur during PRRSV infection. We emphasize how these modifications affect the function and activity of viral proteins, thereby influencing virus replication, assembly, and egress. Additionally, we delve into the host cellular responses triggered by PRRSV, particularly the PTMs that regulate host signaling pathways and immune responses. Furthermore, we summarize the current understandings of how PTMs facilitate the ability of virus to evade the host immune system, enabling it to establish persistent infections. Finally, we address the implications of these modifications in the development of novel antiviral strategies and the potential for exploiting PTMs as therapeutic targets. This review highlights the significance of PTMs in shaping viral pathogenicity and host antiviral mechanisms and provides valuable insights for future research aimed at developing effective interventions against PRRSV infections.

Multi-proteomics and interactome dataset of tick-borne encephalitis virus infected host cells

Tick-borne encephalitis virus (TBEV) is a significant viral pathogen transmitted by ticks, causing severe neurological complications in humans across Europe and Asia, highlighting the urgent need for an in-depth understanding of molecular functions of viral proteins and their interactions with the host proteome. Multi-omics analysis of how TBEV hijack cellular processes provides information about their replication and pathogenic mechanisms. Here, we focused on the proteome, phosphoproteome, and acetylproteome of Vero cells infected by TBEV, revealing the host perturbations triggered by TBEV infection. Additionally, we performed protein-protein interactome analysis to examine the interactions between TBEV and the host. We have provided technical validation, demonstrating the high quality and correlation of samples across all datasets, and evidence of biological consistency of virus-infected cells at the proteomic, phosphoproteomics and acetylomic levels. This comprehensive multi-omics dataset serves as a valuable resource for studying TBEV pathogenesis and identifying potential drug targets for TBEV therapy.

Balancing acts: The posttranslational modification tightrope of flavivirus replication

Posttranslational modifications (PTMs) such as phosphorylation, ubiquitination, SUMOylation, and ISGylation are involved in various cellular pathways, including innate immunity and disease processes. Many viruses have developed sophisticated mechanisms to modulate these host PTMs, either by inhibiting the interferon pathway or by enhancing the stability and function of viral proteins essential for replication. In this Pearl, we review the literature on how flaviviruses are impacted by and exploit posttranslational modifications to their advantage.

MDA5 ISGylation is crucial for immune signaling to control viral replication and pathogenesis

The posttranslational modification (PTM) of innate immune sensor proteins by ubiquitin or ubiquitin-like proteins is crucial for regulating antiviral host responses. The cytoplasmic dsRNA receptor melanoma differentiation-associated protein 5 (MDA5) undergoes several PTMs including ISGylation within its first caspase activation and recruitment domain (CARD), which promotes MDA5 signaling. However, the relevance of MDA5 ISGylation for antiviral immunity in an infected organism has been elusive. Here, we generated knock-in mice (MDA5 K23R/K43R ) in which the two major ISGylation sites, K23 and K43, in MDA5 were mutated. Primary cells derived from MDA5 K23R/K43R mice exhibited abrogated endogenous MDA5 ISGylation and an impaired ability of MDA5 to form oligomeric assemblies leading to blunted cytokine responses to MDA5 RNA-agonist stimulation or infection with encephalomyocarditis virus (EMCV) or West Nile virus. Phenocopying MDA5 -/- mice, the MDA5 K23R/K43R mice infected with EMCV displayed increased mortality, elevated viral titers, and an ablated induction of cytokines and chemokines compared to WT mice. Molecular studies identified human HERC5 (and its functional murine homolog HERC6) as the primary E3 ligases responsible for MDA5 ISGylation and activation. Taken together, these findings establish the importance of CARD ISGylation for MDA5-mediated RNA virus restriction, promoting potential avenues for immunomodulatory drug design for antiviral or anti-inflammatory applications.

Orthoflaviviral Inhibitors in Clinical Trials, Preclinical In Vivo Efficacy Targeting NS2B-NS3 and Cellular Antiviral Activity via Competitive Protease Inhibition

Orthoflaviviruses, including zika (ZIKV), West Nile (WNV), and dengue (DENV) virus, induce severely debilitating infections and contribute significantly to the global disease burden, yet no clinically approved antiviral treatments exist. This review offers a comprehensive analysis of small-molecule drug development targeting orthoflaviviral infections, with a focus on NS2B-NS3 inhibition. We systematically examined clinical trials, preclinical efficacy studies, and modes of action for various viral replication inhibitors, emphasizing allosteric and orthosteric drugs inhibiting NS2B-NS3 protease with in vivo efficacy and in vitro-tested competitive NS2B-NS3 inhibitors with cellular efficacy. Our findings revealed that several compounds with in vivo preclinical efficacy failed to show clinical antiviral efficacy. NS3-NS4B inhibitors, such as JNJ-64281802 and EYU688, show promise, recently entering clinical trials, underscoring the importance of developing novel viral replication inhibitors targeting viral machinery. To date, the only NS2B-NS3 inhibitor that has undergone clinical trials is doxycycline, however, its mechanism of action and clinical efficacy as viral growth inhibitor require additional investigation. SYC-1307, an allosteric inhibitor, exhibits high in vivo efficacy, while temoporfin and methylene blue represent promising orthosteric non-competitive inhibitors. Compound 71, a competitive NS2B-NS3 inhibitor, emerges as a leading preclinical candidate due to its high cellular antiviral efficacy, minimal cytotoxicity, and favorable in vitro pharmacokinetic parameters. Challenges remain in developing competitive NS2B-NS3 inhibitors, including appropriate biochemical inhibition assays as well as the selectivity and conformational flexibility of the protease, complicating effective antiviral treatment design.

ADAM9 promotes type I interferon-mediated innate immunity during encephalomyocarditis virus infection

Viral myocarditis, an inflammatory disease of the heart, causes significant morbidity and mortality. Type I interferon (IFN)-mediated antiviral responses protect against myocarditis, but the mechanisms are poorly understood. We previously identified A Disintegrin And Metalloproteinase domain 9 (ADAM9) as an important factor in viral pathogenesis. ADAM9 is implicated in a range of human diseases, including inflammatory diseases; however, its role in viral infection is unknown. Here, we demonstrate that mice lacking ADAM9 are more susceptible to encephalomyocarditis virus (EMCV)-induced death and fail to mount a characteristic type I IFN response. This defect in type I IFN induction is specific to positive-sense, single-stranded RNA (+ ssRNA) viruses and involves melanoma differentiation-associated protein 5 (MDA5)-a key receptor for +ssRNA viruses. Mechanistically, ADAM9 binds to MDA5 and promotes its oligomerization and thereby downstream mitochondrial antiviral-signaling protein (MAVS) activation in response to EMCV RNA stimulation. Our findings identify a role for ADAM9 in the innate antiviral response, specifically MDA5-mediated IFN production, which protects against virus-induced cardiac damage, and provide a potential therapeutic target for treatment of viral myocarditis.

A 2D-proteomic analysis identifies proteins differentially regulated by two different dengue virus serotypes

The mosquito transmitted dengue virus (DENV) is a major public health problem in many tropical and sub-tropical countries around the world. Both vaccine development and drug development are complex as the species Dengue virus consist of four distinct viruses (DENV 1 to DENV 4) each of which is composed of multiple lineages and strains. To understand the interaction of DENV with the host cell machinery, several studies have undertaken in vitro proteomic analysis of different cell lines infected with DENV. Invariably, these studies have utilized DENV 2. In this study we sought to define proteins that are differentially regulated by two different DENVs, DENV 2 and DENV 4. A 2-dimensional proteomic analysis identified some 300 protein spots, of which only 11 showed differential expression by both DENVs. Of these, only six were coordinately regulated. One protein, prohibitin 1 (PHB1) was downregulated by infection with both DENVs. Overexpression of PHB1 increased DENV protein expression, level of infection and genome copy number. DENV E protein colocalized with PHB, and there was a direct interaction between DENV 2 E protein and PHB1, but not between DENV 4 E protein and PHB1. The low number of proteins showing coordinate regulation after infection by different DENVs is a cause for concern, particularly in determining new druggable targets, and suggests that studies should routinely investigate multiple DENVs.

Regulation and mechanisms of action of RNA helicases

RNA helicases are an evolutionary conserved class of nucleoside triphosphate dependent enzymes found in all kingdoms of life. Their cellular functions range from transcription regulation up to maintaining genomic stability and viral defence. As dysregulation of RNA helicases has been shown to be involved in several cancers and various diseases, RNA helicases are potential therapeutic targets. However, for selective targeting of a specific RNA helicase, it is crucial to develop a detailed understanding about its dynamics and regulation on a molecular and structural level. Deciphering unique features of specific RNA helicases is of fundamental importance not only for future drug development but also to deepen our understanding of RNA helicase regulation and function in cellular processes. In this review, we discuss recent insights into regulation mechanisms of RNA helicases and highlight models which demonstrate the interplay between helicase structure and their functions.