Danyang Gong

25-Hydroxycholesterol Protects Host against Zika Virus Infection and Its Associated Microcephaly in a Mouse Model.

SUMMARY Zika virus (ZIKV) has become a public health threat due to its global transmission and link to severe congenital disorders. The host immune responses to ZIKV infection have not been fully elucidated, and effective therapeutics are not currently available. Herein, we demonstrated that cholesterol‐25‐hydroxylase (CH25H) was induced in response to ZIKV infection and that its enzymatic product, 25‐hydroxycholesterol (25HC), was a critical mediator of host protection against ZIKV. Synthetic 25HC addition inhibited ZIKV infection in vitro by blocking viral entry, and treatment with 25HC reduced viremia and conferred protection against ZIKV in mice and rhesus macaques. 25HC suppressed ZIKV infection and reduced tissue damage in human cortical organoids and the embryonic brain of the ZIKV‐induced mouse microcephaly model. Our findings highlight the protective role of CH25H during ZIKV infection and the potential use of 25HC as a natural antiviral agent to combat ZIKV infection and prevent ZIKV‐associated outcomes, such as microcephaly. HIGHLIGHTSCH25H and its enzymatic product, 25HC, inhibit ZIKV entry in vitro25HC attenuates ZIKV‐associated viremia and disease in mice and non‐human primates25HC prevents ZIKV infection in human cortical organoids25HC protects fetal mice from microcephaly caused by ZIKV infection &NA; Zika virus (ZIKV) presents a major challenge to the global health system. Li et al. find that 25‐hydroxycholesterol (25HC) inhibits ZIKV infection in monkeys and human cortical organoids and protects mice from microcephaly. 25HC has potential as a first‐line antiviral agent to combat a broad array of pathogenic species, including ZIKV.

Organization of Capsid-Associated Tegument Components in Kaposi's Sarcoma-Associated Herpesvirus

ABSTRACT Capsid-associated tegument proteins have been identified in alpha- and betaherpesviruses to play an essential role in viral DNA packaging. Whether and how such tegument proteins exist in gammaherpesviruses have been mysteries. Here, we report a 6-Å-resolution cryo-electron microscopy (cryo-EM) structure of Kaposis sarcoma-associated herpesvirus (KSHV) virion, a member of the oncogenic gammaherpesvirus subfamily. The KSHV virion structure reveals, for the first time, how capsid-associated tegument proteins are organized in a gammaherpesvirus, with five tegument densities capping each penton vertex, a pattern highly similar to that in alphaherpesvirus but completely different from that in betaherpesvirus. Each KSHV tegument density can be divided into three prominent regions: a penton-binding globular region, a helix-bundle stalk region, and a β-sheet-rich triplex-binding region. Fitting of the crystal structure of the truncated HSV-1 UL25 protein (the KSHV ORF19 homolog) and secondary structure analysis of the full-length ORF19 established that ORF19 constitutes the globular region with an N-terminal, 60-amino-acid-long helix extending into the stalk region. Matching secondary structural features resolved in the cryo-EM density with secondary structures predicted by sequence analysis identifies the triplex-binding region to be ORF32, a homolog of alphaherpesvirus UL17. Despite the high level of tegument structural similarities between KSHV and alphaherpesvirus, an ORF19 monomer in KSHV, in contrast to a UL25 dimer in alphaherpesviruses, binds each penton subunit, an observation that correlates with conformational differences in their pentons. This newly discovered organization of triplex-ORF32-ORF19 also resolves a long-standing mystery surrounding the virion location and conformation of alphaherpesvirus UL25 protein. IMPORTANCE Several capsid-associated tegument proteins have been identified in the alpha- and betaherpesvirus subfamilies of the Herpesviridae. These tegument proteins play essential roles in viral propagation and are potential drug targets for curbing herpesvirus infections. However, no such tegument proteins have been identified for gammaherpesviruses, the third herpesvirus subfamily, which contains members causing several human cancers. Here, by high-resolution cryo-EM, we show the three-dimensional structure of the capsid-associated tegument proteins in the prototypical member of gammaherpesviruses, KSHV. The cryo-EM structure reveals that the organization of KSHV capsid-associated tegument proteins is highly similar to that in alphaherpesvirus but completely different from that in betaherpesvirus. Structural analyses further localize ORF19 and ORF32 proteins (the alphaherpesvirus UL25 and UL17 homologs in KSHV, respectively) in the KSHV capsid-associated tegument cryo-EM structure. These findings also resolve a long-standing mystery regarding the location and conformation of alphaherpesvirus UL25 protein inside the virion.

Kaposi's Sarcoma-Associated Herpesvirus ORF18 and ORF30 Are Essential for Late Gene Expression during Lytic Replication

ABSTRACT Kaposis sarcoma-associated herpesvirus (KSHV) is associated with several human malignances. As saliva is likely the major vehicle for KSHV transmission, we studied in vitro KSHV infection of oral epithelial cells. Through infection of two types of oral epithelial cells, normal human oral keratinocytes (NHOKs) and papilloma-immortalized human oral keratinocyte (HOK16B) cells, we found that KSHV can undergo robust lytic replication in oral epithelial cells. By employing de novo lytic infection of HOK16B cells, we studied the functions of two previously uncharacterized genes, ORF18 and ORF30, during the KSHV lytic cycle. For this purpose, an ORF18-deficient virus and an ORF30-deficient virus were generated using a mutagenesis strategy based on bacterial artificial chromosome (BAC) technology. We found that neither ORF18 nor ORF30 is required for immediately early or early gene expression or viral DNA replication, but each is essential for late gene expression during both de novo lytic replication and reactivation. This critical role of ORF18 and ORF30 in late gene expression was also observed during KSHV reactivation. In addition, global analysis of viral transcripts by RNA sequencing indicated that ORF18 and ORF30 control the same set of viral genes. Therefore, we suggest that these two viral ORFs are involved in the same mechanism or pathway that coregulates the viral late genes as a group. IMPORTANCE While KSHV can infect multiple cell types in vitro, only a few can support a full lytic replication cycle with progeny virions produced. Consequently, KSHV lytic replication is mostly studied through reactivation, which requires chemicals to induce the lytic cycle or overexpression of the viral transcriptional activator, RTA. In this study, we present a robust de novo lytic infection system based on oral epithelial cells. Using this system, we demonstrate the role of two viral ORFs, ORF18 and ORF30, in regulating viral gene expression during KSHV lytic replication. As the major route of KSHV transmission is thought to be via saliva, this new KSHV lytic replication system will have important utility in the field.

Functional Constraint Profiling of a Viral Protein Reveals Discordance of Evolutionary Conservation and Functionality

Viruses often encode proteins with multiple functions due to their compact genomes. Existing approaches to identify functional residues largely rely on sequence conservation analysis. Inferring functional residues from sequence conservation can produce false positives, in which the conserved residues are functionally silent, or false negatives, where functional residues are not identified since they are species-specific and therefore non-conserved. Furthermore, the tedious process of constructing and analyzing individual mutations limits the number of residues that can be examined in a single study. Here, we developed a systematic approach to identify the functional residues of a viral protein by coupling experimental fitness profiling with protein stability prediction using the influenza virus polymerase PA subunit as the target protein. We identified a significant number of functional residues that were influenza type-specific and were evolutionarily non-conserved among different influenza types. Our results indicate that type-specific functional residues are prevalent and may not otherwise be identified by sequence conservation analysis alone. More importantly, this technique can be adapted to any viral (and potentially non-viral) protein where structural information is available.

CryoEM and mutagenesis reveal that the smallest capsid protein cements and stabilizes Kaposi's sarcoma-associated herpesvirus capsid

Significance Kaposis sarcoma-associated herpesvirus (KSHV) and EBV are cancer-causing human herpesviruses. Their smallest capsid proteins (SCPs) were shown to be required for capsid assembly and are potential drug targets for curbing viral infections, but how they work is unclear. By cryoEM and genetic engineering, we determine the structures of KSHV capsids bearing full-length or truncated SCPs and localize regions of SCP that are important for capsid assembly. We show that a long kinked helix of SCP cross-links neighboring subunits of the major capsid protein of hexons to stabilize the capsid. Our results explain how SCP, acting like a cementing protein found in bacterial viruses, facilitates tumor herpesvirus capsid assembly and viral maturation. With just one eighth the size of the major capsid protein (MCP), the smallest capsid protein (SCP) of human tumor herpesviruses—Kaposis sarcoma-associated herpesvirus (KSHV) and Epstein-Barr virus (EBV)—is vital to capsid assembly, yet its mechanism of action is unknown. Here, by cryoEM of KSHV at 6-Å resolution, we show that SCP forms a crown on each hexon and uses a kinked helix to cross-link neighboring MCP subunits. SCP-null mutation decreased viral titer by 1,000 times and impaired but did not fully abolish capsid assembly, indicating an important but nonessential role of SCP. By truncating the C-terminal half of SCP and performing cryoEM reconstruction, we demonstrate that SCP’s N-terminal half is responsible for the observed structure and function whereas the C-terminal half is flexible and dispensable. Serial truncations further highlight the critical importance of the N-terminal 10 aa, and cryoEM reconstruction of the one with six residues truncated localizes the N terminus of SCP in the cryoEM density map and enables us to construct a pseudoatomic model of SCP. Fitting of this SCP model and a homology model for the MCP upper domain into the cryoEM map reveals that SCP binds MCP largely via hydrophobic interactions and the kinked helix of SCP bridges over neighboring MCPs to form noncovalent cross-links. These data support a mechanistic model that tumor herpesvirus SCP reinforces the capsid for genome packaging, thus acting as a cementing protein similar to those found in many bacteriophages.

ZAP inhibits murine gammaherpesvirus-68 ORF64 expression and is antagonized by RTA

ABSTRACT Zinc finger antiviral protein (ZAP) is an interferon-inducible host antiviral factor that specifically inhibits the replication of certain viruses, including HIV-1 and Ebola virus. ZAP functions as a dimer formed through intermolecular interactions of its N-terminal tails. ZAP binds directly to specific viral mRNAs and inhibits their expression by repressing translation and/or promoting degradation of the target mRNA. ZAP is not a universal antiviral factor, since some viruses grow normally in ZAP-expressing cells. It is not fully understood what determines whether a virus is susceptible to ZAP. We explored the interaction between ZAP and murine gammaherpesvirus 68 (MHV-68), whose life cycle has latent and lytic phases. We previously reported that ZAP inhibits the expression of M2, which is expressed mainly in the latent phase, and regulates MHV-68 latency in cultured cells. Here, we report that ZAP inhibits the expression of ORF64, a tegument protein that is expressed in the lytic phase and is essential for lytic replication. MHV-68 infection induced ZAP expression. However, ZAP did not inhibit lytic replication of MHV-68. We provide evidence showing that the antiviral activity of ZAP is antagonized by MHV-68 RTA, a critical viral transactivator expressed in the lytic phase. We further show that RTA inhibits the antiviral activity of ZAP by disrupting the N-terminal intermolecular interaction of ZAP. Our results provide an example of how a virus can escape ZAP-mediated immunity.

Genome-wide identification of interferon-sensitive mutations enables influenza vaccine design

Avoiding interferon avoidance Interferon (IFN) expression is a mammals first response to viral infection. Many viruses have thus evolved mechanisms to evade IFN. Du et al. developed a method to systematically ablate IFN evasion genes from live, attenuated influenza virus (see the Perspective by Teijaro and Burton). A combination of mutants was assembled to construct a virus that triggered transient IFN responses in mice but that was unable to replicate effectively. The transient IFN responses led to robust antibody and memory responses that protected against subsequent challenge with different influenza viruses. This approach could be adapted to improve other RNA virus vaccines. Science, this issue p. 290; see also p. 277 High-throughput genomics can be used to retune attenuated viruses to optimize vaccine development. In conventional attenuated viral vaccines, immunogenicity is often suboptimal. Here we present a systematic approach for vaccine development that eliminates interferon (IFN)–modulating functions genome-wide while maintaining virus replication fitness. We applied a quantitative high-throughput genomics system to influenza A virus that simultaneously measured the replication fitness and IFN sensitivity of mutations across the entire genome. By incorporating eight IFN-sensitive mutations, we generated a hyper–interferon-sensitive (HIS) virus as a vaccine candidate. HIS virus is highly attenuated in IFN-competent hosts but able to induce transient IFN responses, elicits robust humoral and cellular immune responses, and provides protection against homologous and heterologous viral challenges. Our approach, which attenuates the virus and promotes immune responses concurrently, is broadly applicable for vaccine development against other pathogens.

Replication and Transcription Activator (RTA) of Murine Gammaherpesvirus 68 Binds to an RTA-Responsive Element and Activates the Expression of ORF18

ABSTRACT The replication and transcription activator (RTA), mainly encoded by open reading frame 50, is an immediate-early gene product that is conserved among all characterized gammaherpesviruses. Previous studies have demonstrated that RTA proteins of Epstein-Barr virus (EBV) and Kaposis sarcoma-associated herpesvirus (KSHV) can activate the promoter of many viral early lytic genes through direct or indirect mechanisms. Murine gammaherpesvirus 68 (MHV-68) is genetically related to KSHV and EBV, and the RTA homologue from MHV-68 also initiates the lytic cycle of gene expression. Although two RTA-dependent promoters had been identified in MHV-68, the mechanism of the interaction between RTA and the promoters was not characterized. In this study, we first identified an RTA-responsive promoter in the left origin of lytic replication region of MHV-68 through a reporter assay and mapped a 27-bp RTA-responsive element (RRE) through systematic deletions. Interestingly, sequence analysis identified a second RRE in this region. An electrophoretic mobility shift assay (EMSA) and a chromatin immunoprecipitation (ChIP) assay showed that RTA can bind directly to these two RREs in vitro or in vivo. Mutagenesis studies have further characterized the nucleotides important for mediating RTA binding by an EMSA. Moreover, we engineered RRE-deleted viruses and demonstrated in the context of the viral genome that one of the RREs mediates the RTA-dependent activation of an essential lytic gene, ORF18, during de novo infection. To our knowledge, this is the first time that RTA binding sites in MHV-68 have been identified. Since ORF18 regulates viral late gene expression, our study has also contributed to the delineation of the expression cascade of gammaherpesvirus lytic genes.

Identification and functional characterization of the left origin of lytic replication of murine gammaherpesvirus 68.

Murine gammaherpesvirus 68 (MHV-68) replicates robustly in cell culture, providing a model for studying viral genome replication during de novo infection of tumor-associated herpesviruses. We have previously identified a 1.25-kb origin of lytic replication (oriLyt) for MHV-68. To further investigate the molecular mechanism of viral genome replication, we first fine-mapped essential cis-elements from this oriLyt fragment using a transposon-mediated high-density mutagenesis method. The result provided information for us to identify a second oriLyt located towards the left end of MHV-68 genome using a de novo infection-replication assay. We further characterized this left oriLyt by scanning deletion analysis and site-directed mutations, and showed that several CCAAT motifs are essential for oriLyt function, whereas an AT-rich region enhances replication. However, GC-rich repeats are not important cis-element. Moreover, we identified a cellular transcription factor, NF-Y, which binds to CCAAT boxes in EMSA and associates with oriLyt in ChIP assay. Using a dominant negative expression plasmid, we demonstrated that NF-Y plays an important role in mediating MHV-68 genome replication during de novo infection.

RIOK3 Is an Adaptor Protein Required for IRF3-Mediated Antiviral Type I Interferon Production

ABSTRACT Detection of cytosolic nucleic acids by pattern recognition receptors leads to the induction of type I interferons (IFNs) and elicits the innate immune response. We report here the identification of RIOK3 as a novel adaptor protein that is essential for the cytosolic nucleic acid-induced type I IFN production and for the antiviral response to gammaherpesvirus through two independent kinome-wide RNA interference screens. RIOK3 knockdown blocks both cytosolic double-stranded B-form DNA and double-stranded RNA-induced IRF3 activation and IFN-β production. In contrast, the overexpression of RIOK3 activates IRF3 and induces IFN-β. RIOK3 functions downstream of TBK1 and upstream of IRF3 activation. Furthermore, RIOK3 physically interacts with both IRF3 and TBK1 and is necessary for the interaction between TBK1 and IRF3. In addition, global transcriptome analysis shows that the expression of many gene involved antiviral responses is dependent on RIOK3. Thus, knockdown of RIOK3 inhibits cellular antiviral responses against both DNA and RNA viruses (herpesvirus and influenza A virus). Our data suggest that RIOK3 plays a critical role in the antiviral type I IFN pathway by bridging TBK1 and IRF3. IMPORTANCE The innate immune response, such as the production of type I interferons, acts as the first line of defense, limiting infectious pathogens directly and shaping the adaptive immune response. In this study, we identified RIOK3 as a novel regulator of the antiviral type I interferon pathway. Specifically, we found that RIOK3 physically interacts with TBK1 and IRF3 and bridges the functions between TBK1 and IRF3 in the activation of type I interferon pathway. The identification of a cellular kinase that plays a role the type I interferon pathway adds another level of complexity in the regulation of innate immunity and will have implications for developing novel strategies to combat viral infection.