Melody M. H. Li

Antiretroelement Activity of APOBEC3H Was Lost Twice in Recent Human Evolution

The primate APOBEC3 gene locus encodes a family of proteins (APOBEC3A-H) with various antiviral and antiretroelement activities. Here, we trace the evolution of APOBEC3H activity in hominoids to identify a human-specific loss of APOBEC3H antiviral activity. Reconstruction of the predicted ancestral human APOBEC3H protein shows that human ancestors encoded a stable form of this protein with potent antiviral activity. Subsequently, the antiviral activity of APOBEC3H was lost via two polymorphisms that are each independently sufficient to destabilize the protein. Nonetheless, an APOBEC3H allele that encodes a stably expressed protein is still maintained at high frequency, primarily in African populations. This stable APOBEC3H protein has potent activity against retroviruses and retrotransposons, including HIV and LINE-1 elements. The surprising finding that APOBEC3H antiviral activity has been lost in the majority of humans may have important consequences for our susceptibility to retroviral infections as well as ongoing retroelement proliferation in the human genome.

The Range of Human APOBEC3H Sensitivity to Lentiviral Vif Proteins

ABSTRACT The APOBEC3H gene is polymorphic in humans, with four major population-dependent haplotypes that encode proteins with different levels of antiviral activity. Haplotype II, present most frequently in African populations, encodes the most stable protein and is most active against human immunodeficiency virus type 1 (HIV-1). In contrast to human APOBEC3G, which can be completely counteracted by HIV-1 Vif, the protein encoded by APOBEC3H haplotype II is only partially sensitive to Vif, while the protein encoded by APOBEC3H haplotype I is completely resistant to HIV-1 Vif. We mapped a residue on APOBEC3H that determines this partial Vif sensitivity. However, it is unclear how HIV-1 can replicate in vivo without the ability to neutralize APOBEC3H antiviral activity. In order to directly address this question, we cloned vif genes from HIV-1-infected individuals with different APOBEC3H genotypes and tested them for their ability to inhibit human APOBEC3H. We found that while the APOBEC3H genotype of infected individuals significantly influences the activity of Vif encoded by their virus, none of the Vif variants tested can completely neutralize APOBEC3H as well as they neutralize APOBEC3G. Consistent with this genetic result, APOBEC3H protein expression in human peripheral blood mononuclear cells was below our limit of detection using newly developed antibodies against the endogenous protein. These results demonstrate that human APOBEC3H is not as strong of a selective force for current HIV-1 infections as human APOBEC3G.

Prenylome profiling reveals S-farnesylation is crucial for membrane targeting and antiviral activity of ZAP long-isoform

S-prenylation is an important lipid modification that targets proteins to membranes for cell signaling and vesicle trafficking in eukaryotes. As S-prenylated proteins are often key effectors for oncogenesis, congenital disorders, and microbial pathogenesis, robust proteomic methods are still needed to biochemically characterize these lipidated proteins in specific cell types and disease states. Here, we report that bioorthogonal proteomics of macrophages with an improved alkyne-isoprenoid chemical reporter enables large-scale profiling of prenylated proteins, as well as the discovery of unannotated lipidated proteins such as isoform-specific S-farnesylation of zinc-finger antiviral protein (ZAP). Notably, S-farnesylation was crucial for targeting the long-isoform of ZAP (ZAPL/PARP-13.1/zc3hav1) to endolysosomes and enhancing the antiviral activity of this immune effector. These studies demonstrate the utility of isoprenoid chemical reporters for proteomic analysis of prenylated proteins and reveal a role for protein prenylation in host defense against viral infections.

Multiple interferon stimulated genes synergize with the zinc finger antiviral protein to mediate anti-alphavirus activity

The zinc finger antiviral protein (ZAP) is a host factor that mediates inhibition of viruses in the Filoviridae, Retroviridae and Togaviridae families. We previously demonstrated that ZAP blocks replication of Sindbis virus (SINV), the prototype Alphavirus in the Togaviridae family at an early step prior to translation of the incoming genome and that synergy between ZAP and one or more interferon stimulated genes (ISGs) resulted in maximal inhibitory activity. The present study aimed to identify those ISGs that synergize with ZAP to mediate Alphavirus inhibition. Using a library of lentiviruses individually expressing more than 350 ISGs, we screened for inhibitory activity in interferon defective cells with or without ZAP overexpression. Confirmatory tests of the 23 ISGs demonstrating the largest infection reduction in combination with ZAP revealed that 16 were synergistic. Confirmatory tests of all potentially synergistic ISGs revealed 15 additional ISGs with a statistically significant synergistic effect in combination with ZAP. These 31 ISGs are candidates for further mechanistic studies. The number and diversity of the identified ZAP-synergistic ISGs lead us to speculate that ZAP may play an important role in priming the cell for optimal ISG function.

Polymorphism in Human APOBEC3H Affects a Phenotype Dominant for Subcellular Localization and Antiviral Activity

ABSTRACT The APOBEC3 family of cytidine deaminases is part of the innate host defense targeted toward retroviruses and retroelements. APOBEC3H is the most distantly related member of the family and carries functional polymorphisms in current human populations. Haplotype II of APOBEC3H, which is more commonly found in individuals of African descent, encodes a protein with the highest antiviral activity in cells, whereas the other haplotypes encode proteins with weak or no antiviral activity. Here, we show that the different human APOBEC3H haplotypes exhibit differential subcellular localizations, as the haplotype I protein is mostly found in the nucleus and the haplotype II protein is mostly localized to the cytoplasm. The determinant responsible for this phenotype maps to a single amino acid that is also important for APOBEC3H protein stability. Furthermore, we show that the cytoplasmic localization is dominant over nuclear localization, by using fusion proteins of APOBEC3H. Our data support a model in which the APOBEC3H protein encoded by haplotype II is actively retained in the cytoplasm by interacting with specific host factors, whereas the less active protein encoded by haplotype I is allowed to enter the nucleus by a passive mechanism. Together, cytoplasmic localization and its link with protein stability correlate with the ability of APOBEC3H to inhibit HIV replication, providing a mechanistic basis for the differential antiviral activities of different APOBEC3H haplotypes.

To translate, or not to translate: viral and host mRNA regulation by interferon-stimulated genes

Type I interferon (IFN) is one of the first lines of cellular defense against viral pathogens. As a result of IFN signaling, a wide array of IFN-stimulated gene (ISG) products is upregulated to target different stages of the viral life cycle. We review recent findings implicating a subset of ISGs in translational regulation of viral and host mRNAs. Translation inhibition is mediated either by binding to viral RNA or by disrupting physiological interactions or levels of the translation complex components. In addition, many of these ISGs localize to translationally silent cytoplasmic granules, such as stress granules and processing bodies, and intersect with the microRNA (miRNA)-mediated silencing pathway to regulate translation of cellular mRNAs.

TRIM25 Enhances the Antiviral Action of Zinc-Finger Antiviral Protein (ZAP)

The host factor and interferon (IFN)-stimulated gene (ISG) product, zinc-finger antiviral protein (ZAP), inhibits a number of diverse viruses by usurping and intersecting with multiple cellular pathways. To elucidate its antiviral mechanism, we perform a loss-of-function genome-wide RNAi screen to identify cellular cofactors required for ZAP antiviral activity against the prototype alphavirus, Sindbis virus (SINV). In order to exclude off-target effects, we carry out stringent confirmatory assays to verify the top hits. Important ZAP-liaising partners identified include proteins involved in membrane ion permeability, type I IFN signaling, and post-translational protein modification. The factor contributing most to the antiviral function of ZAP is TRIM25, an E3 ubiquitin and ISG15 ligase. We demonstrate here that TRIM25 interacts with ZAP through the SPRY domain, and TRIM25 mutants lacking the RING or coiled coil domain fail to stimulate ZAP’s antiviral activity, suggesting that both TRIM25 ligase activity and its ability to form oligomers are critical for its cofactor function. TRIM25 increases the modification of both the short and long ZAP isoforms by K48- and K63-linked polyubiquitin, although ubiquitination of ZAP does not directly affect its antiviral activity. However, TRIM25 is critical for ZAP’s ability to inhibit translation of the incoming SINV genome. Taken together, these data uncover TRIM25 as a bona fide ZAP cofactor that leads to increased ZAP modification enhancing its translational inhibition activity.

Interferon regulatory factor 2 protects mice from lethal viral neuroinvasion.

Li et al. describe a novel role for IRF2, previously known as a negative regulator of type I IFN signaling, in protection of mice from lethal viral neuroinvasion by facilitating the proper localization of B cells and antibodies to the central nervous system.

Sindbis virus can exploit a host antiviral protein to evade immune surveillance

ABSTRACT Viral infection induces production of type I interferons (IFNs), which stimulate the expression of a variety of antiviral factors to inhibit viral replication. To establish effective infection, viruses need to develop strategies to evade the immune responses. A neurovirulent Sindbis virus strain with neuroinvasive properties (SVNI) causes lethal encephalitis in mice, and its replication in cultured cells is inhibited by the zinc finger antiviral protein (ZAP), a host factor that specifically inhibits the replication of certain viruses by binding to the viral mRNAs, repressing the translation of target mRNA, and promoting the degradation of target mRNA. We report here that murine embryonic fibroblast cells from ZAP knockout mice supported more efficient SVNI replication than wild-type cells. SVNI infection of 10-day-old suckling mice led to reduced survival in the knockout mice. Unexpectedly, however, SVNI infection of 23-day-old weanling mice, whose immune system is more developed than that of the suckling mice, resulted in significantly improved survival in ZAP knockout mice. Further analyses revealed that in the weanling knockout mice, SVNI replicated more efficiently in lymphoid tissues at early times postinfection and induced higher levels of IFN production, which restricted viral spread to the central nervous system. Blocking IFN activity through the use of receptor-neutralizing antibodies rendered knockout mice more sensitive to SVNI infection than wild-type mice. These results uncover a mechanism by which SVNI exploits a host antiviral factor to evade innate immune surveillance. IMPORTANCE Sindbis virus, a prototypic member of the Alphavirus genus, has been used to study the pathogenesis of acute viral encephalitis in mice for many years. How the virus evades immune surveillance to establish effective infection is largely unknown. ZAP is a host antiviral factor that potently inhibits Sindbis virus replication in cell culture. We show here that infection of ZAP knockout suckling mice with an SVNI led to faster disease progression. However, SVNI infection of weanling mice led to slower disease progression in knockout mice. Further analyses revealed that in weanling knockout mice, SVNI replicated more efficiently in lymphoid tissues at early times postinfection and induced higher levels of interferon production, which restricted viral spread to the central nervous system. These results uncover a mechanism by which SVNI exploits a host antiviral factor to evade innate immune surveillance and allow enhanced neuroinvasion.

Chaperone-Assisted Protein Folding Is Critical for Yellow Fever Virus NS3/4A Cleavage and Replication

ABSTRACT DNAJC14, a heat shock protein 40 (Hsp40) cochaperone, assists with Hsp70-mediated protein folding. Overexpressed DNAJC14 is targeted to sites of yellow fever virus (YFV) replication complex (RC) formation, where it interacts with viral nonstructural (NS) proteins and inhibits viral RNA replication. How RCs are assembled and the roles of chaperones in this coordinated process are largely unknown. We hypothesized that chaperones are diverted from their normal cellular protein quality control function to play similar roles during viral infection. Here, we show that DNAJC14 overexpression affects YFV polyprotein processing and alters RC assembly. We monitored YFV NS2A-5 polyprotein processing by the viral NS2B-3 protease in DNAJC14-overexpressing cells. Notably, DNAJC14 mutants that did not inhibit YFV replication had minimal effects on polyprotein processing, while overexpressed wild-type DNAJC14 affected the NS3/4A and NS4A/2K cleavage sites, resulting in altered NS3-to-NS3-4A ratios. This suggests that DNAJC14s folding activity normally modulates NS3/4A/2K cleavage events to liberate appropriate levels of NS3 and NS4A and promote RC formation. We introduced amino acid substitutions at the NS3/4A site to alter the levels of the NS3 and NS4A products and examined their effects on YFV replication. Residues with reduced cleavage efficiency did not support viral RNA replication, and only revertant viruses with a restored wild-type arginine or lysine residue at the NS3/4A site were obtained. We conclude that DNAJC14 inhibition of RC formation upon DNAJC14 overexpression is likely due to chaperone dysregulation and that YFV probably utilizes DNAJC14s cochaperone function to modulate processing at the NS3/4A site as a mechanism ensuring virus replication. IMPORTANCE Flaviviruses are single-stranded RNA viruses that cause a wide range of illnesses. Upon host cell entry, the viral genome is translated on endoplasmic reticulum (ER) membranes to produce a single polyprotein, which is cleaved by host and viral proteases to generate viral proteins required for genome replication and virion production. Several studies suggest a role for molecular chaperones during these processes. While the details of chaperone roles have been elusive, in this report we show that overexpression of the ER-resident cochaperone DNAJC14 affects YFV polyprotein processing at the NS3/4A site. This work reveals that DNAJC14 modulation of NS3/4A site processing is an important mechanism to ensure virus replication. Our work highlights the importance of finely regulating flavivirus polyprotein processing. In addition, it suggests future studies to address similarities and/or differences among flaviviruses and to interrogate the precise mechanisms employed for polyprotein processing, a critical step that can ultimately be targeted for novel drug development.