Summary
The ongoing epidemic of Zika virus (ZIKV) illustrates the importance of flaviviruses as emerging human pathogens. All vector-borne flaviviruses studied thus far have to overcome type I interferon (IFN) to replicate and cause disease in vertebrates. The mechanism(s) by which ZIKV antagonizes IFN signaling is unknown. Here, we report that the nonstructural protein NS5 of ZIKV and other flaviviruses examined could suppress IFN signaling, but through different mechanisms. ZIKV NS5 expression resulted in proteasomal degradation of the IFN-regulated transcriptional activator STAT2 from humans but not mice, which may explain the requirement for IFN-deficiency to observe ZIKV-induced disease in mice. The mechanism of ZIKV NS5 resembles dengue virus (DENV) NS5 and not its closer relative, Spondweni virus (SPOV). However, unlike DENV, ZIKV did not require the E3 ubiquitin ligase UBR4 to induce STAT2 degradation. Hence, flavivirus NS5 proteins exhibit a remarkable functional convergence in IFN antagonism, albeit by virus-specific mechanisms.
c RNA interference (RNAi) is an important antiviral defense response in plants and invertebrates; however, evidences for its contribution to mammalian antiviral defense are few. In the present study, we demonstrate the anti-dengue virus role of RNAi in mammalian cells. Dengue virus infection of Huh 7 cells decreased the mRNA levels of host RNAi factors, namely, Dicer, Drosha, Ago1, and Ago2, and in corollary, silencing of these genes in virus-infected cells enhanced dengue virus replication. In addition, we observed downregulation of many known human microRNAs (miRNAs) in response to viral infection. Using reversion-ofsilencing assays, we further showed that NS4B of all four dengue virus serotypes is a potent RNAi suppressor. We generated a series of deletion mutants and demonstrated that NS4B mediates RNAi suppression via its middle and C-terminal domains, namely, transmembrane domain 3 (TMD3) and TMD5. Importantly, the NS4B N-terminal region, including the signal sequence 2K, which has been implicated in interferon (IFN)-antagonistic properties, was not involved in mediating RNAi suppressor activity. Site-directed mutagenesis of conserved residues revealed that a Phe-to-Ala (F112A) mutation in the TMD3 region resulted in a significant reduction of the RNAi suppression activity. The green fluorescent protein (GFP)-small interfering RNA (siRNA) biogenesis of the GFP-silenced line was considerably reduced by wild-type NS4B, while the F112A mutant abrogated this reduction. These results were further confirmed by in vitro dicer assays. Together, our results suggest the involvement of miRNA/ RNAi pathways in dengue virus establishment and that dengue virus NS4B protein plays an important role in the modulation of the host RNAi/miRNA pathway to favor dengue virus replication.
RNA silencing suppressors (RSSs) are well studied for plant viruses but are not well defined to date for animal viruses. Here, we have identified an RSS from a medically important positive-sense mammalian virus, Severe acute respiratory syndrome coronavirus. The viral 7a accessory protein suppressed both transgene and virus-induced gene silencing by reducing the levels of small interfering RNA (siRNA). The suppression of silencing was analyzed by two independent assays, and the middle region (amino acids [aa] 32 to 89) of 7a was responsible for suppression. Finally, the RNA suppression property and the enhancement of heterologous replicon activity by the 7a protein were confirmed for animal cell lines.
SUMMARY
The unprecedented 2013–16 outbreak of Ebola virus (EBOV) resulted in over 11,300 human deaths. Host resistance to RNA viruses requires RIG-I-like receptor (RLR) signaling through the adaptor protein, mitochondrial antiviral signaling (MAVS), but the role of RLR-MAVS in orchestrating anti-EBOV responses in vivo is not known. Here, we apply a systems approach to MAVS−/− mice infected with either wild-type or mouse-adapted EBOV. MAVS controlled EBOV replication through expression of IFNα, regulation of inflammatory responses in the spleen, and prevention of cell death in the liver, with macrophages implicated as a major cell-type influencing host resistance. A dominant role for RLR signaling in macrophages was confirmed following conditional MAVS deletion in LysM+ myeloid cells. These findings reveal tissue-specific MAVS-dependent transcriptional pathways associated with resistance to EBOV, and demonstrate that EBOV adaptation to cause disease in mice involves changes in two distinct events, RLR-MAVS antagonism and suppression of RLR-independent IFN-I responses.
RNAi acts as a host immune response against non-self molecules, including viruses. Viruses evolved to neutralize this response by expressing suppressor proteins. In the present study, we investigated dengue virus non structural protein 3 (dvNS3), for its RNAi-suppressor activity in human cell lines. Dengue virus (DV) NS3 reverts the GFP expression in GFP-silenced cell lines. Pull-down assays of dvNS3 revealed that it interacts with the host factor human heat shock cognate 70 (hHSC70). Down-regulation of hHSC70 resulted in accumulation of dengue viral genomic RNA. Also, the interaction of dvNS3 with hHSC70 perturbs the formation of RISC (RNA-induced silencing complex)-loading complex (RLC), by displacing TRBP (TAR RNA-binding protein) and possibly impairing the downstream activity of miRNAs. Interestingly, some of these miRNAs have earlier been reported to be down-regulated upon DV infection in Huh7 cells. Further studies on the miRNA-mRNA relationship along with mRNA profiling of samples overexpressing dvNS3 revealed up-regulation of TAZ (tafazzin) and SYNGR1 (synaptogyrin 1), known dengue viral host factors (DVHFs). Importantly, overexpression of dvNS3 in human embryonic kidney (HEK) 293T cells resulted in modulation of both mature and precursor miRNAs in human cell lines. Subsequent analysis suggested that dvNS3 induced stage-specific down-regulation of miRNAs. Taken together, these results suggest that dvNS3 affects biogenesis and function of host miRNAs to regulate DVHFs for favouring DV replication.
Highlights d Zika virus antagonizes mitophagy by inhibiting Ajuba translocation to mitochondria d Viral suppression of mitophagy amplifies proinflammatory chemokine expression d Chemokine expression is dependent on PKR sensing of mitochondrial dsRNA d Suppressed mitophagy amplifies early chemokines and viral tissue burden in vivo
HIV-1 relies heavily on the host cellular machinery for its replication. During infection, HIV-1 is known to modulate the host-cell miRNA profile. One of the miRNAs, miR-34a, is up-regulated by HIV-1 in T-cells as suggested by miRNA microarray studies. However, the functional consequences and the mechanism behind this phenomenon were not explored. The present study shows that HIV-1 enhances miR-34a in a time-dependent manner in T-cells. Our overexpression and knockdown-based experimental results suggest that miR-34a promotes HIV-1 replication in T-cells. Hence, there is a positive feedback loop between miR-34a and HIV-1 replication. We show that the mechanism of action of miR-34a in HIV-1 replication involves a cellular protein, the phosphatase 1 nuclear-targeting subunit (PNUTS). PNUTS expression levels decrease with the progression of HIV-1 infection in T-cells. Also, the overexpression of PNUTS potently inhibits HIV-1 replication in a dose-dependent manner. We report for the first time that PNUTS negatively regulates HIV-1 transcription by inhibiting the assembly of core components of the transcription elongation factor P-TEFb, i.e. cyclin T1 and CDK9. Thus, HIV-1 increases miR-34a expression in cells to overcome the inhibitory effect of PNUTS on HIV-1 transcription. So, the present study provides new mechanistic details with regard to our understanding of a complex interplay between miR-34a and the HIV-1 transcription machinery involving PNUTS.
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