Type-1 interferon (IFN)-mediated responses are a crucial first line of defense against viral infections and are critical for generating both innate and adaptive immunity. Therefore, viruses have necessarily evolved mechanisms to impede the IFN response. HSV-2 was found to completely abolish type-1 IFN-mediated signaling via multiple STAT2-associated mechanisms. Although the extent and kinetics of this inactivation were indistinguishable between the various cell-lines examined, there were distinct differences in the mechanisms HSV-2 employed to subvert IFN-signaling amongst the cell-lines. These mechanistic differences could be segregated into two categories dependent on the phase of the HSV replicative cycle that was responsible for this inhibition: 1) early phase-inhibited cells which exhibited abrogation of IFN-signaling prior to viral DNA replication; 2) late phase-inhibited cells where early phase inhibition mechanisms were not functional, but viral functions expressed following DNA replication compensated for their ineffectiveness. In early phase-inhibited cells, HSV-2 infection targeted STAT2 protein for proteosomal degradation and prevented de novo expression of STAT2 by degrading its mRNA. In contrast, HSV-2 infected late phase-inhibited cells exhibited no apparent changes in STAT2 transcript or protein levels. However, in these cells STAT2 was not activated by phosphorylation and failed to translocate to the cell nucleus, thereby preventing transactivation of antiviral genes. In primary human fibroblasts, HSV-2 failed to fully degrade STAT2 and therefore, both early and late phase mechanisms functioned cooperatively to subvert IFN-mediated antiviral gene expression. Taken together, these results indicate the importance that HSV-2 has assigned to STAT2, investing significant genomic currency throughout its replicative lifecycle for continuous targeted destruction and inhibition of this protein.
Generation and isolation of recombinant herpesviruses by traditional homologous recombination methods can be a tedious, time consuming process. Therefore, a novel stoplight recombination selection method was developed that facilitated rapid identification and purification of recombinant viruses expressing fusions of immunological epitopes with EGFP. This “traffic-light” approach provided a visual indication of the presence and purity of recombinant HSV-1 isolates by producing three identifying signals: 1) red fluorescence indicates non-recombinant viruses that should be avoided; 2) yellow fluorescence indicates cells co-infected with non-recombinant and recombinant viruses that are chosen with caution; 3) green fluorescence indicates pure recombinant isolates and to proceed with preparation of viral stocks. Adaptability of this system was demonstrated by creating three recombinant viruses that expressed model immunological epitopes. Diagnostic PCR established that the fluorescent stoplight indicators were effective at differentiating between the presence of background virus contamination and pure recombinant viruses specifying immunological epitopes. This enabled isolation of pure recombinant viral stocks that exhibited wildtype-like viral replication and cell-to-cell spread following three rounds of plaque purification. Expression of specific immunological epitopes was confirmed by western analysis, and the utility of these viruses for examining host immune responses to HSV-1 was determined by a functional T cell assay.
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