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Human cytomegalovirus (HCMV) exploits heat-shock transcription factor 1 (HSF1) to promote viral replication: a potential novel antiviral target to combat HCMV infection
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Chan, Gary
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Summer 2024
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2024
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Human cytomegalovirus (HCMV) is a highly prevalent beta-Herpesviridae virus infecting almost 80-90 % of the world population. Though HCMV infection is typically asymptomatic, it can cause significant morbidity and mortality among immunocompromised individuals. Because of its obligate intracellular nature, HCMV modulates the cellular environment to promote infection. HCMV activates different cellular responses and signaling pathways to facilitate a favorable state for viral replication. During the lytic cycle of HCMV infection, viral entry, and replication inside the cell initiate stress response due to nutrient deficiency, energy depletion, hypoxia, and proteotoxic stress. Stress responses are designed to sense the damage, initiating a cascade of events to survive the stress. Several studies showed that HCMV usurps components of heat shock-stress response (HSR) to mitigate stress-associated damage and promote viral gene expression and replication. In this study, we found that HCMV infection in fibroblast cells induces a unique biphasic activation of heat shock transcription factor 1 (HSF1), a master transcription factor that is activated in response to heat-induced proteotoxic stress. HCMV binding to the integrin-ᵝ receptor activates HSF1 through Src- kinases. Importantly, HCMV infection drives the translocation of HSF1 into the infected cell nucleus. During canonical activation of HSF1, nuclear HSF1 binds to the specific sequence on the genome called heat shock element (HSE) and initiates transcription of a wide variety of stress-related genes. Interestingly, HCMV also utilizes this master transcription factor by harboring HSEs on major immediate early promoter (MIEP) to regulate viral immediate early (IE) gene expression. We found inhibition of HSF1 with a novel anti-HSF1 targeting drug SISU102 (Direct Targeted HSF1 InhiBitor) attenuated IE protein expression, indicating that the HSF1 regulates HCMV lytic replication. Additionally, inhibition of HSF1 reduced late (L) gene expression and subsequent viral progeny production. To explore HSF1 as a potential in vivo anti-HCMV target, we employed a murine model involving the subcutaneous transplantation of human skin into athymic nude mice. Treatment with SISU102 significantly diminishes viral replication in skin xenografts compared to the vehicle-treated group, indicating HSF1 as a possible cellular protein target for HCMV antiviral therapy. Overall, our data suggest that HCMV infection rapidly activates HSF1 during viral binding and entry, driving nuclear localization to promote lytic replication, which can be exploited as an antiviral strategy.