Investigating viral subversion of intercellular communication
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Adenoviruses are non-enveloped, dsDNA tumor viruses responsible for a breadth of pathogenesis including acute respiratory disease and viral myocarditis. Gap junctions, which are formed by connexin proteins, directly couple the cytoplasms of apposed cells enabling immunological, metabolic, and electrical intercellular communication. The gap junction protein connexin43 (Cx43; gene name – GJA1) is the most widely expressed human connexin protein and is the predominant connexin in the working myocardium. Given the immunological role for Cx43 gap junctions, we hypothesized that gap junctions would be targeted during adenoviral infection. We find reduced Cx43 protein due to suppression of GJA1 transcription dependent upon β-catenin during adenoviral infection, with viral protein E4orf1 sufficient to induce β-catenin phosphorylation. Loss of gap junction function occurs prior to reduced Cx43 protein levels with Ad5 infection rapidly inducing Cx43 phosphorylation at residues previously demonstrated to alter gap junction conductance. Direct Cx43 interaction with ZO-1 plays a critical role in gap junction regulation. We find loss of Cx43/ZO-1 complexing during Ad5 infection by co-immunoprecipitation, with complementary studies in human induced pluripotent stem cell derived-cardiomyocytes revealing Cx43 gap junction remodeling concomitant with reduced ZO-1 complexing. These findings demonstrate specific targeting of gap junction function by Ad5 leading to disruptions in intercellular communication which would contribute to dangerous pathological states including arrhythmias in infected hearts.
Intercellular junction proteins belonging to classically defined unique junctions exhibit extensive cross-talk and interdependency for expression and localization. We find reduced connexin43 (Cx43) phosphorylation at a known internalization motif, leading us to hypothesize that gap junctions are maintained during adenoviral infection in order to stabilize intercellular junctions and adenoviral receptors therein. Utilizing immunofluorescence confocal microscopy, we demonstrate that Cx43 reductions are primarily cytosolic with Cx43 preservation at the plasma membrane. Click-IT chemistry, a non-radioactive pulse-chase technique, reveals that Cx43 ½ life is extended during adenoviral infection. In order to test if remaining Cx43 exists in de facto gap junctions (i.e. not undocked or cytosolic connexons) we utilized 1 % Triton X-100 solubility fractionation and find Cx43 is indeed primarily junctional during adenoviral infection. Having demonstrated increases in junctional Cx43, we next asked how tightly coupled cells were during adenoviral infection and by ECIS measurements of electrical resistance we demonstrate a transient increase in mechanical coupling during infection. Our future aims are to uncover changes in Coxsackievirus and adenovirus receptor (CAR) protein localization to determine if adenoviral-induced changes to subcellular architecture predisposes neighboring cells to infection and enhances viral spread. These findings will add to the existing model of adenoviral infection and more broadly, contribute to the therapeutic design of adenoviral vectors for cancer and gene therapy.