Abstract
Human adenoviruses (HAdVs) induce significant reorganization of the nuclear environment, leading to the formation of virus-induced subnuclear structures known as replication compartments (RCs). Within these RCs, viral genome replication, gene expression, and modulation of cellular antiviral responses are tightly coordinated, making them valuable models for studying virus-host interactions. In a recent study, we analyzed the protein composition of HAdV type 5 (HAdV-C5) RCs isolated from infected primary cells at different time points during infection using quantitative proteomics. We identified several chromatin modifiers, including the high-mobility group box 1 protein (HMGB1) as components associated with RCs and demonstrated that HMGB1 can be relocalized to RCs from different HAdV species, thereby modulating viral replication in a species-specific manner. In the present work, using click-chemistry and proximity ligation assays, we discovered that HMGB1 localizes to sites of DNA replication within RCs and that its interaction with DBP in RCs is dependent on both DNA replication and RC assembly. HMGB1-knockdown experiments demonstrated that HMGB1 is required for efficient viral gene expression. However, despite its proviral role in viral replication, we found that HMGB1 levels decreased in late stages of infection due to transcriptional downregulation. Furthermore, by overexpressing HMGB1, we showed that this regulation of HMGB1 levels during infection is critical for optimal HAdV-C5 replication. These results highlight the complex regulatory relationship between HMGB1 and HAdV-C5 infection. IMPORTANCE: In an extensive proteomics analysis, we found that HMGB1, an important cellular chromatin protein, was enriched in adenovirus replication compartments. In this study, we aimed to better understand the role of HMGB1 in the infection process of a human DNA virus, HAdV-C5. We tested different virus types, including some with specific gene deletions and mutations. Our results showed that during infection, HMGB1 levels decreased because the virus suppressed its production. Despite this, even at lower levels, HMGB1 still helped the virus replicate by interacting with key viral proteins and DNA at sites where the virus is actively replicating. Overall, our findings highlight how HMGB1 plays a crucial role in facilitating efficient virus replication, making it an important factor in the infection process.