Microbiology and Immunology Department Theses and Dissertations

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Browsing Microbiology and Immunology Department Theses and Dissertations by Author "Androphy, Elliot J."

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    Biological Functions of Intracellular Hepatitis B e Antigen
    (2019-09) Mitra, Bidisha; Guo, Haitao; Androphy, Elliot J.; Kaplan, Mark; Yu, Andy; Lu, Tao
    The function(s) of the intracellular form of HBeAg, previously reported as the preCore protein intermediate (p22) without the N-terminal signal peptide, remains elusive. Here, we propose to elucidate the translocation of p22 during its formation from endoplasmic reticulum (ER) to cytosol, how it differs from core in its inability to form a capsid and the biological functions of cytoplasmic and nuclear p22. Firstly, we have identified that a portion of p22, after the cleavage of its signal peptide in ER, is released back into the cytosol through an ERAD-independent mechanism, as neither wildtype nor dominant-negative p97 affected the ER-to-cytosol translocation of p22 or ER-Golgi secretion of HBeAg. Secondly, despite sharing the same sequence with core protein except for the extended 10 amino acid precore region at the N-terminus, we observed that p22 wildtype and C-7Q mutant are unable to form a capsid. Thirdly, we report that p22 but not the secreted HBeAg significantly reduced interferon stimulated response element (ISRE) activity and expression of interferon stimulated genes (ISGs) upon interferon-alpha (IFN- α) stimulation. Furthermore, in line with this, RNA-seq analysis of ISG induction profile from IFN-α treated patients showed that HBeAg(+) patients exhibited reduced and weak antiviral ISG upregulations compared to HBeAg(-) patients. Further, mechanistic study indicated that while p22 did not alter the total STAT1 or p-STAT1 levels in IFN-α treated cells, it blocked the nuclear translocation of p-STAT1 by interacting with karyopherin α1, indicating that the cytoplasmic p22 may impede JAK-STAT signaling to help the virus evade host innate immune response and cause resistance to IFN therapy in patients. Additionally, nuclear p22 and nuclear core were found to interact with the promoter regions (ISRE – containing) of ISGs, suggesting a new mechanism of inhibition of ISG expression upon stimulation. Finally, we found that the nuclear p22 can bind to cccDNA minichromosome and affects cccDNA maintenance and/or transcription. Thus, our results indicate that there is a novel ER sorting mechanism for the distribution of the intracellular and secretory HBeAg, and the intracellular HBeAg may contribute to HBV persistence by interfering with IFN-α elicited JAK-STAT signaling and regulating cccDNA metabolism.
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    Conserved Residues in Murine Papillomavirus E2 Regulate the Viral Life Cycle
    (2024-12) Gonzalez, Jessica Kay; Androphy, Elliot J.; Dong, X. Charlie; Katzenellenbogen, Rachel; Robinson, Christopher
    Papillomaviruses (PVs) are small, non-enveloped DNA viruses that infect the stratified epithelia. Once an infection is initiated, the virus must successfully navigate the three stages of its life cycle: establishment, maintenance, and vegetative amplification. A major mechanism of regulating this viral program is post-translational modification on the viral E2 protein, which is responsible for orchestrating viral transcription, replication, and genome partitioning. The hypothesis underscoring this work is that residues in E2 are highly conserved across PV types because they serve some structural or functional purpose for the virus. A targeted mutant library was generated in E2 from murine papillomavirus (MmuPV1) to investigate conserved residues that have been shown to be post-translationally modified in the E2 of other PVs, including BPV-1 and high-risk HPV-31. In the transactivation domain (TAD) tyrosine 102 and the lysine 112/113 motif were modified to their constitutively modified (phosphorylated and acetylated, respectively) or unmodified states, while cysteine 307 in the DNA binding and dimerization domain (DBD) was mutated to a less-reactive serine or DNA binding defective phenylalanine mutant. We characterized how mutation at each of these conserved sites alters E2 function using a battery of in vitro assays to assess for transcription and replication ability. We also studied how each mutant contributes to disease progression using an immunocompromised mouse model assessing cutaneous disease. We demonstrate that mutants which fail to replicate transiently in vitro will also fail to induce proliferative wart formation, establishing a predictive link between in vitro and in vivo experiments. Taken together, our findings suggest that modifications on conserved residues in E2 act as molecular switches that regulate E2 activity throughout the cellular and viral life cycle.
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    HPV replication regulation by acetylation of a conserved lysine in the E2 protein
    (2017-06-26) Thomas, Yanique Serge Gillana; Androphy, Elliot J.; Klemsz, Michael; Yu, Andy; Mayo, Lindsey; Lee, Suk-Hee
    Papillomaviruses (PVs) are non-enveloped DNA viruses that are the primary etiological agents of cervical and oropharyngeal cancers. Vaccines for H(human)PV have proven to be effective prophylactic treatments; however, there is no treatment available for those currently infected. To develop new therapies, we require a clear understanding of viral pathogenesis and regulation. The Papillomavirus E2 protein is a sequence specific DNA binding protein that recruits cellular factors to its genome in infected epithelial cells. E2 also binds to and loads the viral E1 DNA helicase at the origin of replication. Post-translational modifications of PV E2 have been identified as potential regulators of E2 functions. We recently reported lysine (K) 111 as a target of p300 acetylation in B(bovine)PV that is involved in the regulation of viral transcription. K111 is conserved in most papillomaviruses, so we pursued a mutational approach to query the functional significance of lysine in HPV E2. Amino acid substitutions that prevent acetylation, including arginine, were unable to stimulate transcription and E1 mediated DNA replication. The arginine K111 mutant retained E2 transcriptional repression, nuclear localization, DNA and chromatin binding, and association with E2 binding partners involved in PV transcription and replication. When directly investigating origin unwinding, the replication defective E2 K111R mutant recruited E1 to the viral replication origin, but surprisingly, unwinding of the duplex DNA did not occur. In contrast, the glutamine K111 mutant increased origin melting and stimulated replication compared to wild type E2. We have identified Topoisomerase I as a key host factor involved in viral replication whose recruitment is dependent on K111 acetylation, and propose a new model for viral origin dynamics during replication initiation. This work reveals a novel activity of E2 necessary for denaturing the viral origin that likely depends on acetylation of highly conserved lysine 111.
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    Proteomic Analysis of Nuclear HBV rcDNA Associated Proteins Identifies UV-DDB as a Host Factor Involved in cccDNA Formation
    (2022-01) Marchetti, Alexander Lloyd; Guo, Haitao; Yu, Andy; Androphy, Elliot J.; Robinson, Christopher
    Despite the lifecycle of the hepatitis B virus (HBV) being extensively investigated and described, there remains a significant gap in our knowledge of arguably one of the most crucial steps in the HBV lifecycle, the formation and maintenance of a covalently closed circular DNA (cccDNA) reservoir. Advancements in our understanding of host factors and pathways involved in cccDNA formation have been made through hypothesis driven studies and shRNA/siRNA screenings. We sought to create a targeted-unbiased assay to directly observe host factor-rcDNA interactions. This was achieved through an rcDNA Co-Immunoprecipitation paired Mass Spectrometry (rcDNA-CoIP/MS) assay. We created a DNA oligo complimentary to the open portion of the HBV rcDNA, labeled with biotin, to facilitate easy precipitation of nuclear rcDNA and complexed proteins. Proteins precipitated were analyzed through liquid chromatography paired mass spectrometry (LC/MS). Along with previously reported host factors, several factors of DNA damage repair pathways/complexes were also identified. A component of the UV-DDB complex, DDB1, surfaced as a hit. UV-DDB/rcDNA binding was confirmed through ChIP-qPCR. DDB2, the DNA damage binding component of the UV-DDB complex was knocked out in HepG2-NTCP and HepAD38 cells. This resulted in a significant decrease in the formation of cccDNA in DDB2 knockout cell lines following infection or induction. The subsequent reduction of downstream indicators of cccDNA formation such as viral RNA and proteins, HBcAg and HBeAg, showed a consistent decrease with cccDNA levels. Ectopic expression of DDB2 in the knockout cell lines rescued HBV phenotypes of cccDNA levels and its downstream indicators. Inactive mutant DDB2 plasmids were also transfected into the DDB2 K/O cell lines and failed to rescue cccDNA indicators. We therefore showed through a novel assay that we can discover novel viral rcDNA-host interactions, such as the UV-DDB complex recruiting DNA repair pathways to “repair” rcDNA to cccDNA.
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    Regulation of papillomavirus E2 protein by posttranslational modification
    (2015-04-24) Culleton, Sara Poirier; Androphy, Elliot J.; Klemsz, Michael; Mayo, Lindsey; Nakshatri, Harikrishna; Sullivan, William J., Jr.
    Papillomaviruses (PVs) are small, double-stranded DNA viruses. Hundreds of species have evolved to replicate in mammals, birds, and reptiles. Approximately two hundred species are estimated to infect humans alone, and these human papillomaviruses (HPVs) cause diseases ranging from benign warts to anogenital and oropharyngeal cancers. While vaccination is effective at preventing the majority of these infections and their disease outcomes, there are no successful treatments for existing infections; thus, exploration of novel therapeutic targets is warranted. PVs control expression and function of their gene products through alternative splicing, alternate start codons, and post-translational modification (PTM). The viral E2 protein regulates transcription, replication, and genome maintenance in infected cells, and PTMs have been demonstrated for E2 proteins from multiple papillomavirus types. Serine phosphorylation events were reported to influence E2 stability, and our laboratory was the first to describe in vitro acetylation events with implications for E2 transcription function. Here we report confirmation of these acetylation events in vivo and additional data elucidating the role of these PTMs in viral transcription. Moreover, we present a novel phosphorylation site for bovine papillomavirus type 1 (BPV-1) E2 at tyrosine 102 (Y102). Using phospho-deficient and phospho-mimetic point mutants, we found that this site influences E2-mediated transcription and replication, and we hypothesize that phosphorylation at Y102 regulates these activities by interrupting the association of E2 with its binding partners. We also report interaction of BPV-1 E2 and HPV-31 E2 with different receptor tyrosine kinases (TKs), most notably members of the fibroblast growth factor receptor family. We hypothesize that Y102 phosphorylation by these receptors occurs early in infection to limit viral replication and gene expression. Further studies will cement the role of RTKs in PV biology and could reveal novel therapeutic strategies.
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    Vaccina Virus Binding and Infection of Primary Human B Cells
    (2018-12) Shepherd, Nicole Elizabeth; Yu, Andy Qigui; Androphy, Elliot J.; Blum, Janice S.; Serezani, Henrique
    Vaccinia virus (VACV), the prototypical poxvirus, was used to eradicate smallpox worldwide and, in recent years, has received considerable attention as a vector for the development of vaccines against infectious diseases and oncolytic virus therapy. Studies have demonstrated that VACV exhibits an extremely strong bias for binding to and infection of primary human antigenpresenting cells (APCs) including monocytes, macrophages, and dendritic cells. However, very few studies have evaluated VACV binding to and infection of primary human B cells, a main type of professional APC. In this study, we evaluated the susceptibility of primary human peripheral B cells at different developmental stages to VACV binding, infection, and replication. We found that VACV exhibited strong binding but little entry into ex vivo B cells. Phenotypic analysis of B cells revealed that plasmablasts were the only subset resistant to VACV binding. Infection studies showed that plasma and mature-naïve B cells were resistant to VACV infection, while memory B cells were preferentially infected. Additionally, VACV infection was increased in larger and proliferative B cells suggesting a bias of VACV infection towards specific stages of differentiation and proliferative ability. VACV infection in B cells was abortive, and cessation of VACV infection was determined to occur at the stage of late viral gene expression. Interestingly, B cell function, measured by cytokine production, was not affected within 24 hours post-infection. In contrast to ex vivo B cells, stimulated B cells were permissive to productive VACV infection. These results demonstrate the value of B cells as a tool to aid in deciphering the intricacies of poxvirus infection in humans. Understanding VACV infection in primary human B cells at various stages of differentiation and maturation is important for the development of a safer smallpox vaccine and better vectors for vaccines against cancers and other infectious diseases.