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Investigation of viral and host determinants of gammaherpesvirus pathogenesis

$1,269,469ZIAFY2021CANIH

Division Of Basic Sciences - Nci

Investigators

Linked publications, trials & patents

Abstract

(1) STAT3 activation is associated with gammaherpesvirus latency and cancer in cell culture systems, but the target genes that drive latency, proliferation and transformation are not well-defined. As a prelude to studying the effects of STAT3 activation in KSHV itself, we used transgenic mice with a B cell-specific knock-out of STAT3 to determine that STAT3 signaling is critical for the establishment of gammaherpesvirus latency in primary B cells of the host. We also determined that the viral lytic gene transactivator RTA interacts with STAT3 in a cytokine-dependent manner. Our central hypothesis is that gammaherpesviruses require STAT3 to promote B cell latency. To define the STAT3-dependent gene expression program of infected B cells, we are performing RNAseq to compare the gene expression profile in infected cells with and without STAT3. We will merge differentially expressed genes from all available gammaherpesvirus datasets to identify and prioritize common STAT3-regulated pathways and target genes. These will lead to further investigations of latency, reactivation, and transformation in KSHV and murine cell culture systems using conditional knock-out approaches. (2) The numerous herpesvirus genes involved in nucleotide metabolism indicate that the nucleotide pool is a major restriction point in non-dividing cells. We recently reported that the enzymatic properties of the viral uracil DNA glycosylase (UNG) synergize with the viral nucleotide metabolism protein dUTPase to promote pathogenesis and counter recombination-based deletions in the viral genome. Our central hypothesis is that the viral UNG coordinates with the viral DNA polymerase to promote processivity of viral DNA synthesis and genome stability by protecting newly synthesized DNA from host UNG and DNA repair factors. We have generated multiple viral UNG mutants in the mouse system to examine their impact on viral DNA replication and genome stability and the interactions of the vUNG with other viral replication factors and host DNA repair factors. These mutants will inform the design of KSHV recombinant viruses and small molecule inhibitors of thymidine synthesis to test for the impact of uracil incorporation on reactivation from latency. The induction of a DNA damage response and block in viral DNA replication might provide a novel target to cripple KSHV reactivation and prevent AIDS malignancies. (2) Also, in collaboration with the McBride lab, we analyzed the immunoglobulin repertoire of infected and uninfected B cells from infected mice using next generation sequencing. This analysis revealed that gamamherpesvirus-infected cells undergo clonal expansion yet only a few clones were shared between the infected and uninfected germinal center B cells. There is also evidence for receptor editing and clear bias for specific IghV genes in the infected B cells. These novel data indicate the gammaherpesviruses occupy a distinct niche in the infected host and takes an active role in subverting the immunoglobulin repertoire in the B cells that it infects. This supports the existence of a critical strategy that is shared with KSHV and EBV, namely that these viruses bypass normal selection processes, placing the B cells at risk for genetic instability and for producing immunoglobulins with pathologic potential. (4) I am analyzing the host immune response in the peripheral blood mononuclear cells of patients in HAMB clinical trials. We are using flow cytometry to examine if the innate and adaptive immune response differs between HIV+ and HIV- patients. We also study if the immune response changes with the chemotherapies and immunotherapies that are used to treat these patients in the clinical trials. The goal is to identify immune correlates of the clinical response for non-responders and responders to find effective therapies for AIDS associated malignancies. I am also collaborating with other NCI investigators and clinicians in HAMB to analyze the B cell repertoire of KSHV-infected cells in HIV-associated primary effusion lymphoma and lymph node material of HIV-infected KSHV-multicentric Castleman disease patients enrolled in HAMB clinical trials. This will enable us to examine the clonality and source of the B cell transformation. Importantly, this might inform the possible etiology of these diseases which often occur in a concurrent or sequential manner in people living with HIV. (5) With regard to the development of direct animal models of Kaposi sarcoma, a hallmark tumor of AIDS, I am collaborating with clinicians in the HIV and AIDS Malignancy Branch and in the Center for Advanced Preclinical Research (CAPR) of NCI Frederick in more translational projects towards the establishment of a patient-derived xenograft model. KS biopsy material from HIV infected patients in the HAMB clinical cohorts is being implanted into immunodeficient animals. Cell lines derived from this system that maintain KSHV infection and drive tumors in mice will be a tremendous advancement for the field since there is no way to maintain KSHV+ endothelial cells upon explant and there is no pre-clinical animal model of Kaposi sarcoma to screen for effective drug interventions.

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