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2. Hemin treatment drives viral reactivation and plasma cell differentiation of EBV latently infected B cells.

Author

Burnet, Anna M., Brunetti, Tonya, and Rochford, Rosemary

Subjects
*PLASMA cells, *B cells, *VIRUS reactivation, *HEMIN, *B cell differentiation
Abstract

Epstein-Barr virus (EBV) and Plasmodium falciparum have a well described role in the development of endemic Burkitt lymphoma (BL), yet the mechanisms involved remain unknown. A major hallmark of malarial disease is hemolysis and bystander eryptosis of red blood cells, which causes release of free heme in large quantities into peripheral blood. We hypothesized that heme released during malaria infection drives differentiation of latently infected EBV-positive B cells, resulting in viral reactivation and release of infectious virus. To test this hypothesis, we used the EBV-positive Mutu I B-cell line and treated with hemin (the oxidized form of heme) and evaluated evidence of EBV reactivation. Hemin treatment resulted in the expression of EBV immediate early, early and late lytic gene transcripts. In addition, expression of CD138, a marker of plasma cells was co-expressed with the late lytic protein gp350 on hemin treated Mutu I cells. Finally, DNase-resistant EBV DNA indicative of virion production was detected in supernatant. To assess the transcriptional changes induced by hemin treatment, RNA sequencing was performed on mock- and hemin-treated Mutu I cells, and a shift from mature B cell transcripts to plasma cell transcripts was identified. To identify the mechanism of hemin-induced B cell differentiation, we measured levels of the plasma cell transcriptional repressor, BACH2, that contains specific heme binding sites. Hemin treatment caused significant degradation of BACH2 by 24 hours post-treatment in four BL cell lines (two EBV positive, two EBV negative). Knockdown of BACH2 in Mutu I cells using siRNAs significantly increased CD138+gp350+ cells to levels similar to treatment with hemin. This suggested that hemin induced BACH2 degradation was responsible for plasma cell differentiation and viral reactivation. Together, these data support a model where EBV reactivation can occur during malaria infection via heme modulation, providing a mechanistic link between malaria and EBV. Author summary: EBV infection can drive cellular acquisition of cancer hallmarks and is therefore an oncogenic driver of several lymphomas and carcinomas. EBV-associated malignancies require cofactors for initiation and development, and Plasmodium falciparum acts as the cofactor for Burkitt lymphoma (BL) pathogenesis. The link between EBV and malaria has long been established, but the exact mechanisms remain unknown. EBV loads are increased in PBMCs and plasma during malaria infection, which begs the question, what about malaria infection can cause reactivation and subsequent expansion of EBV infected cells? From this question, we hypothesized heme released during malaria modulates B cells to drive EBV reactivation and plasma cell differentiation. This hypothesis was tested using hemin, the oxidized form of heme, to treat latently infected B cells at a clinically relevant concentration (pertaining to malaria infection) to measure terminal differentiation and viral reactivation. These results revealed greater understanding of how hemolytic events during malaria impact EBV latency and expand the EBV-positive B cell pool through reactivation and reinfection, therefore increasing the risk of BL. [ABSTRACT FROM AUTHOR]

Published
2023
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3. Amylin, Aβ42, and Amyloid in Varicella Zoster Virus Vasculopathy Cerebrospinal Fluid and Infected Vascular Cells.

Author

Bubak, Andrew N, Beseler, Cheryl, Como, Christina N, Coughlan, Christina M, Johnson, Noah R, Hassell, James E, Burnet, Anna M, Mescher, Teresa, Schmid, D Scott, Coleman, Colin, Mahalingam, Ravi, Cohrs, Randall J, Boyd, Timothy D, Potter, Huntington, Shilleh, Ali H, Russ, Holger A, and Nagel, Maria A

Subjects
VARICELLA-zoster virus, AMYLIN, CEREBROSPINAL fluid, CENTRAL nervous system infections, AMYLOID, SMALL interfering RNA, PROTEINS, ARTERITIS, DNA, STROKE, HERPES zoster, RESEARCH funding, HERPESVIRUSES, PANCREATIC hormones, PEPTIDES
Abstract

Background: Varicella zoster virus (VZV) vasculopathy is characterized by persistent arterial inflammation leading to stroke. Studies show that VZV induces amyloid formation that may aggravate vasculitis. Thus, we determined if VZV central nervous system infection produces amyloid.Methods: Aβ peptides, amylin, and amyloid were measured in cerebrospinal fluid (CSF) from 16 VZV vasculopathy subjects and 36 stroke controls. To determine if infection induced amyloid deposition, mock- and VZV-infected quiescent primary human perineurial cells (qHPNCs), present in vasculature, were analyzed for intracellular amyloidogenic transcripts/proteins and amyloid. Supernatants were assayed for amyloidogenic peptides and ability to induce amyloid formation. To determine amylin's function during infection, amylin was knocked down with small interfering RNA and viral complementary DNA (cDNA) was quantitated.Results: Compared to controls, VZV vasculopathy CSF had increased amyloid that positively correlated with amylin and anti-VZV antibody levels; Aβ40 was reduced and Aβ42 unchanged. Intracellular amylin, Aβ42, and amyloid were seen only in VZV-infected qHPNCs. VZV-infected supernatant formed amyloid fibrils following addition of amyloidogenic peptides. Amylin knockdown decreased viral cDNA.Conclusions: VZV infection increased levels of amyloidogenic peptides and amyloid in CSF and qHPNCs, indicating that VZV-induced amyloid deposition may contribute to persistent arterial inflammation in VZV vasculopathy. In addition, we identified a novel proviral function of amylin. [ABSTRACT FROM AUTHOR]

Published
2021
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