Cellular Activation, Differentiation, and Proliferation Influence the Dynamics of Genetically Intact Proviruses Over Time

Abstract Human immunodeficiency virus (HIV) persists in cells despite antiretroviral therapy; however, the influence of cellular mechanisms such as activation, differentiation, and proliferation upon the distribution of proviruses over time is unclear. To address this, we used full-length sequencing...

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Bibliographic Details
Published in:The Journal of infectious diseases 2022-04, Vol.225 (7), p.1168-1178
Main Authors: Horsburgh, Bethany A, Hiener, Bonnie, Fisher, Katie, Lee, Eunok, Morgan, Hannah, Eden, John-Sebastian, von Stockenstrom, Susanne, Odevall, Lina, Milush, Jeffrey M, Hoh, Rebecca, Fromentin, Rémi, Chomont, Nicolas, Hecht, Frederick M, Schlub, Timothy E, Deeks, Steven G, Palmer, Sarah
Format: Article
Language:English
Subjects:
Antiretroviral drugs
Antiretroviral therapy
CD4 antigen
CD4-Positive T-Lymphocytes
Cell differentiation
Cell Proliferation
DNA, Viral
Histocompatibility antigen HLA
HIV
HIV Infections
HIV-1 - genetics
Human immunodeficiency virus
Humans
Immunological memory
Lymphocytes T
Major and Brief Reports
Memory cells
Phylogeny
Proviruses
Proviruses - genetics
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Summary:Abstract Human immunodeficiency virus (HIV) persists in cells despite antiretroviral therapy; however, the influence of cellular mechanisms such as activation, differentiation, and proliferation upon the distribution of proviruses over time is unclear. To address this, we used full-length sequencing to examine proviruses within memory CD4+ T-cell subsets longitudinally in 8 participants. Over time, the odds of identifying a provirus increased in effector and decreased in transitional memory cells. In all subsets, more activated (HLA-DR–expressing) cells contained a higher frequency of intact provirus, as did more differentiated cells such as transitional and effector memory subsets. The proportion of genetically identical proviruses increased over time, indicating that cellular proliferation was maintaining the persistent reservoir; however, the number of genetically identical proviral clusters in each subset was stable. As such, key biological processes of activation, differentiation, and proliferation influence the dynamics of the HIV reservoir and must be considered during the development of any immune intervention. The longitudinal analysis of full-length proviruses within memory CD4+ T-cell subsets demonstrates that the biological processes of activation, differentiation, and proliferation influence the dynamics of the HIV reservoir, and must be considered during the development of any immune intervention.
ISSN:0022-1899
1537-6613
DOI:10.1093/infdis/jiab291