Nature Communications (Oct 2023)

Estimating the contribution of CD4 T cell subset proliferation and differentiation to HIV persistence

  • Daniel B. Reeves,
  • Charline Bacchus-Souffan,
  • Mark Fitch,
  • Mohamed Abdel-Mohsen,
  • Rebecca Hoh,
  • Haelee Ahn,
  • Mars Stone,
  • Frederick Hecht,
  • Jeffrey Martin,
  • Steven G. Deeks,
  • Marc K. Hellerstein,
  • Joseph M. McCune,
  • Joshua T. Schiffer,
  • Peter W. Hunt

DOI
https://doi.org/10.1038/s41467-023-41521-1
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 13

Abstract

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Abstract Persistence of HIV in people living with HIV (PWH) on suppressive antiretroviral therapy (ART) has been linked to physiological mechanisms of CD4+ T cells. Here, in the same 37 male PWH on ART we measure longitudinal kinetics of HIV DNA and cell turnover rates in five CD4 cell subsets: naïve (TN), stem-cell- (TSCM), central- (TCM), transitional- (TTM), and effector-memory (TEM). HIV decreases in TTM and TEM but not in less-differentiated subsets. Cell turnover is ~10 times faster than HIV clearance in memory subsets, implying that cellular proliferation consistently creates HIV DNA. The optimal mathematical model for these integrated data sets posits HIV DNA also passages between CD4 cell subsets via cellular differentiation. Estimates are heterogeneous, but in an average participant’s year ~10 (in TN and TSCM) and ~104 (in TCM, TTM, TEM) proviruses are generated by proliferation while ~103 proviruses passage via cell differentiation (per million CD4). In simulations, therapies blocking proliferation and/or enhancing differentiation could reduce HIV DNA by 1-2 logs over 3 years. In summary, HIV exploits cellular proliferation and differentiation to persist during ART but clears faster in more proliferative/differentiated CD4 cell subsets and the same physiological mechanisms sustaining HIV might be temporarily modified to reduce it.