Susanne von Stockenström scite author profile

Summary Latent replication-competent HIV-1 persists in individuals on long-term antiretroviral therapy (ART). We developed the Full-Length Individual Proviral Sequencing (FLIPS) assay to determine the distribution of latent replication-competent HIV-1 within memory CD4+ T cell subsets in six individuals on long-term ART. FLIPS is an efficient, high-throughput assay that amplifies and sequences near full-length (~9 kb) HIV-1 proviral genomes and determines potential replication-competency through genetic characterization. FLIPS provides a genome-scale perspective which addresses the limitations of other methods that also genetically characterize the latent reservoir. Using FLIPS, we identified 5% proviruses as intact and potentially replication-competent. Intact proviruses were unequally distributed between T cell subsets, with effector memory cells containing the largest proportion of genetically intact HIV-1 proviruses. We identified multiple identical intact proviruses suggesting a role for cellular proliferation in the maintenance of the latent HIV-1 reservoir.

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The HIV-1 reservoir in eight patients on long-term suppressive antiretroviral therapy is stable with few genetic changes over time

Josefsson

Stockenström

Faria

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

249

296

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Significance Identifying the source and dynamics of persistent HIV-1 during combinational antiretroviral therapy (cART) is crucial for understanding the barriers to curing HIV infection. Through genetic characterization of HIV-1 DNA in infected cells from peripheral blood and gut-associated lymphoid tissue from patients after long-term suppressive cART, our study reveals that the primary barrier to a cure is a remarkably stable pool of infected memory CD4 + T cells. Through in-depth phylogenetic analyses, we determined that the HIV-1 reservoir in these cells from eight patients is kept stable during long-term cART and, with little evidence of viral replication, this population could be maintained by homeostatic cell proliferation or other processes.

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Longitudinal Genetic Characterization Reveals That Cell Proliferation Maintains a Persistent HIV Type 1 DNA Pool During Effective HIV Therapy

et al. 2015

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High levels of genetically intact HIV in HLA-DR+ memory T cells indicates their value for reservoir studies

Horsburgh

Lee

Hiener

et al. 2020

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Objective: The contribution of HLA-DR+ memory CD4+ T cells to the HIV reservoir during prolonged antiretroviral therapy is unclear as these cells are commonly excluded when assessing for replication-competent HIV. To address this issue, we examined the distribution of genetically intact HIV DNA within HLA-DR− and HLA-DR+ memory CD4+ T cells and the RNA transcriptional profile of these cells during antiretroviral therapy. Design/methods: Full-length DNA sequencing was used to examine the HIV DNA landscape within HLA-DR+ and HLA-DR− memory CD4+ T cells. RNA quantification and sequencing was used to interrogate the relationship between HLA-DR status and HIV RNA transcription. Results: HLA-DR+ CD4+ T cells contained a high frequency of genetically intact HIV genomes, contributing over half of the genetically intact viral sequences to the reservoir. Expansions of genetically identical sequences were identified in all T-cell subsets, indicating that cellular proliferation maintains genetically intact and defective viral DNA during therapy. Intracellular HIV RNA levels in HLA-DR+ and HLA-DR− T cells were not statistically different by either long terminal repeat quantitative PCR quantification or single-genome RNA sequencing of the p6-RT region. Conclusion: The high proportion of intact viral DNA sequences in the proliferative HLA-DR+ subset suggests they are critical in maintaining HIV infection during effective therapy. As such, these cells should be included in any immune intervention targeting HIV during effective therapy.

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Impact of Antiretroviral Therapy Duration on HIV-1 Infection of T Cells within Anatomic Sites

Lee

Stockenström

Morcilla

et al. 2020

J Virol

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Understanding the impact of antiretroviral therapy (ART) duration on HIV-infected cells is critical for developing successful curative strategies. To address this issue, we conducted a cross-sectional/inter-participant genetic characterization of HIV-1 RNA from pre- and on-therapy plasmas and HIV-1 DNA from CD4+ T cell subsets derived from peripheral blood (PB), lymph node (LN), and gut tissues of 26 participants after 3 to 17.8 years of ART. Our studies revealed in four acute/early participants who had paired PB and LN samples a substantial reduction in the proportion of HIV-infected cells per year on therapy within the LN. Extrapolation to all 12 acute/early participants estimated a much smaller reduction in the proportion of HIV-1-infected cells within LNs per year on therapy that was similar to that in the participants treated during chronic infection. LN-derived effector memory T (TEM) cells contained HIV-1 DNA that was genetically identical to viral sequences derived from pre- and on-therapy plasma samples. The proportion of identical HIV-1 DNA sequences increased within PB-derived TEM cells. However, the infection frequency of TEM cells in PB was stable, indicating that cellular proliferation that compensates for T cell loss over time contributes to HIV-1 persistence. This study suggests that ART reduces HIV-infected T cells and that clonal expansion of HIV-infected cells maintains viral persistence. Importantly, LN-derived TEM cells are a probable source of HIV-1 genomes capable of producing infectious HIV-1 and should be targeted by future curative strategies. IMPORTANCE HIV-1 persists as an integrated genome in CD4+ memory T cells during effective therapy, and cessation of current treatments results in resumption of viral replication. To date, the impact of antiretroviral therapy duration on HIV-infected CD4+ T cells and the mechanisms of viral persistence in different anatomic sites is not clearly elucidated. In the current study, we found that treatment duration was associated with a reduction in HIV-infected T cells. Our genetic analyses revealed that CD4+ effector memory T (TEM) cells derived from the lymph node appeared to contain provirus that was genetically identical to plasma-derived virions. Moreover, we found that cellular proliferation counterbalanced the decay of HIV-infected cells throughout therapy. The contribution of cellular proliferation to viral persistence is particularly significant in TEM cells. Our study emphasizes the importance of HIV-1 intervention and provides new insights into the location of memory T cells infected with HIV-1 DNA, which is capable of contributing to viremia.

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

Horsburgh

Hiener

Fisher

et al. 2021

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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 eight participants. Over time, the odds of identifying a provirus increased in effector and decreased in transitional memory cells. In all subsets, the more activated (HLA-DR-expressing) cells contained a higher frequency of intact provirus, as did more differentiated cells such as the 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.

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Cellular proliferation maintains genetically intact and defective HIV-1 over time

Horsburgh

Hiener

Eden

et al. 2019

Journal of Virus Eradication

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The genetic traits of full-length HIV sequenced from memory T cell subsets

Horsburgh

Hiener

Lee

et al. 2017

Journal of Virus Eradication

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