Ex Vivo Characterization and Targeting of the Latent HIV Infected Reservoir to Cure HIV

Overview

Combination antiretroviral therapy (cART) blocks intracellular human immunodeficiency virus (HIV) replication in CD4+ T-lymphocytes, but fails to eliminate latent HIV infected CD4+ T-lymphocytes. About 7 (range \<1-100) in 106 of these cells are latently infected and can cause reactivation of proviral HIV when cART is stopped. These latently infected cells form the reservoir and must be targeted in order to cure HIV. We would like to further investigate this reservoir and assess potential interventions to eradicate it. One promising option is to further study the influence of HIV latency disruptors (latency reversing agents, LRA) on the HIV infected reservoir. These agents are used in shock and kill strategies that disrupt latency by LRA followed by the selective (induced) killing of the reservoir cell due to viro-pathogenic effects. For accurate assessment of the reservoir and potential cure strategies, including the impact of LRA on the reservoir, a large reservoir and sufficient cells for analysis are desirable. Our understanding on the reservoir comes from in vitro lymphocyte models and early ex vivo studies. Additional studies of patients with different clinical phenotypes including untreated versus treated versus the rare individuals that control HIV spontaneously are increasingly relevant to the field. Especially this last category represent biological examples of viral control without cART and are useful to study the factors that set them apart from those that need treatment for their HIV. This study aims to deepen our understanding of the HIV reservoir and cure strategies, foremost, shock and kill strategies. We will do this by setting up a durable ex vivo platform for HIV reservoir and cure studies of which the samples can be used for hypothesis generation for in-vivo studies. A project from the Erasmus MC HIV Eradication Group (EHEG).

This is a prospective cross-sectional cohort study used for ex vivo studies using material from HIV infected individuals. Peripheral blood mononuclear cells (PBMC's) and whole blood are obtained through leukapheresis and blood sampling at a single timepoint. Relevant clinical data will be collected to support interpretation of ex vivo experimental results. In vitro experiments are performed on patient derived material. In a substudy, patients can consent to longitudinal follow up with yearly sampling for 4 years. Reservoir characteristics and efficacy of shock and kill strategies as defined in the endpoints will be explored between patients with different HIV clinical phenotypes. This allows us to identify discriminative factors useful to develop future cure strategies in clinic. We will therefore aim to include the following patients groups in the cohort: * HIV-1 patients including B and non-B subtypes patients * HIV-2 patients * Long term non progressors (plasma HIV-RNA \<2000c/mL without cART) * Elite controllers (plasma HIV-RNA \<50c/mL without cART) * Post-treatment controller (plasma HIV-RNA \<2000c/mL after permanent cART interruption)