The HIV-1 specific T cell response is initially effective but in the face of HIV-1's phenomenal ability to alter its sequence and escape from immune pressure, loss of CD4 T cell help and chronic antigen, the response becomes "exhausted" and no longer can longer control HIV-1 replication. Overcoming or reversing T cell exhaustion is likely going to be an important part of any successful HIV-1 immunotherapy, but how to do this is currently not clear. We propose to develop and combine two exciting approaches to restore HIV-1 specific immunity. The first involves using high affinity HIV-1 specific TCRs to redirect the immune response toward HIV-1. This approach has the potential to reset the HIV-1 specific exhaustion clock and to re-establish control of HIV-1 replication. Our preliminary data indicates the high affinity TCRs confer a more pronounced polyfunctional T cell response, the ability to control HIV-1 replication at low effector to target ratios and the ability to recognize common SL9-escape mutants. Here, we propose to extend these to studies to in vivo models and mechanistic studies. The second approach is to render these HIV-1 specific T cells resistant to the exhaustion differentiation pathway by targeting PD-1 expression. To do this we will use zinc finger nucleases to permanently disrupt PD-1 expression. The advantage of this approach over the systematic delivery of blocking Abs is that loss of PD-1 expression is restricted to the HIV-1 specific T cells that are being infused. Thus, the potential for autoimmunity is reduced. We propose to achieve our goal of reinvigorating the HIV-1 specific immune response through three related and coordinated specific aims: 1) Develop and characterize a lead PD-1 specific ZFN;2 Determine how PD-1 deficiency affects the HIV-1 specific T cell response;3) Perform in vivo, pre-clinical experiments to determine whether PD-1 deficient HIV-1 specific T cells are superior at controlling HIV-1 replication. These studies will provide the basis and rationale to test this approach in humans and hopefully lead to clinical tools that successfully control of HIV-1 replication in the absence of HAART.

National Institute of Health (NIH)
National Cancer Institute (NCI)
Research Project (R01)
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AIDS Immunology and Pathogenesis Study Section (AIP)
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Ogunbiyi, Peter
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University of Pennsylvania
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