Exosomal Tat protein activates latent HIV-1 in primary, resting CD4+ T lymphocytes
Xiaoli Tang, Huafei Lu, Mark Dooner, Stacey Chapman, Peter J. Quesenberry, Bharat Ramratnam
Xiaoli Tang, Huafei Lu, Mark Dooner, Stacey Chapman, Peter J. Quesenberry, Bharat Ramratnam
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Research Article AIDS/HIV Infectious disease

Exosomal Tat protein activates latent HIV-1 in primary, resting CD4+ T lymphocytes

Abstract

Replication competent HIV-1 persists in a subpopulation of CD4+ T lymphocytes despite prolonged antiretroviral treatment. This residual reservoir of infected cells harbors transcriptionally silent provirus capable of reigniting productive infection upon discontinuation of antiretroviral therapy. Certain classes of drugs can activate latent virus but not at levels that lead to reductions in HIV-1 reservoir size in vivo. Here, we show the utility of CD4+ receptor targeting exosomes as an HIV-1 latency reversal agent (LRA). We engineered human cellular exosomes to express HIV-1 Tat, a protein that is a potent transactivator of viral transcription. Preparations of exosomal Tat-activated HIV-1 in primary, resting CD4+ T lymphocytes isolated from antiretroviral-treated individuals with prolonged periods of viral suppression and led to the production of replication competent HIV-1. Furthermore, exosomal Tat increased the potency of selected LRA by over 30-fold in terms of HIV-1 mRNA expression, thereby establishing it as a potentially new class of biologic product with possible combinatorial utility in targeting latent HIV-1.

Authors

Xiaoli Tang, Huafei Lu, Mark Dooner, Stacey Chapman, Peter J. Quesenberry, Bharat Ramratnam

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Figure 2

Subcellular localization of engineered EXO-Tat protein.

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Subcellular localization of engineered EXO-Tat protein. HEK293T cells we...
HEK293T cells were maintained in culture and transfected by pEXO-Tat or an empty expression vector (EV). Cells and supernatants were fractionated, and Western blot revealed Tat expression in all cellular fractions examined, as well as in released exosomes. GAPDH was used to control for protein loading in experiments involving cellular fractions, and Alix was used for those involving exosomal preparations. No Tat protein was detected in parallel experiments involving the transfection of an EV. EXO-Tat protein expression in whole cell lysate (A), cytoplasmic fraction (B), nuclear fraction (C), membranous fraction (D), and released exosomes (E).