Abstract
HIV cannot be cured by current antiretroviral therapy (ART) because it persists in a transcriptionally silent form in long-lived CD4+ cells. Leading efforts to develop a functional cure have prioritized latency reversal to expose infected cells to immune surveillance, coupled with enhancement of the natural cytolytic function of immune effectors, or “kick and kill.” The most clinically advanced approach to improving the kill is therapeutic immunization, which aims to augment or re-focus HIV-specific cytolytic T cell responses. However, no vaccine strategy has enabled sustained virological control after ART withdrawal. Novel approaches are needed to overcome the limitations of natural adaptive immune responses, which relate to their specificity, potency, durability, and access to tissue reservoirs. Adoptive T cell therapy to treat HIV infection was first attempted over two decades ago, without success. Since then, progress in the field of cancer immunotherapy, together with recognition of the similarities in tumor microenvironments and HIV reservoirs has reignited interest in the application of T cell therapies to HIV eradication. Advances in engineering of chimeric antigen receptor (CAR)-transduced T cells have led to improved potency, persistence and latterly, resistance to HIV infection. Immune retargeting platforms have incorporated non-neutralizing and broadly neutralizing antibodies to generate Bispecific T cell Engagers (BiTEs) and Dual-Affinity Re-Targeting proteins (DARTs). T cell receptor engineering has enabled the development of the first bispecific Immune-mobilizing monoclonal T Cell receptors Against Viruses (ImmTAV) molecules. Here, we review the potential for these agents to provide a better “kill” and the challenges ahead for clinical development.
Highlights
Long-lived cells that harbor replication-competent HIV are responsible for viral persistence during antiretroviral therapy (ART)
The lack of a unique and reliable marker of these diverse reservoirs has significantly encumbered the development of strategies to provide either a sterilizing cure, in which all forms of HIV are eliminated from the body, or a functional cure, defined by long-term control of HIV and preserved immune competence after ART withdrawal [12, 13]
Modified hematopoietic stem cells (HSC)-derived chimeric antigen receptor (CAR) T cells were shown to engraft, proliferate, and display antiviral activity in a humanized mouse model of HIV infection; in a non-human primate model only transient and partial control of viral replication was observed after SHIV challenge and withdrawal of ART [54, 55]
Summary
Long-lived cells that harbor replication-competent HIV are responsible for viral persistence during antiretroviral therapy (ART). We discuss the potential for T cell retargeting therapies to bring about a functional cure by overcoming the hurdles outlined above, namely, overcoming low antigen expression through affinity enhancement of antigen receptors, mobilizing sufficient numbers of effectors targeting conserved or non-escaped viral epitopes, recruiting functionally intact cells, and exploiting technologies to optimize tissue penetration and persistence (Figure 1). Modified HSC-derived CAR T cells were shown to engraft, proliferate, and display antiviral activity in a humanized mouse model of HIV infection; in a non-human primate model only transient and partial control of viral replication was observed after SHIV challenge and withdrawal of ART [54, 55]. Two clinical trials of CAR T cell therapy in HIV-positive ARTtreated subjects are ongoing or due to recruit: one is evaluating a bNAb (VRC01)-based CAR, VC-CAR-T (NCT03240328) and the other, a CD4 CAR modified for HIV resistance by ZFN disruption of CCR5 and conjugation of the C34 peptide to the CXCR4 N-terminus (NCT03617198) [61]
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