ABSTRACT The presence of extensive heterogeneity between individual latently HIV-1 infected T cells suggests that latent HIV-1 infection can persist under greatly differing host cell conditions. While we and others have described the biomolecular phenotype of latently infected T cells, the biomolecular driver(s) of these stable phenotypic changes remain unknown. For primary T cells, the transition to a resting memory state or T cell exhaustion effects may play a role, but latent infection is also found in naïve T cells or TfH cells suggesting additional contributing mechanisms. Leading to this application, we addressed the question whether HIV infection can trigger an irreversible modification of host cells that can explain the stability of latent infection events, and could occur independent of memory status or CD4+ T cell subtype. We show that latently infected T cell lines and a large percentage of in vitro generated latently infected primary T cells, when derived from male donors, exhibited a Loss of Y-chromosome (LOY) phenotype. Numerical chromosomal aberrations, including the loss of sex chromosomes, cause nonlinear transcriptomic changes, which would explain the observed extensive transcriptomic heterogeneity between individual latently HIV-1 infected T cells. Extensive transcriptomic changes can also result in impaired cellular signaling, and explain the widely differing reactivation response spectrum between individual cells. For primary T cells, we demonstrate that latent HIV-1 infection events in LOY cells are largely resistant to TCR/CD3-complex activation mediated reactivation, while latently infected T cells in possession of their Y-chromosome promoted HIV-1 reactivation following TCR/CD3 activation. Loss of Y- chromosome phenomena could thus explain the presence of a reactivation-resistant reservoir that has been first described by the Siliciano group. As LOY is irreversible, this is the first report of a biomolecular alteration that can mechanistically explain HIV-1 latency stability and reactivation inertness, which we consider the major hurdle to viral eradication. In this application we will extend our studies on the correlation of LOY and reactivation resistant HIV-1 latency. Our discovery provides us with the unique opportunity to separate the two phenotypic parts of the latent reservoir based on a causative mechanism (LOY) that has functional consequences (reactivation resistance), which will allow for the exploration and development of therapeutic strategies to individually target these reservoir components using single cell analysis approaches (Aim 1). In parallel we will investigate whether similar latency phenotypes can be found in T cells from female donors and whether loss of X-chromosome (LOX), the most frequent numerical chromosomal aberration in females, plays a similar role for HIV-1 latency control than LOY (Aim 2). The insights generated from this proposal should provide fundamental new insights into HIV-1 laten...