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The latent reservoir is a major barrier to HIV cure. As latently infected cells cannot be phenotyped directly, the features of the in vivo reservoir have remained elusive. Here, we describe a method that leverages high-dimensional phenotyping using CyTOF to trace latently infected cells reactivated ex vivo to their original pre-activation states. Our results suggest that, contrary to common assumptions, the reservoir is not randomly distributed among cell subsets, and is remarkably conserved between individuals. However, reservoir composition differs between tissues and blood, as do cells successfully reactivated by different latency reversing agents. By selecting 8–10 of our 39 original CyTOF markers, we were able to isolate highly purified populations of unstimulated in vivo latent cells. These purified populations were highly enriched for replication-competent and intact provirus, transcribed HIV, and displayed clonal expansion. The ability to isolate unstimulated latent cells from infected individuals enables previously impossible studies on HIV persistence. There is no cure for the human immunodeficiency virus infection (HIV), but anti-retroviral drugs allow infected people to keep the virus at bay and lead a normal life. These drugs suppress the growth of HIV, but they do not eliminate the virus. If the treatment is interrupted, the virus bounces back within weeks in most individuals. HIV can start growing again because it hides within particular immune cells, called T cells. These infected cells stay in the infected person’s body for their whole life in a dormant or “latent” state, and represent the main barrier to an HIV cure. If these cells could be eliminated or prevented from producing more virus without daily treatment, then HIV could be cured. The fact that HIV hides inside T cells has been known for a long time, but it has remained unclear exactly what kinds of T cells the virus prefers. One challenge to characterizing latently-infected cells is that there is no single protein made by them that is not also made by uninfected T cells. The latently-infected T cells are also very rare: HIV mainly attaches to a protein called CD4, but only one in about a million T cells with CD4 contain the virus. To figure out which CD4-carrying T cells in a patient sample are latently infected, the cells are extracted from the patient’s body and ‘reactivated’ so the virus will start growing again. Unfortunately, the mixture of drugs used to reactivate the T cells changes the cells and the proteins they are producing, which obscures the features the latently-infected T cells had before reactivation. Neidleman, Luo et al. developed a new approach to trace the infected, reactivated T cells back to their state before reactivation. Using computational methods and a laboratory technique called mass cytometry, the levels of approximately 40 different proteins were measured in millions of T cells from people living with HIV. These experiments provided an ‘atlas’ of overall T cell features onto which each reactivated cell could be mapped. The population of latently-infected T cells exhibited common features among all the participants. Selecting a few of the most abundant proteins on the surface of the latently-infected cells allowed these cells to be physically separated from all other immune cells. In the future, this relatively pure population of infected T cells could be used to study how HIV can persist for many decades. The ‘map’ of these cells’ features will provide a valuable resource for HIV researchers and might enable the discovery of new drugs to eliminate the latent T cells.

The primary reservoir for HIV is within memory CD4+ T cells residing within tissues, yet the features that make some of these cells more susceptible than others to infection by HIV is not well understood. Recent studies demonstrated that CCR5-tropic HIV-1 efficiently enters tissue-derived memory CD4+ T cells expressing CD127, the alpha chain of the IL7 receptor, but rarely completes the replication cycle. We now demonstrate that the inability of HIV to replicate in these CD127-expressing cells is not due to post-entry restriction by SAMHD1. Rather, relative to other memory T cell subsets, these cells are highly prone to undergoing latent infection with HIV, as revealed by the high levels of integrated HIV DNA in these cells. Host gene expression profiling revealed that CD127-expressing memory CD4+ T cells are phenotypically distinct from other tissue memory CD4+ T cells, and are defined by a quiescent state with diminished NFκB, NFAT, and Ox40 signaling. However, latently-infected CD127+ cells harbored unspliced HIV transcripts and stimulation of these cells with anti-CD3/CD28 reversed latency. These findings identify a novel subset of memory CD4+ T cells found in tissue and not in blood that are preferentially targeted for latent infection by HIV, and may serve as an important reservoir to target for HIV eradication efforts.

CD4 T lymphocytes belong to diverse cellular subsets whose sensitivity or resistance to HIV-associated killing remains to be defined. Working with lymphoid cells from human tonsils, we characterized the HIV-associated depletion of various CD4 T cell subsets using mass cytometry and single-cell RNA-seq. CD4 T cell subsets preferentially killed by HIV are phenotypically distinct from those resistant to HIV-associated cell death, in a manner not fully accounted for by their susceptibility to productive infection. Preferentially-killed subsets express CXCR5 and CXCR4 while preferentially-infected subsets exhibit an activated and exhausted effector memory cell phenotype. Single-cell RNA-seq analysis reveals that the subsets of preferentially-killed cells express genes favoring abortive infection and pyroptosis. These studies emphasize a complex interplay between HIV and distinct tissue-based CD4 T cell subsets, and the important contribution of abortive infection and inflammatory programmed cell death to the overall depletion of CD4 T cells that accompanies untreated HIV infection.

Viral RNAis present in both the plasma and whole-cell fractions of semen,4 and infectious virus is found inseminal plasma and spermatozoa,4 with viral antigen found in spermatozoa in one patient 56 days after symptom onset.5 We have also shown that Zika virus infects the human testis ex vivo and that productively infected sperm progenitors (ie, testicular germ cells) are shed in semen from acutely infected patients.6 In this Correspondence, we report the characterisation of seminal non-sperm cells infected by Zika virus in three patients (patients 6, 13, and 15) from our published cohort,4 for whom we collected longitudinal semen smears up to 160 days after symptom onset. Through analysis of cell markers (DDX4, EPCAM, CD14, CD68, and MPO) and Zika virus antigens (envelope [E] and non-structural protein 1 [NS1]) by immunofluorescence microscopy (appendix),we found persistent shedding of Zika virus-infected testicular germ cells in the semen of all three patients. Persistent infection of non-sperm cells contributes to viral shedding and could explain the prolonged Zika virus excretion reported in semen from vasectomised men.3 The data are important and highlight the need for further studies to decipher Zika virus localisation within the human male genital tract and its consequences for reproductive function and sexual transmission.

Abstract Despite the success of combination antiretroviral therapy (ART) for individuals living with HIV, mild forms of HIV-associated neurocognitive disorder (HAND) continue to occur. Brain microglia form the principal target for HIV infection in the brain. It remains unknown how infection of these cells leads to neuroinflammation, neuronal dysfunction, and/or death observed in HAND. Utilizing two different inducible pluripotent stem cell-derived brain organoid models (cerebral and choroid plexus [ChP] organoids) containing microglia, we investigated the pathogenic changes associated with HIV infection. Infection of microglia was associated with a sharp increase in CCL2 and CXCL10 chemokine gene expression and the activation of many type I interferon stimulated genes (MX1, ISG15, ISG20, IFI27, IFITM3 and others). Production of the proinflammatory chemokines persisted at low levels after treatment of the cell cultures with ART, consistent with the persistence of mild HAND following clinical introduction of ART. Expression of multiple members of the S100 family of inflammatory genes sharply increased following HIV infection of microglia measured by single-cell RNA-seq. However, S100 gene expression was not limited to microglia but was also detected more broadly in uninfected stromal cells, mature and immature ChP cells, neural progenitor cells and importantly in bystander neurons suggesting propagation of the inflammatory response to bystander cells. Neurotransmitter transporter expression declined in uninfected neurons, accompanied by increased expression of genes promoting cellular senescence and cell death. Together, these studies underscore how an inflammatory response generated in HIV-infected microglia is propagated to multiple uninfected bystander cells ultimately resulting in the dysfunction and death of bystander neurons.

Zika virus (ZIKV) is a teratogenic mosquito-borne flavivirus that can be sexually transmitted from man to woman. The finding of high viral loads and prolonged viral shedding in semen suggests that ZIKV replicates within the human male genital tract, but its target organs are unknown. Using ex vivo infection of organotypic cultures, we demonstrated here that ZIKV replicates in human testicular tissue and infects a broad range of cell types, including germ cells, which we also identified as infected in semen from ZIKV-infected donors. ZIKV had no major deleterious effect on the morphology and hormonal production of the human testis explants. Infection induced a broad antiviral response but no IFN upregulation and minimal proinflammatory response in testis explants, with no cytopathic effect. Finally, we studied ZIKV infection in mouse testis and compared it to human infection. This study provides key insights into how ZIKV may persist in semen and alter semen parameters, as well as a valuable tool for testing antiviral agents.

People living with HIV (PLWH) on antiretroviral therapy (ART) accumulate primarily defective proviral sequences in genomes of often clonally expanded CD4+ HIV-1 target cells. Viral-derived DNA is preferentially found at distinct genomic loci suggesting a selective process driven by integration site-specific crosstalk between viral and host sequences. Focusing on one of the most prominent selected integration loci, the BTB Domain and CNC Homolog 2 ( ) gene, we here show evidence for exaptation of provirus-derived regulatory sequences leading to target cell reprogramming during long-term ART. Using a cellular model of -integrated proviruses, we find that proviral transcription drives aberrant BACH2 protein levels that escape autoregulatory feedback and impose BACH2-dependent transcriptomic changes. By mimicking these changes in primary CD4+ T lymphocytes, we observe that BACH2 drives reprogramming of cells toward a proliferative, precursor memory-like type. These reprogrammed CD4+ T cells possess traits of immune evasion and cellular survival that are signatures of HIV reservoir cells in PLWH. Inhibition of provirus transcriptional activity can mitigate exaptation, suggesting a strategy to offset HIV-driven differentiation and expansion of CD4+ T cells. Finally, our data suggest that provirus exaptation at the Signal Transducer And Activator of Transcription 5B (STAT5B) selected integration gene drives a contrary, effector-like T cell fate, suggesting a multifaceted impact of exaptation on immune homeostasis. Overall, our data demonstrate that proviruses, even if structurally defective, can modulate target cells through insertional activation of integration genes, a process which we postulate to contribute to the complex immune dysregulation experienced by ART-suppressed PLWH. People living with HIV (PLWH) on suppressive therapy accumulate genomically integrated proviruses in HIV-1-targeted immune cells. We show that HIV proviruses can exapt viral regulatory elements to disrupt integration gene control, resulting in reprogramming of HIV-targeted CD4+ T cells toward different fates. The most prominent BACH2-integrated proviruses for example direct cells toward a proliferative, memory-like state with features of persistence and immune evasion. This mechanism demonstrates how even defective proviruses contribute to immune dysregulation in HIV-1 infection, and suggests that blocking proviral transcription may mitigate these effects in PLWH.

\"Active\" reservoir cells transcribing HIV can perpetuate chronic inflammation in virally suppressed people with HIV (PWH) and likely contribute to viral rebound after antiretroviral therapy (ART) interruption, so they represent an important target for new therapies. These cells, however, are difficult to study using single-cell RNA-seq (scRNA-seq) due to their low frequency and low levels of HIV transcripts, which are usually not polyadenylated. Here, we developed \"HIV-seq\" to enable more efficient capture of HIV transcripts - including non-polyadenylated ones - for scRNA-seq analysis of cells from PWH. By spiking in a set of custom-designed capture sequences targeting conserved regions of the HIV genome during scRNA-seq, we increased our ability to find HIV RNA+ cells from PWH by up to 44%. Implementing HIV-seq in conjunction with surface phenotyping by CITE-seq on paired blood specimens from PWH before vs. after ART suppression, we found that HIV RNA+ cells were enriched among T effector memory (Tem) cells during both viremia and ART suppression, but exhibited a cytotoxic signature during viremia only. By contrast, HIV RNA+ cells from the ART-suppressed timepoints exhibited a distinct anti-inflammatory signature involving elevated TGF-β and diminished IFN signaling. Overall, these findings demonstrate that active reservoir cells exhibit transcriptional features distinct from HIV RNA+ cells during viremia, and underscore HIV-seq as a useful tool to better understand the mechanisms by which HIV-transcribing cells can persist during ART.