by Brigham and Women’s Hospital
Phenotypic profile of patient-derived HIV-1-infected cells circulating in PB. a, Global visualization of phenotypic properties of HIV-1-infected CD4+ T cells from five study participants using two-dimensional UMAP plots; five computationally defined spherical clusters reflecting phenotypically distinct mCD4+ T cell subsets are shown. One plot is shown for each cell category. b, A heatmap summarizing the normalized phenotypic profile of cells in each spherical cluster, based on 53 surface markers included in this study. c, Volcano plots showing enrichment ratios of marker-positive cells and corresponding FDR-adjusted (adj.) P values for all 53 surface markers included in this study; selected markers are labeled individually. Marker sensitivities, calculated as the proportions of marker-positive cells in the indicated categories of cells, are indicated by dot sizes. Comparisons between indicated categories of cells are depicted; bootstrapped data from all five participants are shown. Significance was tested using a two-sided chi-squared test; FDR-adjusted P values are shown. Credit: Nature (2023). DOI: 10.1038/s41586-022-05538-8
Soon after infection, HIV-1 establishes a life-long presence by forming viral reservoirs in the body—cells that are infected with HIV but not actively producing new viruses. Antiretroviral therapy (ART) reduces HIV levels in the blood, but a small population of virally infected cells persists indefinitely, making HIV infection an incurable disease. Those cells capable of reigniting infection upon discontinuation of ART are extremely rare, and until now have eluded identification and characterization.
Researchers at the Ragon Institute of MGH, MIT, and Harvard; the National Institute of Allergies and Infectious Diseases; and Mass General Brigham’s founding members, Brigham and Women’s Hospital (BWH) and Massachusetts General Hospital (MGH), now report the application of novel technology that allows multidimensional characterization of single cells (single-cell proteogenomic profiling) to study HIV reservoir cells isolated directly from people living with HIV-1.
With this new technical approach, they found signature surface markers that may explain how some HIV reservoir cells can persist long-term and resist host immune responses. The findings, recently published in Nature, may inform future strategies for curing HIV.
“High-throughput, single-cell sequencing now allows us to take a precise look at the surface profile of the very small numbers of infected cells that persist lifelong despite antiretroviral therapy, and can fuel rebound viremia when treatment is stopped. With this knowledge, we are able to understand their susceptibilities and vulnerabilities, and can develop a tailored immune response to target these cells,” says Mathias Lichterfeld, MD, Ph.D., professor of Medicine at Harvard Medical School, infectious disease physician at the Brigham and Women’s Hospital and Massachusetts General Hospital, and senior author of the study.
Researchers collected peripheral blood cells from five HIV-positive study participants. Four of the participants had been on ART for about 10 years, and one was an “elite controller” who had undetectable levels of HIV in the blood despite not being on ART. Earlier blood samples from two of these participants after only 1–2 years of ART were also analyzed. The researchers also collected lymph node cells from three HIV-positive study participants who had been on ART for 10 to 15 years. From these samples, they isolated memory CD4+ T cells, white blood cells that are produced in response to infection and that represent the primary target cells for HIV.
The researchers developed a new experimental strategy called phenotypic and proviral sequencing (PheP-Seq), a single-cell next-generation sequencing technology to evaluate biomarkers on the surface of individual virally infected cells. Using PheP-Seq, they analyzed more than 530,000 individual peripheral blood cells and 396,000 single lymph node cells.
Blood cells that contained intact proviruses, complete viral genomes that have been incorporated into the host cell’s DNA, frequently had surface biomarkers associated with increased resistance to being killed by cytotoxic T and NK cells, two types of immune cells that typically protect against viral infection. The reservoir cells also had elevated expression of immune checkpoint markers that limit viral gene transcription. This means that some HIV-1 reservoir cells have specific characteristics that may reduce exposure to and killing by the immune system, which could explain why they persist in the body.
Some of the cells collected 1–2 years after participants started ART already showed increased expression of these biomarkers and immune checkpoint markers, although the changes were less pronounced relative to later stages of ART, when these resistant cells became more readily identifiable. Cells with intact virus from the lymph nodes showed upregulated surface markers promoting cell survival, giving the resistant reservoir cells a selective advantage.
Overall, the results suggest that only a small subset of infected cells are optimally adapted to evade the immune system and survive during long-term ART treatment. Moreover, the data indicate that the human immune system is able to exert effective immune selection pressure on most HIV reservoir cells.
These biomarkers are unlikely to be universal in all ART-treated people living with HIV, the researchers note, because selection may vary due to differences in individual immune responses. Still, the identification of phenotypic biomarkers distinguishing viral reservoir cells may inform future research into an HIV-1 cure. If researchers can develop clinical strategies designed to intensify and accelerate immune selection of HIV-1 reservoir cells, they may be able to reduce HIV long-term persistence and induce drug-free remission.
“Over more than four decades, HIV has slowly but progressively revealed its secrets, and this is yet another critical secret revealed. The ability to visualize individual reservoir cells was a pipe dream, and now has become a reality. Now we must build on this information to eradicate these cells,” says Bruce Walker, MD, Director of the Ragon Institute of MGH, MIT and Harvard and co-investigator in the study.
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