The HIV-1 viral inhibition assay (VIA) measures CD8 T cell-mediated inhibition of HIV replication in CD4 T cells and is increasingly used for clinical testing of HIV vaccines and immunotherapies. The VIA has multiple sources of variability arising from in vitro HIV infection and co-culture of two T cell populations. Here, we describe multiple modifications to a 7-day VIA protocol, the most impactful being the introduction of independent replicate cultures for both HIV infected-CD4 (HIV-CD4) and HIV-CD4:CD8 T cell cultures. Virus inhibition was quantified using a ratio of weighted averages of p24+ cells in replicate cultures and the corresponding 95% confidence interval. An Excel template is provided to facilitate calculations. Virus inhibition was higher in people living with HIV suppressed on antiretroviral therapy (n=14, mean: 40.0%, median: 43.8%, range: 8.2 to 73.3%; p < 0.0001, two-tailed, exact Mann-Whitney test) compared to HIV-seronegative donors (n = 21, mean: -13.7%, median: -14.4%, range: -49.9 to 20.9%) and was stable over time (n = 6, mean %COV 9.4%, range 0.9 to 17.3%). Cross-sectional data were used to define 8% inhibition as the threshold to confidently detect specific CD8 T cell activity and determine the minimum number of culture replicates and p24+ cells needed to have 90% statistical power to detect this threshold. Last, we note that, in HIV seronegative donors, the addition of CD8 T cells to HIV infected CD4 T cells consistently increased HIV replication, though the level of increase varied markedly between donors. This co-culture effect may contribute to the weak correlations observed between CD8 T cell VIA and other measures of HIV-specific CD8 T cell function.
In this paper, we review the key elements that should be considered to take a novel vaccine from the laboratory through to licensure in the modern era. This paper is divided into four sections. First, we discuss the host immune responses that we engage with vaccines. Second, we discuss how in vivo and in vitro studies can inform vaccine design. Third, we discuss different vaccine modalities that have been licensed or are in testing in humans. Last, we overview the basic principles of vaccine approvals. Throughout we provide real‐world examples of vaccine development against infectious diseases, including coronavirus disease 2019 (COVID‐19).
This study investigated the function of memory CD8 T cells in HIV-infected people durably suppressed on antiretroviral therapy (HIV+ cART). We assessed bulk and virus-specific memory CD8 T cells in HIV+ cART and HIV-seronegative individuals (HIV−) by flow cytometry. We observed a population of CD3+ CD8dim CD14− CD16− (CD8dim) T cells that was expanded as a percentage of total CD8 T cells in both HIV− and CMV-seropositive individuals. Bulk memory CD8dim T cells expressed significantly higher CD69 and less MHC Class I and CD127 ex vivo than CD8bright T cells, suggesting recent activation. CD8dim T cells expressed less GLUT1 and PGC-1α and took up less glucose (2-NBDG) and lipid (Bodipy) than CD8bright T cells, indicating relatively lower metabolic activity. Multimer reactivity was used to examine CMV-, EBV- and HIV-specific CD8 T cells ex vivo. Virus-specific populations were consistently CD8high. However, after peptide stimulation, antigen-specific CD8 T cells down-regulated CD3 and CD8. CMV-specific CD8 T cells down-regulated CD3 and CD8 more than HIV-specific cells. CD3 and CD8 downregulation were strongly correlated with the functional avidity of the response. A strong correlation between GLUT1 down-regulation and CD8 down-regulation was also observed, suggesting an association between CD8 expression and metabolic activity. These results suggest that the expanded CD8dim population in HIV+ cART individuals, who are >90% CMV-seropositive, may be driven by ongoing activation of high-avidity CMV-specific CD8 T cells. They also suggest that different virus-specific CD8 T cell populations differentially downregulate components of the TCR complex and metabolism after antigen stimulation, possibly to avoid excessive activation.
This study investigated the mechanistic basis behind the reported superior efficacy of high-avidity CD8 T cells. CMV and HIV are both chronic viral infections, but while CMV-specific CD8 T cells can mediate lifelong viral control, in untreated HIV infection HIV-specific CD8 T cells progressively lose function. Using in vitro studies of human cells, we show that avidity-dependent downregulation of the CD8 co-receptor directly programs metabolism, due to a novel association between CD8 and the glucose transporter GLUT1. We used flow cytometry to profile ex vivo and virus-specific CD8 T cells from HIV-infected individuals on antiretroviral therapy. Ex vivo, cells expressing low levels of CD8 (CD8dim) expressed more CD69 but less cell surface GLUT1, and took up less glucose (2-NBDG) than CD8bright T cells. Following antigen stimulation, CD3, CD8, and GLUT1 were downregulated from the cell surface in an avidity-dependent manner. CMV-specific CD8 T cells, which were of higher avidity, downregulated these proteins to a greater extent than lower-avidity HIV-specific CD8 T cells. GLUT1 downregulation strongly correlated with CD8 but not CD3 downregulation. Antibody-mediated downregulation of CD8 from the cell surface resulted in reduced glucose uptake and increased fatty acid (Bodipy) uptake, independent of CD3. Finally, CD3, CD8, and GLUT1 downregulation by HIV-specific CD8 T cells was impaired following viral escape mutations that reduced CD8 T cell avidity. We confirmed this finding in a transduction setting with a single clonal TCR. Our data reveal a novel function of the CD8 co-receptor, linking the avidity and metabolism of CD8 T cells.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.