OBJECTIVES: To investigate the potential for CD4+CD8+ T cells [CD8 double positive (CD8 DP)] T cells to form a reservoir of HIV-1 following HAART through measurement of the rate of decay of infected CD4/CD8 DP T cells. METHODS: HIV-1 proviral loads in highly pure CD4 and CD8 DP T cells were determined for study subjects before and after 200-400 days of therapy and HIV-1 DNA decay rates were calculated. RESULTS: Before therapy, HIV-1 proviral load in CD8 DP correlated negatively with CD4 cell count. Decay rates of HIV-1-infected CD4 and CD8 DP T cells were similar. Rates for CD8 DP T cells correlated with the time to suppression of viral replication, whereas no such relationship was true for CD4 cell decay rates. A significant reduction in activated cells was observed for both cell types. The action of HAART on HIV-1 replication was similar for both CD4 cells and CD8 DP T cells, although the rate of clearance of infected CD8 DP T cells appeared more critical for a rapid reduction in plasma viral load. Although the size of the CD8 DP T cell reservoir in peripheral blood was smaller relative to that of CD4 cells, HAART did not completely clear HIV-1 infection from this cell subset. CONCLUSION: This study confirmed that CD8 DP T cells are a major reservoir for HIV-1 in vivo and, therefore, represent a potential reservoir for HIV-1 during HAART, in a manner analogous to that of CD4 T cells.
OBJECTIVES: To investigate the potential for CD4+CD8+ T cells [CD8 double positive (CD8 DP)] T cells to form a reservoir of HIV-1 following HAART through measurement of the rate of decay of infected CD4/CD8 DP T cells. METHODS:HIV-1 proviral loads in highly pure CD4 and CD8 DP T cells were determined for study subjects before and after 200-400 days of therapy and HIV-1 DNA decay rates were calculated. RESULTS: Before therapy, HIV-1 proviral load in CD8 DP correlated negatively with CD4 cell count. Decay rates of HIV-1-infectedCD4 and CD8 DP T cells were similar. Rates for CD8 DP T cells correlated with the time to suppression of viral replication, whereas no such relationship was true for CD4 cell decay rates. A significant reduction in activated cells was observed for both cell types. The action of HAART on HIV-1 replication was similar for both CD4 cells and CD8 DP T cells, although the rate of clearance of infected CD8 DP T cells appeared more critical for a rapid reduction in plasma viral load. Although the size of the CD8 DP T cell reservoir in peripheral blood was smaller relative to that of CD4 cells, HAART did not completely clear HIV-1 infection from this cell subset. CONCLUSION: This study confirmed that CD8 DP T cells are a major reservoir for HIV-1 in vivo and, therefore, represent a potential reservoir for HIV-1 during HAART, in a manner analogous to that of CD4 T cells.
Authors: Marc A Frahm; Ralph A Picking; JoAnn D Kuruc; Kara S McGee; Cynthia L Gay; Joseph J Eron; Charles B Hicks; Georgia D Tomaras; Guido Ferrari Journal: J Immunol Date: 2012-03-28 Impact factor: 5.422
Authors: Shi Zou; Yuting Tan; Yanni Xiang; Yang Liu; Qi Zhu; Songjie Wu; Wei Guo; Mingqi Luo; Ling Shen; Ke Liang Journal: Front Public Health Date: 2022-05-27
Authors: Juliana de Meis; Désio Aurélio Farias-de-Oliveira; Pedro H Nunes Panzenhagen; Naiara Maran; Déa Maria Serra Villa-Verde; Alexandre Morrot; Wilson Savino Journal: J Parasitol Res Date: 2012-02-01
Authors: Alexandra Melton; Lara A Doyle-Meyers; Robert V Blair; Cecily Midkiff; Hunter J Melton; Kasi Russell-Lodrigue; Pyone P Aye; Faith Schiro; Marissa Fahlberg; Dawn Szeltner; Skye Spencer; Brandon J Beddingfield; Kelly Goff; Nadia Golden; Toni Penney; Breanna Picou; Krystle Hensley; Kristin E Chandler; Jessica A Plante; Kenneth S Plante; Scott C Weaver; Chad J Roy; James A Hoxie; Hongmei Gao; David C Montefiori; Joseph L Mankowski; Rudolf P Bohm; Jay Rappaport; Nicholas J Maness Journal: PLoS Pathog Date: 2021-12-20 Impact factor: 6.823