Detection and quantification of live, apoptotic, and necrotic human peripheral lymphocytes by single-laser flow cytometry

Abstract

Regulation of peripheral lymphocyte number involves a poorly understood balance between cell renewal and loss. Disrupting this balance leads to a large number of disease states. Methods which allow qualitative and quantitative measurements of cell viability are increasingly valuable to studies directed at revealing the mechanisms underlying apoptotic and necrotic cell death. Here, we have characterized a method using single-laser flow cytometry that differentiates and quantifies the relative number of live, apoptotic, and late-stage apoptotic and necrotic peripheral lymphocytes. Following in vitro gamma irradiation and staining with acridine orange in combination with ethidium bromide, three distinct populations were seen by bivariate analysis of green versus red fluorescence. The identity of each distinct fluorescent population (whether live, apoptotic, or necrotic) was determined by sorting and examination of cellular morphology by electron microscopy. This flow cytometric method is directly compared with the techniques of trypan blue exclusion and DNA fragmentation to quantify cell death following exposure to various doses of in vitro gamma irradiation and postirradiation incubation times. We extend our findings to illustrate the utility of this method beyond analyzing radiation-induced apoptotic peripheral blood mononuclear cells (PBMC); similar fluorescent patterns are shown for radiation- and corticosteroid-treated murine thymocytes, activated human PBMC, and PBMC from human immunodeficiency virus-infected individuals. Our results demonstrate that dual-parameter flow cytometric analysis of acridine orange-ethidium bromide-stained lymphocytes is overall a superior method with increased sensitivity, greater accuracy, and decreased subjectivity in comparison with the other methods tested. By using standard laser and filter settings commonly available to flow cytometric laboratories, this method allows rapid measurement of a large number of cells from a heterogeneous sample.