PURPOSE: To define which intracellular pools of sphingomyelin and ceramide are involved in the triggering of apoptosis of Jurkat leukemia cells in response to gamma-ray exposure. METHODS AND MATERIALS: We examined the kinetics of ceramide generation at the whole-cell level and in different subcellular compartments (plasma membrane rafts, mitochondria, and endoplasmic reticulum) after irradiation with photons. Ceramide was measured by high-performance liquid chromatography or after pulse labeling experiments, and the presence of sphingomyelinase within mitochondria was assessed by electron microscopy. RESULTS: Irradiation of Jurkat leukemia cells resulted in the sequential triggering of sphingomyelin hydrolysis, followed by de novo synthesis that led to a late ceramide response (from 24 h) correlated with the triggering of apoptosis. At the subcellular level, pulse-label experiments, using [(3)H]-palmitate as a precursor, strengthened the involvement of the radiation-induced sphingomyelin breakdown and revealed a very early peak (15 min) of ceramide in plasma membrane rafts. A second peak in mitochondria was measured 4 h after irradiation, resulting from an increase of the sphingomyelin content relating to the targeting of acid sphingomyelinase toward this organelle. CONCLUSION: These data confirm that ceramide is a major determinant in the triggering of radiation-induced apoptosis and highlight the complexity of the sequential compartment-specific ceramide-mediated response of Jurkat leukemia cells to gamma-rays.
PURPOSE: To define which intracellular pools of sphingomyelin and ceramide are involved in the triggering of apoptosis of Jurkat leukemia cells in response to gamma-ray exposure. METHODS AND MATERIALS: We examined the kinetics of ceramide generation at the whole-cell level and in different subcellular compartments (plasma membrane rafts, mitochondria, and endoplasmic reticulum) after irradiation with photons. Ceramide was measured by high-performance liquid chromatography or after pulse labeling experiments, and the presence of sphingomyelinase within mitochondria was assessed by electron microscopy. RESULTS: Irradiation of Jurkat leukemia cells resulted in the sequential triggering of sphingomyelin hydrolysis, followed by de novo synthesis that led to a late ceramide response (from 24 h) correlated with the triggering of apoptosis. At the subcellular level, pulse-label experiments, using [(3)H]-palmitate as a precursor, strengthened the involvement of the radiation-induced sphingomyelin breakdown and revealed a very early peak (15 min) of ceramide in plasma membrane rafts. A second peak in mitochondria was measured 4 h after irradiation, resulting from an increase of the sphingomyelin content relating to the targeting of acid sphingomyelinase toward this organelle. CONCLUSION: These data confirm that ceramide is a major determinant in the triggering of radiation-induced apoptosis and highlight the complexity of the sequential compartment-specific ceramide-mediated response of Jurkat leukemia cells to gamma-rays.
Authors: Chad P Satori; Michelle M Henderson; Elyse A Krautkramer; Vratislav Kostal; Mark D Distefano; Mark M Distefano; Edgar A Arriaga Journal: Chem Rev Date: 2013-04-10 Impact factor: 60.622
Authors: Jeremy Shaw; Pedro Costa-Pinheiro; Logan Patterson; Kelly Drews; Sarah Spiegel; Mark Kester Journal: Adv Cancer Res Date: 2018-06-19 Impact factor: 6.242
Authors: Joseph C Cheng; Aiping Bai; Thomas H Beckham; S Tucker Marrison; Caroline L Yount; Katherine Young; Ping Lu; Anne M Bartlett; Bill X Wu; Barry J Keane; Kent E Armeson; David T Marshall; Thomas E Keane; Michael T Smith; E Ellen Jones; Richard R Drake; Alicja Bielawska; James S Norris; Xiang Liu Journal: J Clin Invest Date: 2013-09-16 Impact factor: 14.808