Ionizing radiation induces blockade of c-Jun N-terminal kinasedependent cell death pathway in amanner correlated with p21Cip/WAF1 induction in primary cultured normal human fibroblasts

During radiotherapy of cancer, neighboring normal cells may receive sub-lethal doses of radiation. To investigate whether such low levels of radiation modulate normal cell responses to death stimuli, primary cultured human fibroblasts were exposed to various doses of gamma-rays. Analysis of cell viability using an exclusion dye propidium iodide revealed that the irradiation up to 10 Gy killed the fibroblasts only to a minimal extent. In contrast, the cells efficiently lost their viability when exposed to 0.5-0.65 mM H2O2. This type of cell death was accompanied by JNK activation, and was reversed by the use of a JNK-specific inhibitor SP600125. Interestingly, H2O2 failed to kill the fibroblasts when these cells were pre-irradiated, 24 h before H2O2 treatment, with 0.25-0.5 Gy of gamma-rays. These cytoprotective doses of gamma-rays did not enhance cellular capacity to degrade H2O2, but elevated cellular levels of p21Cip/WAF1, a p53 target that can suppress H2O2-induced cell death by blocking JNK activation. Consistently, H2O2-induced JNK activation was dramatically suppressed in the pre-irradiated cells. The overall data suggests that ionizing radiation can impart normal fibroblasts with a survival advantage against oxidative stress by blocking the process leading to JNK activation.

Proteomic analysis of the cellular proteins induced by adaptive concentrations of hydrogen peroxide in human U937 cells

When cells are first exposed to low levels of oxidative stress, they develop a resistance to a subsequent challenge of the same stress, even at higher levels. Although some protein(s) induced by oxidative stress likely mediated this adaptive response, the nature of these proteins is unknown. In this study, the total proteins extracted from human U937 leukemia cells exposed to 50 mM H2O2 for 24 h to induce an optimal protective response were analyzed by two-dimensional polyacrylamide gel electrophoresis. H2O2 treatment induced elevation of level of 34 protein spots. An analysis of these spots by a matrix associated laser desorption/ionization time-of-flight mass spectrometry identified 28 of the H2O2-induced proteins. These include proteins involved in energy metabolism, translation and RNA processing, chaperoning or mediating protein folding, cellular signaling, and redox regulation, as well as a mitochondrial channel component, and an actin-bundling protein. Therefore, it appears that the cellular adaptation to oxidative stress is a complex process, and is accompanied by a modulation of diverse cellular functions.

Two Distinxt Apoptotic Pathway in Human Monocytes Mediated by IL-4 and Fas / 대한면역학회지

Apoptosis has ernerged as a key mechanism for regulating the number of leukocytes at sites of inflammation. Besides withdrawal of inflammatory stimuli, apoptosis of human monocytes can be directly triggered through two cell surface molecules, Fas and the IL-4 receptor. In contrast to Fas-mediated death which utilizes reactive oxygen intermediates (ROI) as instruments of death, IL-4-induced apoptosis of monocytes was neither blocked by antioxidants, nor accompanied by elevation of cellular ROI. Moreover, PMA which upregulates protein kinase C (PKC) inhibited IL-4-, but not Fas-mediated death. These data define a ROl-dependent, PKC-resistant Fas pathway, and a ROl-independent, PKC-susceptible IL-4 pathway of apoptosis. Monocyte apoptosis triggered by depletion of inflammatory mediators resembles the IL-4 pathway. Within the context of an inflammatory site, monocyte accumulation and depletion may be susceptible to manipulation through these pathways.