Apoptosis induction in lymphoma cells: thiol deprivation versus thiol excess.

We studied the effects of thiol availability on apoptosis induction in B-cell lymphoma 38C13, T-cell lymphoma EL4, and also other cells. Compounds with a free SH group are required for survival and growth of 38C13 cells but not of EL4 cells. Thiol deprivation (2-mercaptoethanol concentrations about 0.3 microM and lower) induced apoptosis in 38C13 cells. On the other hand, thiol excess (2-mercaptoethanol concentrations higher than 300 microM) induced apoptosis in 38C13 cells and EL4 cells as well as in other cells (e.g. Raji, HeLa). L-cystine and non-thiol antioxidant ascorbic acid were unable to support survival of 38C13 cells. Ascorbic acid induced cell death at concentrations higher than 600 microM. Thiol cross-linking compound diamide (100 microM and higher) abrogated the survival-supporting effect of 2-mercaptoethanol (50 microM). Apoptosis induction by thiol deprivation and by thiol excess was not directly related to a specific significant change in the p53 level or p53 activation. Apoptosis induction by thiol excess was associated with a certain decrease in the Bcl-2 level while the Bax level did not change. We conclude that both thiol deprivation and thiol excess can induce apoptosis in lymphoma cells. Apoptosis induction by thiol deprivation is specifically related to the presence of a free SH group. However, apoptosis induction by thiol excess does not seem to be specifically related to the presence of a free SH group. It probably results from the excess of a reductant. Apoptotic control protein p53 does not seem to play a significant role in apoptosis induction either by thiol deprivation or by thiol excess.

Differing sensitivity of tumor cells to apoptosis induced by iron deprivation in vitro.

We studied the sensitivity of tumor cells to the induction of apoptosis by iron deprivation. Iron deprivation was achieved by the employment of a defined iron-deficient culture medium. Mouse 38C13 cells and human Raji cells die within 48 and 96 h of incubation in iron-deficient medium, respectively. On the contrary, mouse EL4 cells and human HeLa cells are completely resistant to the induction of death under the same experimental arrangement. Deoxyribonucleic acid fragmentation analysis by agarose gel electrophoresis as well as flow cytometric analysis after propidium iodide staining detected in 38C13 and Raji cells, but not in EL4 and HeLa cells, changes characteristic to apoptosis. The 38C13 cells, sensitive to iron deprivation, also displayed a similar degree of sensitivity to apoptosis induction by thiol deprivation (achieved by 2-mercaptoethanol withdrawal from the culture medium) as well as by rotenone (50 nM), hydroxyurea (50 microM), methotrexate (20 nM), and doxorubicin (100 nM). Raji cells shared with 38C13 cells a sensitivity to rotenone, methotrexate, doxorubicin, and, to a certain degree, to hydroxyurea. However, Raji cells were completely resistant to thiol deprivation. EI4 and HeLa cells, resistant to iron deprivation, also displayed a greater degree of resistance to most of the other apoptotic stimuli than did their sensitive counterparts. We conclude that some tumor cells in vitro are sensitive to apoptosis induction by iron deprivation, while other tumor cells are resistant. All the tumors found to be sensitive to iron deprivation in this study (four cell lines) are of hematopoietic origin. The mechanism of resistance to apoptosis induction by iron deprivation differs from the mechanism of resistance to thiol deprivation.