Mitomycin C induced increases in the activities of the deoxyribonucleases of HeLa cells

Mechanism of unbalanced growth-induced cell damage. II. A probable relationship between unbalanced growth, DNA breakage and cell death

This study examines the relationship between unbalanced growth, DNase II activity, DNA breakage and cell survival during the exposure of L5178Y cells to hydroxyurea (HU), excess thymidine (dThR) or HU with excess of four deoxyribonucleosides (dNR). It has been found that in the cells arrested by HU or dThR, but still appearing viable with the trypan blue exclusion test, Protein/DNA imbalance and abnormal cell volume are correlated with enhancement of DNase II activity in the cells and in the medium and with moderate increase in parental DNA breakage. The incidence of DNA breaks was markedly potentiated in the presence of non-toxic concentration of caffeine (CAF), used to inhibit DNA repair. In HU+dNR arrested cells, in which unbalanced growth was abolished, enhancement of DNase II activity and of DNA breakage in the presence or absence of CAF was substantially prevented. Comparison of posttreatment cell survival in the presence or absence of CAF confirmed the differential effect of CAF: while in HU or dThR arrested cells the presence of CAF induced marked cell killing, in HU+dNR arrested cells the influence of CAF was negligible. Only a slight effect of CAF was observed in cells in which dThR-induced arrest and unbalanced growth were reversed by deoxycytidine (dCR) addition. It is suggested that the involvement of DNA nucleases in the unbalanced growth-induced overproduction of numerous hydrolytic enzymes, with their progressive leakage through the cell membranes, can lead to progressive DNA digestion. DNA breaks produced in this way are normally, at least partly, repaired. Concomitant exposure of such cells to DNA repair inhibitor can markedly enhance the level of breaks, leading to potentiation of unbalanced growth-induced cell killing.

Mechanism of unbalanced growth-induced cell damage. I. A probable role for hydrolytic enzymes synthesis

This study examines the relationship between cell progress into the state of unbalanced growth, hydrolytic enzyme activities and cell survival during the exposure of L5178Y cells to hydroxyurea (HU), excess thymidine (dThR), hydroxyurea with excess of four deoxyribonucleosides (dNR) or excess dTHR with deoxycytidine (dCR). Cell progress into the state of unbalanced growth was measured as cell size, protein/DNA ratio and protein content per cell. Activities of two lysosomal (acid phosphatase, beta-N-acetylglucosaminidase) and one cytoplasmic non-lysosomal (LDH) enzymes were determined. It has been found that in cells arrested by HU or excess dThR, a progressive cell volume increase with protein/DNA imbalance is correlated with a progressive increase in lysosomal and non-lysosomal hydrolase activities in the cells and in the medium and with a marked lethal effect. Cell volume increase, enhancement of enzyme activities and cell killing could be prevented in HU-arrested cells by concomitant addition of excess dNR (deoxyadenosine, deoxyguanosine, thymidine, deoxycytidine) leading to equal inhibition of DNA and protein synthesis. Control-like values of all parameters were achieved also in cells in which the dThR-inhibiting effect was reversed by dCR addition. It is suggested that a common pathway in the mode of action of the chemotherapeutic agents inducing cell killing through the state of unbalanced growth can be the over-production, abnormal accumulation and progressive leakage of numerous hydrolytic enzymes through the cell membranes, leading in consequence to 'lytic' cell death.

Physical, chemical, and biological factors affecting sister-chromatid exchange induction in human lymphocytes exposed to mitomycin C prior to culture

In experiments to assess the effects of several biological, chemical, and physical variables on sister-chromatid exchange (SCE) induction in cultured lymphocytes exposed to mitomycin C (MMC) before PHA stimulation we observed: (1) high SCE frequencies in female cells, and normal SCE frequencies in Y-bearing metaphases in mixed cultures containing equal numbers of MMC-treated female lymphocytes and untreated male lymphocytes; (2) small, but statistically significant, decreases in SCEs with increasing pH after G0 exposure in the pH range 6.6-7.6; (3) pronounced reductions in MMC-induced SCEs in lymphocytes exposed at 4 degrees C vs. 37 degrees C. In other studies, SCE induction was evaluated in cultures exposed during G0 to MMC concentrations ranging from 0.25 to 2.5 microgram/ml for varying time intervals ranging from 5 min to 24 h. For all concentrations tested SCE induction varied as a linear function of G0 exposure time. To compare SCE induction between cultures, we calculated the mean frequencies of SCEs induced per metaphase/unit dose MMC/unit G0 exposure time (SCE/microgram/h). A mean frequency of 20.7 +/- 4.8 SCE/microgram/h was observed for 41 lymphocyte cultures suggesting that a single term adequately describes the rate of SCE induction following G0 exposure to a 10-fold range in concentration of MMC for time intervals of 30 min to 24 h.

Use of biochemical lesions for selection of human cells with hybrid cytoplasms

Techniques for preparing large populations of anucleate cytoplasms from cultured eukaryotic cells have only recently been described. The principal value of anucleate cytoplasms derives from studies that can be done after they are fused to whole cells. Since present methods for the isolation of heterokaryons are unsuitable for the selection of hybrids between whole cells and anucleate cytoplasms (heteroplasmons), a selective system has been developed which is based on the capacity of anucleate cytoplasms containing active enzymes to rescue whole cells poisoned with iodoacetate. Ethidium bromide, a partially effective agent, was used in conjunction with iodoacetate to demonstrate the feasibility of selecting heterokaryons by producing complementary biochemical lesions in the parental cell strains. The potential for artifact in these systems is not, however, entirely precluded.