Soumitra Sen

Apoptosis Biochemical events and relevance to cancer chemotherapy

Two distinct pathways for cell death exist. Compared to necrotic death, physiological or apoptotic cell death is an active suicidal process that consists of a cascade of well‐regulated synthetic events. Participation of specific genes in apoptosis, and its possible molecular regulation, are considered in order to investigate the mechanism of cell death induced by some cancer chemotherapeutic agents.

PROGRAMMED CELL DEATH: CONCEPT, MECHANISM AND CONTROL

Programmed cell death or apoptosis occurs under physiological conditions as a result of physiological effectors. It is a relatively slower process and requires active participation of the cell in the suicidal mechanism. Apoptosis is controlled by precise intrinsic genetic programme and may be induced by almost all those stimuli causing necrosis. The role played by the intensity in determining the death process and the underlying mechanism is imperfectly understood. Morphologically apoptotic cells appear as small condensed body. The chromatin is dense and fragmented, packed into compact membrane-bound bodies together with randomly distributed cell organelles. The plasma membrane loses its characteristic architecture and shows extensive blebbing. It buds off projections so that the whole cell may split into several membrane-bound apoptotic bodies. Significant chemical changes take place in the plasma membrane. This helps in recognition of the apoptotic bodies by phagocytes. At this moment it is unclear if all cells can undergo apoptosis or it is a characteristic of only some tissues which are predisposed to apoptotic death being directly under the control of hormones or growth factors. Experimental studies aimed at comparison of induction of apoptosis in cells of different origin are warranted to elucidate this point. Biochemically a pre-commitment step for induction of death programmation through macromolecular synthesis is essential for most systems. The double-stranded linker DNA between nucleosomes is cleaved at regular inter-nucleosomal sites through the action of a Ca2+, Mg(2+)-sensitive neutral endonuclease. Zinc is a potent inhibitor of the enzyme. Calcium probably plays a key controlling role in activation of the enzyme since prevention of Ca2+ increase prevents endonuclease activation. It is becoming evident that signal transduction through appropriate receptors control the Ca2+ flux in the cells. Most apoptotic cells require synthesis of RNA and proteins. Delay or abrogation of apoptosis by inhibition of macromolecular synthesis is well known. The dying cells show high mRNA levels for several enzymes. Several degradative enzymes become active. Regulatory proteins maintain control over the apoptotic cascade. At the molecular level, search has been initiated for the mammalian equivalents of the cell death (ced) gene. Activation of several specific genes is indicated. Specific expression of cell death-associated gene products (e.g. TRPM-2/SGP-2) has been reported in several unrelated apoptotic cell systems. Sequential induction of c-fos, c-myc and 70 kDa heat shock protein is reported. Studies demonstrate that certain genes must remain in a transcriptionally active demethylated state during programmed cell death. Recent evidences clearly indicate that apoptosis may be positively or negatively modulated by certain genes.(ABSTRACT TRUNCATED AT 400 WORDS)

Ciprofloxacin: mammalian DNA topoisomerase type II poison in vivo

Ciprofloxacin (CF), a fluoroquinolone widely used as a potent antimicrobial drug, was evaluated in vivo in mouse bone marrow cells for its ability to induce clastogenicity and DNA damage in terms of increased sister-chromatid exchange (SCE) frequencies. Doses of 0.6, 6 and 20 mg/kg body weight of CF given intraperitoneally induced a positive dose-dependent significant clastogenicity (trend test alpha < or = 0.05), though the effects were not specific for specific phases of the cell cycle. The DNA-damaging effect observed as increased SCE frequencies using doses of 0.15, 0.30, 0.60, 1.2 and 6 mg/kg body weight showed a significant dose-dependent increase (trend test alpha < or = 0.05; lowest effective concentration 1.2 mg/kg of body weight). Compared to a potent eukaryotic DNA topoisomerase type II poison, etoposide (VP-16, 0.5, 1 and 5 mg/kg body weight, given intraperitoneally), ciprofloxacin produced comparable dose-dependent SCE frequency increases. Ciprofloxacin was postulated to be specific for the target DNA gyrase, the prokaryotic homologue of DNA topoisomerase type II enzyme. The present paper along with the existing earlier data strongly suggest that topoisomerase type II and DNA gyrase are physiological targets for the drug action. In view of the present significant in vivo mammalian DNA topoisomerase type II-mediated genotoxicity and clastogenicity data, ciprofloxacin should be administered with caution.

Inhibition of clastogenic effects of cesium chloride in mice in vivo by chlorophyllin.

The antagonistic effect of chlorophyllin was tested in reducing the clastogenic action of cesium chloride (CsCl) in vivo on mice bone marrow cells. CsCl induced chromosomal aberration in frequencies directly proportional to the dose administered. Chlorophyllin, when given alone, was not clastogenic even at a concentration of 1.5 mg/kg body wt. of the animal. Simultaneous administration of chlorophyllin and CsCl reduced chromosomal aberrations significantly at 24 h. Exposure to the same dose of chlorophyllin 2 h before exposure to CsCl also decreased clastogenic effects but to a lesser extent. These findings are of importance in view of the uptake of radioactive Cs by green plants after nuclear fallout.

Potentiation of etoposide cytotoxicity against a human ovarian cancer cell line by pretreatment with non-toxic concentrations of methotrexate or aphidicolin

Exposure of human ovarian cancer SW626 cell line to 0.08 mumol/l methotrexate or 25 mumol/l aphidicolin for 24 h caused no cytotoxicity but enhanced etoposide cytotoxicity. Methotrexate or aphidicolin treatment induced a reversible blockade at the beginning of S phase which was reversed upon drug removal with a consequent wave of synchronisation. The enhancement of etoposide cytotoxicity was not due to higher etoposide intracellular uptake in the methotrexate or aphidicolin-pretreated cells. The topoisomerase II content in methotrexate or aphidicolin pretreated SW626 cells was higher than in control cells assessed by western blotting or flow cytometry. The higher etoposide cytotoxicity observed after synchronization with methotrexate or aphidicolin was apparently unrelated to the number of drug-induced DNA-topoisomerase II complexes evaluated as DNA double strand breaks or DNA-protein crosslinks. These data support the view that etoposide-induced DNA-topoisomerase II complexes are more cytotoxic in cells which are in S-phase.

Phenethyl isotiocyanate modulates clastogenicity of mitomycin C and cyclophosphamide in vivo

Phenethyl isothiocyanate (PEITC), a constituent of many cruciferous vegetables, is an effective chemopreventive agent against N-nitrosamine-induced carcinogenesis. We have investigated the extent to which PEITC modulates the clastogenicity of standard genotoxicants, mitomycin C and cyclophosphamide, using bone marrow cells of Swiss albino mice. PEITC, 1 mumol/kg body weight in corn oil was administered by gavage for 7 consecutive days to prime the animals. 24 h later, mice received a single dose of cyclophosphamide (10 or 20 mg/kg body weight) or mitomycin C (1 or 2 mg/kg body weight) intraperitoneally. Clastogenicity of the chemicals was compared using PEITC-primed and non-primed animals 24 h after clastogen treatment. As a single agent, PEITC is not clastogenic even after 7 days of priming. Oral priming with PEITC decreased the aberrations per cell values by 22-67% in all cases. PEITC could only alleviate the clastogenicity of 1 mg/kg body weight mitomycin C to near-control values (p < or = 0.05). Although PEITC is reported to be effective against N-nitrosamine-induced tumorigenesis by preventing metabolic activation and by blocking the reactive species formed, it is virtually ineffective against the clastogenicity of cyclophosphamide. The results of inhibition by PEITC of the clastogenicity of mitomycin C suggest that the modulation of mitomycin C bio-activation contributes to, but may not be sufficient for, PEITC chemoprevention of clastogenicity by mitomycin C.

Comparative efficacy of chlorophyllin in reducing cytotoxicity of some heavy metals

SummaryThe potential of chlorophyllin in reducing clastogenicity was studied against two concentrations of each of three potent metallic clastogens (cesium chloride, mercuric chloride and cobalt chloride) in bone marrow cells of mice in vivo. The respective salts and chlorophyllin were administered orally to mice by gavaging in different combinations. Simultaneous administration of chlorophyllin with both concentrations of each salt reduced the clastogenic effects in the order Cs > Hg > Co. Chlorophyllin could not decrease the clastogenic effects when administered 2 h before the salts.

Potentiation of Betel-Induced Alterations of Mouse Glandular Stomach Mucosa by Tobacco in Studies Simulating Betel Addiction

AbstractHistopathological effects of chewing of betel quid with tobacco was studied by simulating four different chewing habits, using mouse glandular stomach mucosa as a model system. Chronic oral administration for five months resulted in marked intestinal metaplasia in all animals receiving extract of tobacco with betel nut and lime and extract of tobacco with betel leaf, nut and lime, in doses normally ingested by human addicts. Tobacco markedly augmented the effect of other ingredients. Lime and Piper betle L. var. bangla probably played a protectant role by reducing the dysplasia and metaplasia. In the light of the growing use of smokeless tobacco and betel chewing habits, our results may exemplify the way in which the various chewing mixtures, which are ingested daily in relatively large quantities, could affect carcinogenesis in habitual chewers.

Betel Cytotoxicity: Further Evidence from Mouse Bone Marrow Cells

AbstractLong term studies (up to 10 months) for the simulation of betel habits, with or without tobacco, as currently practiced in Oriental countries, were performed using inbred Swiss albino mice. The cytotoxic and clastogenic potential of these complex chewing mixtures were assessed distally on bone marrow cells. Total aqueous extracts of Areca catechu L. nut and Nicoliana tabacum L. sundried leaf have been found to be mitogenic. The basic ingredients of the quid per se were not clastogenic. Tobacco, in any combination of chewing mixture, induced time-dependent clastogenicity. Direct damage to chromosomes was observed in the early stage, and lethal effects were observed in the latter stages of the study. Nuclear DNA content of the cells, measured in situ by Feulgen cytophotometry, was increased after administration of A. catechu and Piper betle leaf (vars. Bangla and Metha-Thakpala) or any combination of tobacco with or without leaf; nut and lime [Ca(OH)2]. High lime and leaf (var. Bangla) counteracted ...

O6-Alkylguanine-DNA alkyltransferase content in synchronised human cancer cells.

SummaryThe DNA repair enzymeO6-alkylguanine-DNA alkyltransferase (AT) was analysed in the human ovarian-cancer SW626 cell line and in the human promonocytic leukemia U937 cell line following their synchronisation with low non-toxic concentrations of methotrexate. In SW626, AT increased in the early S phase of the cell cycle and then declined during progression of the S phase to levels found in the G1 phase of unsynchronised cells. In contrast, at the G1/S-phase boundary and in the S phase, U937 cells showed a lower AT content than did exponentially growing unsynchronised cells. In addition, AT activity was greatly reduced in resting U937 cells but was not reduced appreciably in resting SW626 cells. The results of these studies indicate that AT fluctuations do not follow a constant pattern during the cell cycle of different cell lines.