Cytotoxicity, DNA cross-linking, and single strand breaks induced by activated cyclophosphamide and acrolein in human leukemia cells

The in vitro cytotoxicity and mechanism of action of cyclophosphamide (CP) were studied in a dual cell culture system, using rat hepatocytes and K562 human chronic myeloid leukemia cells. Cytotoxicity and DNA damage were measurable in K562 cells using CP concentrations that are clinically attainable. Alkaline elution analysis of cellular DNA demonstrated the presence of concentration- and time-dependent DNA interstrand cross-links, DNA-protein cross-links, and DNA single strand breaks in K562 cells following a 1-h exposure to cyclophosphamide activated by hepatocytes. Hepatocyte-activated CP was 3 to 4 times more potent than phosphoramide mustard with regard to cytotoxicity and induction of DNA interstrand cross-links. Exposure to phosphoramide mustard did not produce single strand breaks, but exposure of K562 cells to acrolein resulted in substantial levels of single strand breaks. The demonstration of acrolein-induced single strand breaks following exposure to activated CP is a novel finding and suggests that acrolein may have a role in the cytotoxicity of CP.     

Analysis of the induction of alkali sensitive sites in the DNA by chromate and other agents that induce single strand breaks

CaCrO₄ was shown to induce alkali labile sites in the DNA ofChinese hamster ovary cells by analysis of the lack of linearityin the alkaline elution curves, and by a study of the dependenceupon pH in the elution of DNA from filters. The effect of CaCrO₄on these parameters was compared with N-methyl-N-nitrosourea,an agent known to produce alkali labile sites. Based upon theaforementioned parameters HgCl₂, formaldehyde and X-rays causedthe formation of frank single strand breaks with little or noinduction of alkaline labile sites. These findings demonstratedifferences in the production of alkali sensitive sites by agentsthat cause DNA single strand breaks.     

Glutathione depletion as a determinant of sensitivity of human leukemia cells to cyclophosphamide

The role of glutathione (GSH) as a determinant of cellular sensitivity to the cytotoxic and DNA-damaging effects of cyclophosphamide (CP) was studied in a dual culture system of rat hepatocytes and K562 human chronic myeloid leukemia cells, which have elevated aldehyde dehydrogenase activity with a corresponding insensitivity to activated CP. Exposure of K562 cells to 50 microM DL-buthionine-S,R-sulfoximine for 24 h resulted in a depletion of cellular GSH content to 10% of control values without toxicity. Subsequent 1-h exposure of GSH-depleted cells to activated cyclophosphamide, obtained by incubation of CP with suspension cultures of rat hepatocytes, resulted in a 5-fold potentiation of the cytotoxicity of CP. Alkaline elution analysis of cellular DNA demonstrated that the level of apparent interstrand cross-linking was 3 to 4 times higher in GSH-depleted cells than in nondepleted cells. GSH-depleted cells were, in addition, more sensitive to induction of DNA single strand breaks than nondepleted cells. Depletion of GSH content did not increase cellular sensitivity to the cytotoxicity of phosphoramide mustard. Preincubation of K562 cells with 1 mM cysteine for 4 h resulted in an approximately 60% increase in cellular GSH content, which was accompanied by decreased sensitivity to the cytotoxicity of hepatocyte-activated CP. Exposure of nondepleted cells to clinically relevant concentrations of hepatocyte-activated CP resulted in depletion of cellular GSH content. Replenishment of GSH content in these cells was relatively slow following CP exposure. Acrolein was highly effective at depleting cellular GSH content, whereas phosphoramide mustard had no effect on cellular GSH content. The depletion of GSH by intracellularly released acrolein may be important in the mechanism of cytotoxicity of CP.     

Differential induction of DNA strand breaks by nitrosamines in the rat liver and esophagus

Hepatic and esophageal nuclei were isolated from Sprague-Dawley rats treated with 5 mg/kg dimethylnitrosamine (DMN), 100 mg/kg diethylnitrosamine (DEN) and 2.5 mg and 10 mg/kg methylbenzylnitrosamine (MBN) and subjected to alkaline elution to determine DNA strand breaks and their subsequent repair. Results obtained showed that hepatic nuclei isolated from rats 4 h after treatment by either DMN or DEN had about 60% of the DNA eluting through the filter. However, at 12 h post treatment, while about 50% of the single-strand breaks in dimethylnitrosamine treated rats were repaired, only about 10-15% of such breaks induced by DEN were repaired in the liver. That DEN is a more effective inducer of hepatic preneoplastic lesions could thus be attributed to this slow repair of the DEN induced lesions. Strand breaks were neither induced by DMN in the esophagus nor by MBN in the liver, the nontarget tissues. More surprising, however, was the finding that MBN induced little or no single-strand breaks in its target tissue, the esophagus. Furthermore, there was no evidence for DNA-protein cross-linking or alkali labile sites in the esophageal DNA. The results indicate that DNA damage induced by the initiating carcinogen in the target tissue may not necessarily involve strand breaks.     

Depletion of cellular glutathione by N,N'-bis(trans-4-hydroxycyclohexyl)-N'-nitrosourea as a determinant of sensitivity of K562 human leukemia cells to 4-hydroperoxycyclophosphamide

N,N'-Bis(trans-4-hydroxycyclohexyl)-N'-nitrosourea (BHCNU) is a nitrosourea which has carbamoylating but not alkylating activity. It has been shown to carbamoylate and inactivate glutathione reductase thereby reducing the intracellular levels of glutathione (GSH). Since GSH depletion by buthionine-S,R-sulfoximine potentiates the cytotoxicity of cyclophosphamide, with a corresponding increase in DNA cross-linking, we have investigated the potential interaction between BHCNU and cyclophosphamide. Treatment of K562 human leukemia cells with 15 microM BHCNU for 1 h resulted in depletion of glutathione to 40% of control values, without significant reduction of cell viability. Subsequent treatment with 10 microM 4-hydroperoxycyclophosphamide (4-HC), a self-activating derivative of cyclophosphamide, reduced the level of glutathione to less than 20% of control values. BHCNU pretreatment enhanced the cytotoxicity of 4-HC resulting in a dose modification factor of 2.5. Alkaline elution analysis of cellular DNA demonstrated that the level of interstrand cross-linking was 2-fold higher in GSH-depleted cells than in nondepleted cells, and the induction of single strand breaks was markedly increased. These findings demonstrate that BHCNU potentiates the cytotoxicity of 4-HC and suggest that this is due to the increased formation of DNA interstrand cross-links caused by a reduced intracellular conjugation of 4-HC with glutathione which results in an increased binding of 4-HC to DNA targets.     

Paradoxical increase in DNA cross-linking in a human ovarian carcinoma cell line resistant to cyanomorpholino doxorubicin

The cyanomorpholino analog of doxorubicin (MRA-CN) is a potent cytotoxic agent which is known to cross-link DNA. A human ovarian carcinoma cell line, ES-2, was grown in increasing concentrations of MRA-CN from 0.1 to 0.5 nM. The resultant resistant subline, ES-2R, was 4-fold resistant to MRA-CN. DNA damage and repair in response to MRA-CN were compared in the parental and resistant cell lines using alkaline elution. DNA cross-links were detectable after 3-h incubation of the cells at 37 degrees C in MRA-CN at concentrations greater than or equal to 1.0 nM. Paradoxically, 2-fold more cross-links were detected in the ES-2R cells as compared with the ES-2 cells. This paradoxical difference in cross-links between the 2 cell lines was observed to increase with time of exposure to 2.5 nM of MRA-CN. Non-protein-associated DNA strand breaks were also detected in the 2 cell lines after exposure to 2.5 nM of the drug. The ES-2 cells consistently showed twice as many breaks as the ES-2R cells, which could explain the paradoxical higher apparent DNA cross-linking observed with the ES-2R cells after exposure to MRA-CN. Studies of the time course of cross-link repair after exposure to MRA-CN revealed that 75% of the DNA cross-links disappeared in the ES-2R cells by the end of 8 h in drug-free medium. In contrast, cross-links in the ES-2 cells were undetectable after 4 h, which coincided with a progressive increase in DNA strand breaks. The topoisomerase II level in the ES-2 cells was 2- to 4-fold higher than that in the ES-2R cells. However, proteinase K treatment of the lysed cells did not increase the number of apparent strand breaks produced by MRA-CN, suggesting that topoisomerase II may not be involved. These findings indicate that, in addition to DNA cross-linking, MRA-CN causes DNA strand breakage. Resistance to MRA-CN in the ES-2R cells is associated with more apparent DNA cross-linking and less DNA strand breakage, which may be a consequence of differences in DNA repair and/or nonspecific DNA degradation between the resistant and the sensitive cell lines.     

Effect of aldehyde dehydrogenase inhibitors on the ex vivo sensitivity of human multipotent and committed hematopoietic progenitor cells and malignant blood cells to oxazaphosphorines

The ex vivo sensitivity of human multipotent and committed hematopoietic progenitor cells and several cultured human malignant blood cell lines to analogues of "activated" cyclophosphamide, namely, 4-hydroperoxycyclophosphamide and mafosfamide, and to phosphoramide mustard was quantified with and without concurrent exposure to an inhibitor of aldehyde dehydrogenase activity, namely, disulfiram, cyanamide, diethyldithiocarbamate, or ethylphenyl(2-formylethyl)phosphinate. Inhibitors of aldehyde dehydrogenase activity potentiated the cytotoxic action of 4-hydroperoxycyclophosphamide and mafosfamide toward all of the hematopoietic progenitors; they did not potentiate the cytotoxic action of phosphoramide mustard toward these cells. Potentiation of the cytotoxic action of mafosfamide toward cultured human malignant blood cells was minimal. Spectrophotometric assay revealed little NAD-linked aldehyde dehydrogenase activity present in the cultured human tumor cell lines as compared to that found in normal mouse liver or oxazaphosphorine-resistant L1210 cells. Cellular aldehyde dehydrogenases are known to catalyze the oxidation of 4-hydroxycyclophosphamide/aldophosphamide, the major intermediate in cyclophosphamide bioactivation, to the relatively nontoxic acid, carboxyphosphamide. Thus, our findings indicate that human multipotent hematopoietic progenitor cells contain the relevant aldehyde dehydrogenase activity, the relevant activity is retained upon differentiation to progenitors committed to the megakaryocytoid, granulocytoid/monocytoid, and erythroid lineages, and the relevant activity may be lost or diminished upon transformation of hematopoietic progenitors to malignant cells.     

Phenotypically deficient urinary elimination of carboxyphosphamide after cyclophosphamide administration to cancer patients

The 0-24-h urinary metabolic profile of cyclophosphamide was investigated in a series of 14 patients with various malignancies receiving combination chemotherapy including i.v. cyclophosphamide. This was accomplished using combined thin-layer chromatography-photography-densitometry, which can quantitate cyclophosphamide and its four principal urinary metabolites (4-ketocyclophosphamide, nor-nitrogen mustard, carboxyphosphamide, and phosphoramide mustard). Recovery of drug-related metabolites was 36.5 +/- 17.8% (SD) dose, the most abundant metabolites being phosphoramide mustard (18.5 +/- 16.1% dose) and unchanged cyclophosphamide (12.7 +/- 9.3% dose). The most variable metabolite was carboxyphosphamide, with five patients excreting 0.3% dose or less. These patients were termed low carboxylators (LC) and could be distinguished from high carboxylators (HC) by a carboxylation index (relative percentage as carboxyphosphamide multiplied by 10). Mean carboxylation indices for the LC and HC phenotypes were 3.4 +/- 2.6 and 151 +/- 115, respectively. There were no associations between patient age, sex, body weight, tumor type, or concomitant drug therapy and carboxylation phenotype. Neither 4-ketocyclophosphamide nor nor-nitrogen mustard excretion differed between LC and HC phenotypes; however, HC patients had a greater excretion of cyclophosphamide (46.4 +/- 15.5 relative percentage) than LC patients (19.4 +/- 12.6%). The DNA cross-linking cytotoxic metabolite phosphoramide mustard was elevated more than 2-fold in the LC (76.5 +/- 13.9%) compared with the HC (33.0 +/- 12.2%) phenotype. It is concluded that these data represent the first evidence of a defect in cyclophosphamide metabolism, and it is proposed that this arises from a hitherto unrecognized aldehyde dehydrogenase genotype.     

DNA-protein cross-linking and DNA interstrand cross-linking by haloethylnitrosoureas in L1210 cells.

Bifunctional alkylating agents are known to produce cross-links between DNA and protein and between paired DNA strands. The possibility of discriminating these two classes of cross-links in L1210 cells treated with haloethylnitrosoureas or nitrogen mustard was explored with the alkaline elution technique. Two classes of cross-links were demonstrated, based on sensitivity to proteinase K; the proteinase-sensitive cross-links appear to be DNA-protein cross-links, and the proteinase-resistant class may include interstrand cross-links. Proteinase-sensitive cross-links form more rapidly than do proteinase-resistant cross-links in cells treated with chloroethylnitrosoureas, perhaps because these agents can chloroethylate protein sulfhydryl or amino groups followed by rapid reaction of these chloroethylated groups with DNA. Although both types of cross-links produced by nitrogen mustard disappeared or were repaired after 24 hr, the removal of cross-links produced by chloroethylnitrosoureas either did not occur or was incomplete in 24 hr. In addition to cross-links, cells treated with haloethylnitrosoureas exhibited DNA strand breaks; a method is suggested for estimating the apparent frequencies of strand breaks and cross-links in the DNA.     

Measurements of DNA damage in Chinese hamster cells treated with equitoxic and equimutagenic doses of nitrosoureas.

The DNA of V-79 Chinese hamster cells was examined by alkaline elution following treatment of cultures with eight different nitrosoureas. Drug incubations were performed under consistent biological conditions of equal toxicity and equal mutation induction at the hypoxanthineguanine phosphoribosyltransferase locus. The goals of this study were to determine whether DNA damage could be detected in cells treated with biologically relevant doses of nitrosoureas and to determine whether the type and number of observed DNA lesions could be correlated with the cytotoxic and mutagenic effects of the drugs. All of the compounds tested produced, to some degree, lesions that were observed as DNA strand breaks upon exposure of the DNA to alkali. The levels of DNA strand breaks and/or alkali-labile lesions were comparable for all of the drugs at the equimutagenic doses. DNA cross-linking was observed at both the equitoxic and the equimutagenic concentrations of the haloethylnitrosoureas, but cross-linking was not observed with methylnitrosourea or streptozotocin. Methylnitrosourea and streptozotocin required approximately 40 times the drug concentration to produce toxicity equal to the haloethylnitrosoureas. These data suggest that the ability to cross-link DNA confers increased cytotoxicity to the haloethylnitrosoureas.     

Auromomycin-induced DNA damage and repair in human leukemic lymphoblasts (CCRF-CEM cells)

An alkaline elution procedure was used to study the nature of DNA damage induced by auromomycin, an antitumor protein, in human leukemic lymphoblasts (CCRF-CEM cells). The filter elution of drug-treated cells at pH 12.2 and 9.6 showed induction of both single and double strand DNA breaks. The DNA strand scission activities were linear in relation to drug concentration. The frequency of single strand breaks was higher than that of the double strand breaks. Protein-associated DNA single strand breaks were also detected in alkaline elution of drug-treated cells when a proteinase K digestion step was included in the assay protocol. The auromomycin-induced single strand breaks were repaired to almost completion within 8 h of postincubation of DNA-damaged cells whereas the repair of double strand breaks was not detected.     

A proposed mechanism of resistance to cyclophosphamide and phosphoramide mustard in a Yoshida cell line in vitro

Summary A Yoshida sarcoma cell line (Y_R/cyclo) showing decreased sensitivity to metabolically activated cyclophosphamide in vitro has been shown to be cross-resistant to phosphoramide mustard, the ultimate alkylating agent formed from cyclophosphamide. Resistance to these alkylating agents has been shown to be associated with increased activity of the glutathione S-transferase group of enzymes, and with elevated levels of glutathione, the cosubstrate of the enzyme. The resistant cell line shows lower levels of cellular damage, as measured by alkaline elution following treatment with phosphoramide mustard, than the parental (Ys) line. The mechanism of resistance is ascribed to increased deactivation of potentially damaging metabolites of cyclophosphamide by the glutathione S-transferase enzymes, resulting in decreased cellular damage in the resistant cell line.This work was supported by a grant from the Cancer Research Campaign     

Evidence for a role of chloroethylaziridine in the cytotoxicity of cyclophosphamide

A number of investigators have observed that the use of 4-hydroperoxycyclophosphamide (4-HC) in multiwell plate cytotoxicity assays can be associated with toxicity to cells in wells that contain no drug. Previous reports have implicated diffusion of 4-HC decomposition products, and acrolein in particular, as the active species. Purpose: The purpose of this study was to elucidate the species responsible for the airborne cytotoxicity of 4-HC, and to devise ways to minimize such effects in chemosensitivity assays. Methods: To this end, analogues of 4-HC were synthesized to identify the contributions of individual cyclophosphamide metabolites to cytotoxicity. The analogues were then tested for activity against three human breast tumor cell lines (including a line resistant to 4-HC), and one non-small-cell lung carcinoma line. Cytotoxicity was evaluated by assays that quantitate cellular metabolism and nucleic acid content. Results: Didechloro-4-hydroperoxycyclophosphamide, a compound that generates acrolein and a nontoxic analogue of phosphoramide mustard, gave no cross-well toxicity. In contrast, a significant neighboring well effect was observed with phenylketophosphamide, a compound that generates phosphoramide mustard but not acrolein. Addition of authentic chloroethylaziridine reproduced the airborne toxicity patterns generated by 4-HC and phenylketophosphamide. Increasing the buffering capacity of the growth medium and sealing the microtiter plates prevented airborne cytotoxicity. Conclusions: Since it is unlikely that phosphoramide mustard is volatile, these findings implicate chloroethylaziridine rather than acrolein as the volatile metabolite of 4-HC that is responsible for airborne cytotoxicity. The fact that chloroethylaziridine is generated in amounts sufficient to volatilize, diffuse across wells and cause cytotoxicity indicates that it is an important component in the overall cytotoxicity of 4-HC in vitro. Furthermore, these findings suggest that chloroethylaziridine may also contribute to the toxicity of cyclophosphamide in vivo. Received: 9 July 1999 / Accepted: 19 November 1999     

Mechanisms of Cyclophosphamide Resistance in a Human Myeloid Leukemia Cell Line

The 4-hydroperoxycyclophosphamide (4HC)-resistant B5-180³ subline of the cloned KBM-7/B5 cell line was developed as a model of induced cyclophosphamide resistance in human myeloid leukemia. Based on IC₉₀ values, this subline was $20-fold resistant to 4HC. Furthermore, it was significantly cross-resistant to phosphorodiamidic mustard (PM), whose cytotoxicity is independent of aldehyde dehydrogenase (ADH). Using alkaline elution we found that the resistant line had decreased initial levels of DNA interstrand cross-links (ISCs) following 4HC but not PM treatment. The resistant cells also appeared to remove ISCs from their DNA more rapidly than the parental cells. Our data therefore suggest that 4HC resistance in the B5-180³ subline is multifactorial; ADH is an important mediator of its resistance to ISC induction by 4HC, while a second process, which may involve an increased ability to tolerate drug-induced DNA damage, appears to be important for its resistance to both 4HC and PM. The B5-180³ cells were also cross-resistant to γ-radiation ($ 1.7-fold at a surviving fraction of 0.1); if generally applicable, such effects could have important clinical implications, since pretransplant total body irradiation is a major component of the eradiction of leukemic cells.     

Binding of metabolites of cyclophosphamide to DNA in a rat liver microsomal system and in vivo in mice

The stability of phosphoramide mustard, a metabolite of cyclophosphamide was studied at pH 7.2 and 37 degrees C using 31P nuclear magnetic resonance. The phosphorus signal of phosphoramide mustard disappeared with a half-life of 8 min indicating rapid conversion to other species. The final product, inorganic phosphate, appeared with a half-life of 105 min indicating that phosphoramide mustard was easily dephosphoramidated. A rat liver microsomal system was used to study the binding of [chloroethyl-3H]cyclophosphamide to DNA. DNA was hydrolyzed in 0.1 N HCl:0.5 N NaCl at 80 degrees C for 20 min, conditions known to convert phosphoramide mustard to nornitrogen mustard with liberation of the phosphoramide residue. After such treatment three adducts were detected by high-performance liquid chromatography using several elution systems. They were all 7-substituted guanine adducts of nornitrogen mustard; two were monoalkylation products with an intact [N-(2-chloroethyl)-N-[2-(7-guaninyl)ethyl]amine] or an hydroxylated mustard arm [N-(2-hydroxyethyl)-N-[2-(7-guaninyl)ethyl]amine]; the third adduct was a cross-linked product [N,N-bis [2-(7-guaninyl)ethyl]-amine]. The relative abundance of these adducts depended on the length of the microsomal incubation. After 2 h, N-(2-chloroethyl)-N-[2-(guaninyl)ethyl]amine was the main product but after 6 h N-(2-hydroxyethyl)-N-[2-(7-guaninyl)ethyl]amine was most abundant, and at this time the cross-linked product represented 12% of the total adducts. The adducts in DNA depurinated readily and after 24 h at pH 7.0 and 37 degrees C 70% of them had been liberated. The rate of depurination was decreased in the presence of 0.5 N NaCl. After short-term depurination in 0.1 N HCl at 25 degrees C the primary alkylating species was phosphoramide mustard rather than nornitrogen mustard. In in vivo studies mice were given injections i.p. of 100 microCi of cyclophosphamide. Maximal levels of radioactivity had been incorporated into DNA between 2-7 h after injection; the specific activity of DNA from the kidney and lung exceeded that from the liver. While the level of radioactivity found in kidney DNA was rapidly reduced the rate of fall was lower in the lung. Between 24 and 72 h the specific activity of lung DNA exceeded that of kidney and liver DNA by a factor of 3:8. Lung is the principal target tissue for tumor formation in mice after an i.p. injection.     

DNA damage and cytotoxicity in L1210 cells by ellipticine and a structural analogue, N-2-(diethylaminoethyl)-9-hydroxyellipticinium chloride.

N-2-(Diethylaminoethyl)-9-hydroxyellipticinium chloride (DHE) is a structural analogue of ellipticine that is currently a leading compound for clinical trials. We have investigated the mechanism of DNA damage by this compound in murine L1210 leukemia cells using the method of alkaline elution. Although DHE was about 100-fold more cytotoxic than ellipticine, this increased cytotoxicity was not accompanied by greater amounts of DNA strand breakage or protein-DNA cross-linking. The single strand breaks caused by both compounds were protein associated and could be accounted for by the presence of double strand breaks. DNA damage by the compounds therefore was consistent with topoisomerase II inhibition. Unlike DHE, 80% of the DNA damage elicited by ellipticine was repaired within 1 h after removal of drug. For DHE, 20-h incubations in drug-free media were required to obtain 70% repair of single strand DNA breaks. These data indicated that although both ellipticine and DHE may inhibit topoisomerase II, the type of DNA damage which resulted in topoisomerase II inhibition by DHE was much more persistent than the DNA damage elicited by ellipticine.     

Comparative pharmacokinetics of DNA lesion formation and removal following treatment of L1210 cells with nitrogen mustards

The kinetics of formation and removal of DNA interstrand crosslinks (ISC), DNA-protein crosslinks (DPC), and single strand breaks (SSB) by several nitrogen mustards were compared in order to determine the degree to which lesion selectivity may vary. The kinetic measurements using DNA alkaline elution methodology were obtained in mouse L1210 cells treated with mechlorethamine (HN2), phenylalanine mustard (L-PAM), uracil mustard (UM), 6-methyl-UM, and quinacrine mustard (QM). The ISC or DPC challenge delivered to cells was gauged on the basis of the kinetics as either total ISC or DPC produced, or as the area under the lesions versus time curve (AUC). By either measure (excepting QM), ISC correlated well with loss of colony survival, whereas DPC did not. The ISC/DPC ratio may therefore be a useful index of lesion selectivity. This ratio was significantly greater for 6-methyl-UM than for HN2. The ratio was also greater for L-PAM than for HN2 but only when gauged by AUC; this was attributable to an unusually slow rate for ISC removal in the case of L-PAM. The preferential reaction of UM at some 5'-GC-3' sites in purified DNA had suggested that UM might produce ISC with increased efficacy. UM, however, was somewhat less efficacious in ISC production than was 6-methyl-UM, which lacked selectivity for alkylation at 5'-GC-3'. QM was the only compound that produced detectable SSB, and the SSB were so numerous that ISC could not be quantitated.(ABSTRACT TRUNCATED AT 250 WORDS)     

Chromium (VI)-induced DNA damage in chick embryo liver and blood cells in vivo

Uptake of chromium (VI) and subsequent induction of DNA damagewas examined in liver and blood cells of 14-day chick embryosafter injection of sodium dichromate onto the inner shell membrane.Maximal loss of chromium from the inner shell membrane and distributionof chromium in liver, lung and blood was observed 2 h afterinjection. DNA strand breaks, interstrand cross-links and DNA-proteincross-links were measured using the alkaline elution technique.In chick embryo liver, chromium(VI) induced DNA cross-linksin the absence of strand breaks. Maximal DNA cross-linking wasdetected in the liver 8 h after injection. Little or no DNAdamage remained in the liver 10–24 h after injection.In contrast, chromium(VI) induced DNA strand breaks in the absenceof cross-links in chick embryo blood cells. Maximal DNA strandbreakage was observed in blood cells 8 h after injection. Highlevels of DNA strand breaks were present in blood cells even24 h after treatment. These intra-embryonic tissue differencesin chromium(VI)-induced DNA damage may be a result of the differencesin glutathione, cytochrome P-450, other pathways of chromium(VI)metabolism of chromatin organization which exist in liver andblood cells.     

Cyclophosphamide induced DNA strand breaks in mouse embryo cephalic tissue in vivo

Pregnant C3H mice were exposed to teratogenic doses of cyclophosphamide(CPA), on the 11th day after copulation. The effects of thisagent on embryonal cephalic DNA strand breaks were assessedbetween 3 and 40 h after drug administration. Administrationof 15, 30 and 60 mg CPA/kg body weight resulted in conversionof 23,30 and 44% of the DNA to the single-stranded form, respectively.No detectable DNA damage was evident 3 h after drug administration,but after 6 h significant DNA damage had occurred, reachinga maximum after 9 h. However, no evidence of DNA strand breakswas present at 22, 30 and 40 h after CPA treatment, suggestingthat these lesions had been repaired. These findings demonstratethat cephalic DNA damage Induced by CPA in the developing mouseembryo occurs in a time and concentration dependent manner,and provide some insight into the kinetics of formation andremoval of DNA strand breaks caused by CPA in vivo     

Correlations between intercalator-induced DNA strand breaks and sister chromatid exchanges, mutations, and cytotoxicity in Chinese hamster cells

Intercalator-induced DNA strand breaks in mammalian cells represent topoisomerase II:DNA complexes trapped by intercalators. These complexes are detected as protein-associated DNA single-strand breaks (SSB) and DNA double-strand breaks (DSB) by filter elution. Using Chinese hamster lung fibroblasts (V79 cells) that were treated for 30 min with various concentrations of 4'-(9-acridinylamino)methanesulfon-m-anisidide or 5-iminodaunorubicin, we measured DNA strand breaks (SSB and DSB), sister chromatid exchanges (SCE), mutations at the hypoxanthine:guanine phosphoribosyltransferase locus, and cell killing. Further, we correlated DNA strand breakage with the three other parameters. Both drugs induced SCE, mutations, and cell killing at concentrations which also produced reversible DNA strand breaks. While the quantity of DSB correlated with SCE, mutations, and cytotoxicity for both drugs, we found more SCE, mutations, and cytotoxicity per SSB in cells treated with 5-iminodaunorubicin than in those treated with 4'-(9-acridinylamino)methanesulfon-m-anisidide. These data show that the DSB (but not the SSB) induced by 4'-(9-acridinylamino)methanesulfon-m-anisidide and 5-iminodaunorubicin at DNA topoisomerase II binding sites correlated closely with SCE, mutations, and cell killing and could therefore be responsible for their production.