Correlation of nitrosourea murine bone marrow toxicity with deoxyribonucleic acid alkylation and chromatin binding sites

All of the clinically available nitrosourea antitumor agents produce serious treatment-limiting bone marrow toxicity. A reduction in this toxicity can be achieved by attaching the chloroethylnitrosourea cytotoxic group to C2 (chlorozotocin) or C1 (1-(2-chloroethyl)-3-(β-d-glucopyranosyl)-1-nitrosourea, GANU) of glucose. Both glucose analogs are less myelotoxic in mice than 1-(2-chloroethyl)-3-cyclohepyl-1-nitrosourea (CCNU) or 1-(4-amino-2-methylpyrimidin-5-yl)methyl-3-(2-chloroethyl)-3-nitrosourea (ACNU), while retaining comparable antitumor activity against the murine L121o leukemia. To define the nuclear mechanisms for this reduced myelotoxicity, alkylation of L1210 and murine bone marrow DNA was quantitated. With the use of the endonucleases micrococcal nuclease and DNase I, the sites of alkylation within the chromatin substructure were determined. Experiments were performed on L1210 leukemia or bone marrow cells that had been incubated in vitro for 2 hr with 0.1 mM [¹⁴C]chloroethyl drug. The quantitative alkylation of DNA by GANU was 1.3-fold greater in L1210, as compared to bone marrow, cells. This ratio of DNA alkylation is comparable to the 1.3 ratio we previously reported for chlorozotocin [L. C. Panasci, D. Green and P. S. Schein, J. clin. Invest.64, 1103 (1979)]. In contrast, the ratio of alkylation (L1210: bone marrow DNA) for the myelotoxic ACNU was 0.66, similar to 0.59 for CCNU. Nuclease digestion experiments demonstrated that chlorozotocin and GANU preferentially alkylated internucleosomal linker regions of bone marrow chromatin, while nucleosome core particles were the preferred targets of CCNU and ACNU. The reduced myelotoxicity of chlorozotocin and GANU may be correlated with the advantageous ratio of L1210: bone marrow DNA alkylation and preferential alkylation of internucleosomal regions of bone marrow chromatin.     

Inhibition of intracellular esterases by antitumour chloroethylnitrosoureas. Measurement by flow cytometry and correlation with molecular carbamoylation activity

Antitumour chloroethylnitrosoureas (Cnus) decompose in physiological conditions yielding alkylating species and organic isocyanates. While antitumour activity is mainly attributed to the alkylation of DNA, carbamoylation of intracellular proteins by isocyanates may also have pharmacological and toxicological relevance. We previously reported a novel dynamic flow cytoenzymological assay for esterase inhibition in intact murine cells by BCNU and related isocyanates, and proposed that this might form the basis of an assay for intracellular carbamoylation. We have now examined a wide range of Cnus, isocyanates, and alkylating agents for their ability to inhibit cellular esterases. BCNU, CCNU, their derived isocyanates, and the 4-OH metabolites of CCNU exhibited potent inhibitory activity (I50 values 5.5 x 10(-5)-7.3 x 10(-4) M). Chlorozotocin and GANU were relatively inactive (I50 much greater than 10(-2) M). ACNU, TCNU and the 2-OH metabolites of CCNU exhibited intermediate activity (I50 values 1.1 x 10(-3)-2.3 x 10(-2) M). Compounds not able to form isocyanates were essentially inactive. Poor membrane permeability was also implicated in the weak activity of chlorozotocin and GANU. There was overall a good correlation between esterase inhibition and chemical carbamoylating activity, but some particular differences were identified. We concluded that flow cytoenzymological assay appears to have the potential to provide useful measurement of intracellular protein carbamoylation by existing Cnus and novel derivatives, and also offers the advantage of cell subpopulation identification for in vivo evaluation of these agents.     

Chemical properties and biological effects of 2-haloethyl sulfonates

Data for the alkylating activities, DNA cross-linking activities, and proliferation-inhibitory activities toward cultured L1210 cells for twenty-four 2-haloethyl sulfonates are reported. Previously reported activities against P388 leukemia in vivo are also presented to permit correlation of in vitro and in vivo properties. Since these compounds are believed to be 2-haloethylating agents, their properties and effects were compared with those of chlorozotocin, which is a recognized 2-chloroethylating agent. 2-Chloroethyl chloromethanesulfonate, which was the most effective compound against P388 leukemia, had a moderate level of alkylating activity and a low level of cross-linking activity, but it was quite active in inhibiting proliferation of cultured L1210 cells. Although its alkylating activity was about the same as that of chlorozotocin, it caused much less cross-linking of DNA. The in vitro tests were useful for gaining information relating structure to the individual properties, but results obtained for one of the properties might not be predictive of the relative values obtained for other properties nor for in vivo activity against P388 leukemia. These results indicate that additional experiments to define the mechanism of action of these agents are needed.     

An analysis of 1-(2-chloroethyl)-1-nitrosourea activity at the cellular level

The effect of five different 1-(2-chloroethyl)-1-nitrosoureas on the growth of cultured P388 cells has been analyzed in terms of physical, chemical, and kinetic parameters that are related to the mechanism of action of this class of cancer chemotherapeutic agent. This study correlates structure with activity at the cellular level by using a dose function that is related to the amount of active species, the (2-chloroethyl)diazonium ion, that is formed during the period of exposure of cells to drug rather than to the initial drug dose. 1-(2-Chloroethyl)-1-nitrosourea analogues that rapidly enter the P388 cells are shown to have the same activity relative to the amount of active species formed. When analyzed in this way, activity is not influenced by the structure of the N-3 substituent, lipophilicity, or carbamoylating activity. The agents 1-(2-chloroethyl)-1-nitrosourea (CNU), 1-(2-chloroethyl)-3-(2,6-dioxo-3-piperidyl)-1-nitrosourea (PCNU), 1-(2-chloroethyl)-3-cyclohexyl-1-nitrosourea (CCNU), and 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU) all produce a 50% cell growth inhibition at 6 to 7 microM active species formed per cell volume. Chlorozotocin required a twofold higher effective dose to produce the same toxic effect. This decreased activity is attributed to the slow uptake of the water-soluble chlorozotocin into P388 and L1210 cells relative to the rate of chlorozotocin conversion to active species in medium. The yields to 2-chloroethanol from CNU, BCNU, and chlorozotocin were shown to be the same, indicating that these agents generate the same yield of alkylating intermediate at 37 degrees C and pH 7.4.     

A structure--activity study of seven new water soluble nitrosoureas.

The in vitro alkylating activity, carbamoylating activity, decomposition rates and octanol-water partition coefficients (Log P) of seven water soluble chloroethylnitrosourea antitumor agents and a reference lipid soluble analog were correlated with their biological activities in mice. The alkylating activity of each compound demonstrated a significant inverse linear correlation with both the decomposition rate in 0.1 M sodium phosphate buffer. pH7.4 (r = -0.92,P< 0.01), and the molar ld₁₀ dose (r = 0.87, P< 0.01). A direct relationship was found between the Log P values and both the alkylating activity (r = -0.86. P< 0.01) and the molar ld₁₀ dose (r = 0.77, P< 0.025). However, the addition of the variable. Log P, in multiple regression analysis did not contribute significantly to any of the direct correlations of chemical parameters with biological variables. In comparison, carbamoylating activity did not function as an independent variable for the relative myelotoxicity or lethality of each compound. All water soluble drugs except for chlorozotocin and 1-(2 chloroethyl)-3-(β-d-glucopyranosyl)-1-nitrosourea, the two analogs with glucose carriers, produced a significant reduction in circulating neutrophils at their respective ld₁₀ doses. There was no correlation between relative myelotoxicity and alkylating activity, carbamoylating activity or Log P. The glucose moiety appears to function as an independent variable for reducing nitrosourea cytotoxicity to bone marrow cells without significantly altering antitumor activity.     

Synthesis and biologic evaluation of major metabolites of N-(2-chloroethyl)-N'-cyclohexyl-N-nitrosourea.

N-(2-chloroethyl)-N'-(cis-4-hydroxycylohexyl)-N-nitrosourea, a major metabolite of N-(2-chloroethyl)-N'-cyclohexyl-N-nitrosourea (CCNU), and its trans isomer were prepared from the corresponding 4-aminocyclohexanols. A convenient and stereospecific precursor was found in 2-oxa-3-azabicyclo[2.2.2]oct-5-ene hydrochloride, hydrogenation giving pure cis-4-aminocyclohexanol hydrochloride. The metabolites were, at nontoxic levels, at least as active as CCNU in tests against murine leukemia L1210 implanted both intraperitoneally and intracerebrally and, on a weight basis, were more active and more toxic. These observations and previously reported metabolic studies suggest that the anticancer activity of CCNU is due primarily to its metabolites.     

Two glycine containing 2-chloroethylnitrosoureas--a comparative study on some physicochemical properties, in vivo antimelanomic effects and immunomodulatory properties.

Physicochemical properties such as alkylating and carbamoylating activity and in vivo antimelanomic effects against B16 melanoma of the spin labeled (nitroxyl free radical containing) glycine nitrosourea (SLCNUgly) and its nonlabeled analogue (ChCNUgly), synthesized in our laboratory are studied and compared to those of antitumour drug 3-cyclohexyl-1-(2-chloroethyl)-1-nitrosourea (CCNU). We have demonstrated that introducing of glycine moiety in the nitrosourea structure in practice does not affect either alkylating or carbamoylating activity. On the other hand replacement of cyclohexyl moiety in ChCNUgly structure with nitroxyl free radical leads to a decrease in carbamoylating activity and an increase in alkylating activity. Compound ChCNUgly showed in vivo a higher antimelanomic activity against B16 melanoma in comparison with CCNU and SLCNUgly. It completely inhibited B16 melanoma growth (TGI=100%) at a dose 64.0 mg/kg. Moreover, we established that joint i.p. application in normal mice of SLCNUgly plus a new immunostimulator (C3bgp) formerly isolated in our laboratory led to a 75% restoration in immune function with respect to antibody production measured by Jerne hemolytic plaque assay. In contrast, no immunostimulation was found after joint application of C3bgp plus ChCNUgly or CCNU at the same experimental conditions. Based on these preliminary results, a possibility for developing of new combination immunochemotherapy schemes for treatment of human cancers is discussed.     

Hydroxylation of 1-(2-chloroethyl)-3-cyclohexyl-1-nitrosourea.

Rat liver microsomal mixed function oxidase catalyzes the hydroxylation of the cyclohexyl moiety of 1-(2-chloroethyl)-3-cyclohexyl-1-nitrosourea (CCNU) to give at least five metabolites. When exposed to alkaline pH at 100° CCNU and its metabolites quantitatively release their cyclohexyl moiety as cyclohexylamine and aminocyclohexanol respectively. The N-(2,4-dinitrophenyl) derivatives of cyclohexylamine and aminocyclohexanols were separated by high pressure liquid chromatography. The metabolites in vitro and in vivo have been identified as trans-2-hydroxy CCNU, cis-3-hydroxy CCNU, trans-3-hydroxy CCNU, cis-4-hydroxy CCNU and trans-4-hydroxy CCNU. Ring hydroxylation axial to the 1-(2-chloroethyl)-1-nitrosourea group (cis-2-, trans-3-, cis-4-) is favored over equatorial attack (trans-2-, cis-3-, trans-4-). Pretreatment of rats with phenobarbital leads to an increased rate of hydroxylation and a change in the relative amounts of the hydroxylated products. The significance of hydroxylation in relation to the antitumor activity of CCNU is discussed.     

Spin labelled nitrosoureas and triazenes and their non-labelled clinically used analogues--a comparative study on their physicochemical properties and antimelanomic effects

Physicochemical properties, such as half life time (tau0.5), alkylating and carbamoylating activity and in vivo antimelanomic effects against B16 melanoma of spin labeled (containing nitroxyl free radical moiety) amino acid nitrosoureas, synthesized in our laboratory, have been studied and compared to those of the antitumor drug N'-cyclohexyl-N-(2-chloroethyl)-N-nitrosourea (lomustine, CCNU). We have shown that the introduction of amino acid moieties and the replacement of cyclohexylamine with nitroxyl moiety leads to a faster decomposition, higher alkylating, lower carbamoylating activity, better antimelanomic activity and lower general toxicity, when compared to those of CCNU. It was also established that spin labeled triazenes, previously synthesized by us, were more stable in phosphate saline than their nonlabeled analogue, 5-(3,3-dimethyltriazene-1-yl)-imidazole-4-carboxamide (dacarbazine, DTIC). A higher cytotoxicity to B16 melanoma cells than to YAC-1 and lymphocytes was demonstrated for all spin labeled triazenes, in comparison with DTIC. An assumption has been made to explain the lower general toxicity of the spin labeled nitrosoureas compared to that of CCNU. Based on the results presented, we accept that a new trend for synthesis of more selective and less toxic nitrosourea and triazene derivatives as potential antimelanomic drugs might be developed.     

In the search for new anticancer drugs. XXIII: Exploration of a predictive design for anticancer drugs of carbohydrates containing N-nitrosochloroethylamino, N-nitrosomethyl, and N-nitrosoaminoxyl components.

The spin-labeled glucose nitrosoureas 13-16, streptozotocin (18), chlorozotocin (31), streptozotocin analogues of galactosyl 24 and mannosyl 28, and their tetra-O-acetyl derivatives 25 and 29, MCNU (Cymerin, 34), and glucamine (21) were synthesized and evaluated in vivo for their anticancer activities against the murine lymphocytic leukemia P388. Compounds 13-16, 18, 24, 28, 31, and 34 possessed activities ranging from 33 to 603% increase in life span (%ILS), whereas 21, 25, and 29 were inactive (%ILS = 9 to 10). All CD2F1 male mice treated with the most active compounds (13, 14, and 34) at 20 mg/kg were alive after 30 days, whereas all mice treated with the clinical drug streptozotocin (18) and clinically tested chlorozotocin (31) succumbed. Compounds 13-16, 18, 31, and 34 were further evaluated for their antineoplastic activity against lymphoid leukemia L1210. Compounds 13 and 34 on day 60 exhibited %ILS values of 557 and 713, respectively, as compared with %ILS values of 646 and 713 for CCNU (1) and the spin-labeled SLCNU (3), respectively. The lipophilicities of 13-16, 18, 21, 24, 25, 28, 29, 31, and 34 were determined using EPR and/or UV methods. A predictive design pattern was observed, with the most active drug (34) possessing some hydrophobic property (log P = 1.24), followed by 13 (log P = 1.87) and 14 (log P = 1.81) as the more active drugs with higher hydrophobicity than 34. The clinical drugs streptozotocin (18) and chlorozotocin (31) were distinctly hydrophilic and less active. Finally, it was concluded that various scattered results of anticancer activity in the literature can be explained by a linear correlation of activities with lipophilicities.     

L-Chlorozotocin.

L-Chlorozotocin (2-[[[2-chloroethyl)nitrosoamino]carbonyl]amino]-2-deoxy-L-glucose) was synthesized in seven steps from L-arabinose for comparison with chlorozotocin, which is the D enantiomorph and an antineoplastic agent with clinical potential. Purification of the intermediate 2-amino-2-deoxy-L-glucose as the Schiff's base formed with 4-methoxybenzaldehyde ensured complete separation from the manno epimer. Comparative screening against leukemia L1210 with concurrent toxicity controls revealed no significant difference between D- and L-chlorozotocin in either activity or toxicity.     

Antineoplastic agents. 1. Synthesis and antineoplastic activities of chloroethyl- and methylnitrosourea analogues of thymidine

A new class of chloroethyl- and methylnitrosourea analogues of thymidine, 5a,b, 6, 10, and 11, has been synthesized from the corresponding amino nucleosides, 2 and 7. The 3'-chloroethyl and 3'-methyl derivatives, 10 and 11, inhibited L1210 cell growth in culture (ED50 = 1.5 and 1.0 micrometer, respectively) more effectively than 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU) (ED50 = 4 micrometer) and the 5'-nitrosourea analogues. Neither the alkylating nor the carbamoylating activities of these compounds correlated with their biological activity.     

pH‐dependent general base catalyzed activation rather than isocyanate liberation may explain the superior anticancer efficacy of laromustine compared to related 1,2‐bis(methylsulfonyl)‐1‐(2‐chloroethyl)hydrazine prodrugs

Laromustine (also known as cloretazine, onrigin, VNP40101M, 101M) is a prodrug of 90CE, a short‐lived chloroethylating agent with anticancer activity. The short half‐life of 90CE necessitates the use of latentiated prodrug forms for in vivo treatments. Alkylaminocarbonyl‐based prodrugs such as laromustine exhibit significantly superior in vivo activity in several murine tumor models compared to analogs utilizing acyl, and alkoxycarbonyl latentiating groups. The alkylaminocarbonyl prodrugs possess two exclusive characteristics: (i) They are primarily unmasked by spontaneous base catalyzed elimination; and (ii) they liberate a reactive carbamoylating species. Previous speculations as to the therapeutic superiority of laromustine have focused upon the inhibition of enzymes by carbamoylation. We have investigated the therapeutic interactions of analogs with segregated chloroethylating and carbamoylating activities (singly and in combination) in the in vivo murine L1210 leukemia model. The combined treatment with chloroethylating and carbamoylating prodrugs failed to result in any synergism and produced a reduction in the therapeutic efficacy compared to the chloroethylating prodrug alone. Evidence supporting an alternative explanation for the superior tumor selectivity of laromustine is presented that is centered upon the high pH sensitivity of its base catalyzed activation, and the more alkaline intracellular pH values commonly found within tumor cells.     

含硫亚硝基脲衍生物

本文报道一系列含硫亚硝基脲衍生物的合成、光谱学特征及对小鼠白血病L1210的作用。这些化合物都是CNC-半胱胺的衍生物,包括二硫化合物、2-氯乙基氨甲酸酯衍生物以及与羰基化合物环合而成的2,2-二取代的CNC-四氢噻唑。CNC-半胱胺及其二硫化合物、CNC-胱胺甲酰叠氮均有良好的抗L1210的作用;相应的氨甲酸酯衍生物和四氢噻唑衍生物的作用不明显。值得注意的是,2-甲基-2-乙氧羰甲基-3-CNC-四氢噻唑(15b)是一个例外,它对L1210有显著的抑制作用。     

Anti-tumour,toxicological and pharmacokinetic properties of a novel taurine-based nitrosourea (TCNU)

Summary A novel nitrosourea, 1-(2-chloroethyl)-3-[2-(dimethylaminosulfonyl) ethyl]-1-nitrosourea (TCNU) tauromustine, has been investigated in a broad anti-tumour screen and, in depth toxicology and initial pharmacokinetics carried out.TCNU and its two metabolites were found to exhibit equal or better oral efficacy than that of BCNU, CCNU, MeCCNU or chorozotocin against L1210 leukemia, Walker mammary carcinoma, Lewis Lung, Harding Passey melanoma and colon carcinoma C26. The toxicological profile of TCNU after acute and 3 months treatment was similar in mice and rats to that of CCNU, with the exception that, TCNU did not cause the chronic liver disturbances found for CCNU. In dogs treated for 6 weeks with TCNU leucopenia and thrombocytopenia were the major side effects. Parent TCNU was found in all dogs. The absorption was fast, the maximum level being reach after 25 mins and the mean absorption time was 22 mins. The mean half life was 16.1 mins after intravenous and 17.4 after oral administration. The combination of these factors make TCNU an interesting clinical candidate.     

New cysteamine (2-chloroethyl)nitrosoureas. Synthesis and preliminary antitumor results

Three chemical pathways were used for the synthesis of four new N'-(2-chloroethyl)-N-[2-(methylsulfinyl)ethyl]- and N'-(2-chloroethyl)-N-[2-(methylsulfonyl)ethyl]-N- or N'-nitrosoureas. These compounds are plasma metabolites of CNCC, a promising antineoplastic (2-chloroethyl)nitrosourea. Preliminary antitumor evaluation was performed against L1210 leukemia implanted intraperitoneally in mice. Among these compounds, two of them exhibited a greater antitumor activity compared to that of the parent mixture.     

Studies on the mechanism of resistance of selected murine tumors to l-alanosine

Sublines of P388 and L1210 leukemia were rendered resistant to l-alanosine [l-2-amino-3-(N-hydroxy-N-nitrosamino) propionic acid] and designated P388/LAL and L1210/LAL. Assessments were made of certain biochemical and pharmacological determinants of the sensitivity or resistance to l-alanosine of these sensitive and resistant lines. It was observed that the antibiotic strongly inhibited adenylosuccinate synthetase and DNA synthesis only in the parent or sensitive lines; moreover, after a therapeutic dose of the drug, the concentration of l-alanosyl-AICOR (l-alanosyl-5-amino-4-imidazole carboxylic acid ribonucleotide), the putative active anabolite of l-alanosine, was dramatically higher in these parent lines as compared with the resistant variants. Enzymologic studies established that, in P388/LAL, the specific activity of the enzyme SAICAR synthetase (5-amino-4-imidazole-N-succinocarboxamide ribonucleotide synthetase), which is believed to conjugate l-alanosine with the nascent purine AICOR (5-amino-4-imidazole carboxylic acid ribonucleotide), was depressed significantly; the same was not true for L1210/LAL. In both resistant lines, however, the enzymes of purine salvage were present at levels about 200 per cent higher than those measured in the native strains. These studies establish that resistance to l-alanosine is very likely pluricausal, but that the ability of susceptible cells to synthesize or retain l-alanosyl-AICOR is an element important to the process.     

Degradation and disposal of some antineoplastic drugs

Bulk quantities and pharmaceutical preparations of the antineoplastic drugs carmustine (BCNU), lomustine (CCNU), chlorozotocin, N-[2-chloroethyl]-N'-[2,6-dioxo-3-piperidinyl]-N-nitrosourea (PCNU), methyl CCNU, mechlorethamine, melphalan, chlorambucil, cyclophosphamide, ifosfamide, uracil mustard, and spiromustine may be degraded using nickel-aluminum alloy in KOH solution. The drugs are completely destroyed and only nonmutagenic reaction mixtures are produced. Destruction of cyclophosphamide in tablets requires refluxing in HCl before the nickel-aluminum alloy reduction. Streptozotocin, chlorambucil, and mechlorethamine may be degraded using an excess of saturated sodium bicarbonate solution. The nitrosourea drugs BCNU, CCNU, chlorozotocin, PCNU, methyl CCNU, and streptozotocin were also degraded using hydrogen bromide in glacial acetic acid. The drugs were completely destroyed but some of the reaction mixtures were mutagenic and the products were found to be, in some instances, the corresponding mutagenic, denitrosated compounds.     

Nitrosamine formation from interaction of isosorbide dinitrate and hydroxyzine HCl, a tertiary amine

The interaction of two drugs—isosorbide dinitrate (ISDN) and hydroxyzine hydrochloride (HZ), a tertiary amine—was studied in vitro, under conditions simulating those found in the stomach, to determine if nitrosamines are formed. Gas chromatography-mass spectrometry was used to monitor the latter compounds. We found that, in the presence of sodium nitrite, HZ undergoes oxidative cleavage and nitrosation, forming three nitrosamine compounds, N-(4-chlorophenyl)benzyl]-N′-nitro-sopiperazine (A), N′-[2-(2′-hydroxyethoxy)ethyl]-N′-nitrosopiperazine (B), and N, N′-dinitrosopiperazine (C). However, when ISDN (0.8 g) and HZ (2.0 g) were incubated together for 1 hr, only N-[α-(4-chlorophenyl)benzyl]-N′-nitrosopiperazine (A) was recovered. Although preparations of HZ contain (A) as an impurity, the quantity is trivial (0.5 ng/mg drug), and the bulk of the material detected is formed by interaction of ISDN with HZ. Because some individuals may ingest isosorbide dinitrate and hydroxyzine HCl, or analogous combinations, over a period of years, the risk posed by this type of drug interaction should be determined.     

Spin labeled antioxidants protect bacteria against the toxicity of alkylating antitumor drug CCNU

We have studied the toxic effect of the alkylating antitumor drug N'-cyclohexyl-N-(2-chloroethyl)-N-nitrosourea (lomustine, CCNU) on Escherichia coli (E. coli) and Staphylococcus aureus (S. aureus) strains, alone and in presence of oxygen radical-scavenging substances [Vitamin E, stable nitroxyl radical 2,2,6,6-tetramethylpiperidine-N-oxyl (TMPO), and spin labeled (nitroxyl free radical moiety containing) analogues of CCNU] and compared with that of the alkylating antitumor drug 5-(3,3-dimethyltriazene-1-yl)-imidazole-4-carboxamide (dacarbazine, DTIC). All spin labeled compounds tested were almost no toxic at doses of 50-500 microM/ml, whereas the alkylating antitumor drug CCNU showed toxicity in a dose dependent manner. Even low doses of spin labeled nitrosoureas provided protection against the toxicity caused by the antitumor drug CCNU alone. The lowest toxicity against E. coli and S. aureus were achieved when 500 microM/ml of CCNU was combined with 200 microM/ml of spin labeled nitrosourea N-[N'-(2-chloroethyl)-N'-nitrosocarbamoyl]-glycine amid of 2,2,6,6-tetramethyl-4-aminopiperidine-1-oxyl (SLCNUgly). A combination of TMPO with vitamin E completely abolished the toxicity of CCNU. Endogenous formation of oxygen radicals and their possible involvement in CCNU toxicity towards the bacteria strains tested have been also discussed.