Induction of NF-kappa B DNA-binding activity during the G0-to-G1 transition in mouse fibroblasts.

A DNA-binding factor with properties of NF-kappa B and another similar activity are rapidly induced when growth-arrested BALB/c 3T3 cells are stimulated with serum growth factors. Induction of these DNA-binding activities is not inhibited by pretreatment of quiescent cells with the protein synthesis inhibitor cycloheximide. Interestingly, the major NF-kappa B-like activity is not detected in nuclear extracts of proliferating cells, and thus its expression appears to be limited to the G0-to-G1 transition in 3T3 cells. These DNA-binding activities bind many of the expected NF-kappa B target sequences, including elements in the class I major histocompatibility complex and human immunodeficiency virus enhancers, as well as a recently identified NF-kappa B binding site upstream of the c-myc gene. Furthermore, both the class I major histocompatibility complex and c-myc NF-kappa B binding sites confer inducibility on a minimal promoter in 3T3 cells stimulated with serum growth factors. The results demonstrate that NF-kappa B-like activities are immediate-early response proteins in 3T3 cells and suggest a role for these factors in the G0-to-G1 transition.

Glucose repression of the yeast ADH2 gene occurs through multiple mechanisms, including control of the protein synthesis of its transcriptional activator, ADR1.

The rate of ADH2 transcription increases dramatically when Saccharomyces cerevisiae cells are shifted from glucose to ethanol growth conditions. Since ADH2 expression under glucose growth conditions is strictly dependent on the dosage of the transcriptional activator ADR1, we investigated the possibility that regulation of the rate of ADR1 protein synthesis plays a role in controlling ADR1 activation of ADH2 transcription. We found that the rate of ADR1 protein synthesis increased 10- to 16-fold within 40 to 60 min after glucose depletion, coterminous with initiation of ADH2 transcription. Changes in ADR1 mRNA levels contributed only a twofold effect on ADR1 protein synthetic differences. The 510-nt untranslated ADR1 mRNA leader sequence was found to have no involvement in regulating the rate of ADR1 protein synthesis. In contrast, sequences internal to ADR1 coding region were determined to be necessary for controlling ADR1 translation. The ADR1c mutations which enhance ADR1 activity under glucose growth conditions did not affect ADR1 protein translation. ADR1 was also shown to be multiply phosphorylated in vivo under both ethanol and glucose growth conditions. Our results indicate that derepression of ADH2 occurs through multiple mechanisms involving the ADR1 regulatory protein.

Denitrosation as a determinant of nitrosocimetidine in vivo activity.

The widely used drug cimetidine (Tagamet) can be nitrosated in the presence of nitrite and under mild acid conditions to form a compound, nitrosocimetidine (NC), which has a chemical structure very similar to those of the mutagens and laboratory carcinogens N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) and methylnitrosourea (MNU). NC has given positive indications in several short-term tests for possible carcinogenic activity and is capable of methylating DNA in vitro and in cultured cells in a manner identical to that of MNNG and MNU. Nevertheless, NC has been found to be a weak carcinogen or a noncarcinogen and to be very poor at modifying DNA in vivo when administered p.o. We have found that NC, like MNNG, decomposes very rapidly when incubated with thiol compound in neutral pH buffer. Much of this decomposition is denitrosation. In the presence of excess reduced glutathione, about 35% of the degradation results in denitrosation to produce cimetidine, and in the presence of excess cysteine about 65% results in denitrosation to produce cimetidine. The compound also rapidly decomposes in whole blood isolated from rats; about 70% of this decomposition produces cimetidine. In solution with purified rat hemoglobin, approximately 90% of the NC degradation proceeds via a denitrosation pathway; hemoglobin cysteine residues have been implicated in the denitrosation reaction. In parallel experiments with MNNG, it has been found that, although a fraction of the decomposition of this agent in the presence of thiol compound, in isolated whole blood, and in solution with purified hemoglobin generates the denitrosated derivative, denitrosation is in the range of one-third to one-half of that found for NC. Denitrosation and degradation to form a methylating species appear to be the major NC and MNNG decomposition pathways in vitro. There is no indication that MNU degradation is sensitive to thiols, nor is the compound susceptible to denitrosation at neutral pH. Molar-equivalent doses of methyl group-radiolabeled NC, MNNG, and MNU were administered via the tail vein to groups of F344 rats, and the DNA methylation yields in lung, liver, kidney, and brain tissue were assessed. Of the organs considered, DNA methylation was greatest in the lungs of MNNG-treated animals, followed by kidney (25% of the lung value). Methylation of lung tissue DNA in MNU-treated animals was about 50% of that observed in the MNNG experiments; DNA methylation in the other organs was about equivalent to that found in the lung.(ABSTRACT TRUNCATED AT 400 WORDS)

Absence of protein kinase C in nuclei of EL4 mouse thymoma cells.

Since evidence indicates that phorbol ester-induced production of interleukin 2 requires transcription, we investigated the possibility that the phorbol ester receptor acts directly in the nuclei of EL4 thymoma cells. Using a procedure that minimized plasma membrane contamination (as measured by 5'-nucleotidase activity) and maintained the integrity of the double nuclear membrane, we were unable to detect specific binding of [3H]phorbol 12,13-dibutyrate in nuclei of unstimulated cells. Treatment of cells with phorbol 12,13-dibutyrate (100 nM, 37 degrees C) for up to 6 h did not cause appearance of phorbol ester binding capacity in nuclei (4 +/- 8% of homogenate value; 5'-nucleotidase activity = 10 +/- 3%) despite translocation of 40% of the cytosolic binding capacity to the plasma membrane fraction. The failure to detect nuclear binding capacity in treated cells was not due to occupation of nuclear sites with unlabeled ligand; effective exchange binding was demonstrated by recovery of total homogenate binding capacity in treated cells of 82 +/- 13% of that in untreated cells. Treatment of isolated nuclei with DNase to liberate DNA binding proteins also failed to reveal any nuclear phorbol ester binding capacity. Assay of nuclei for protein kinase C enzymatic activity gave similar negative results. These data argue strongly against a direct action of the intact phorbol ester receptor (or the phorbol ester binding fragment) in the transcriptional activation of interleukin 2 in EL4 cells but cannot rule out the possibility of a role for the catalytic fragment.

Rat, mouse and hamster isozyme specificity in the glutathione transferase-mediated denitrosation of nitrosoguanidinium compounds.

The major isozymes from affinity column-purified glutathione transferases isolated from Sprague-Dawley rat liver, kidney, and testis cytosol and also from BALB/c mouse and Syrian golden hamster liver cytosol have been resolved by chromatofocusing and tested for their ability to denitrosate and thus detoxicate the DNA-methylating agents and potential carcinogens nitrosocimetidine and 1,3-dimethyl-2-cyano-1-nitrosoguanidine (CyanoDMNG). The isozymes have been kinetically characterized using a battery of substrates permitting, in the rat and mouse cases, subunit composition identification. It has been found that the rat and mouse isozymes belonging to the mu class are uniquely and highly active in the denitrosation of nitrosocimetidine and CyanoDMNG. A specific set of hamster glutathione transferase isozymes were also found to be active in these reactions. We have identified the reaction products produced by the rat liver 3-4 isozyme activity. The glutathione transferase-mediated degradations of 1-methyl-2-nitro-1-nitrosoguanidine and CyanoDMNG generate one molecule of S-nitrosoglutathione per molecule of denitrosated guanidinium compound produced. In the CyanoDMNG incubations essentially all degradation was via denitrosation; nitrite and glutathione disulfide were minor products. In the 1-methyl-2-nitro-1-nitrosoguanidine case nonenzymic degradation of the nitroso compound in the presence of reduced glutathione was evident but little of this decomposition produced S-nitrosoglutathione or 1-methyl-2-nitroguanidine. In the presence of rat transferase 3-4 isozyme, glutathione-dependent 1-methyl-2-nitro-1-nitrosoguanidine degradation was shifted markedly towards denitrosation with the concomitant production of S-nitrosoglutathione.

Species differences in blood-mediated nitrosocimetidine denitrosation.

Nitrosocimetidine (NC) is the nitrosated derivative of cimetidine (Tagamet), a p.o. administered drug used widely in the treatment of stomach ulcers. NC is capable of methylating DNA in vitro and in cultured cells in a manner similar to that of the laboratory carcinogens 1-methyl-2-nitro-1-nitrosoguanidine and methylnitrosourea (MNU) and gives positive indications in short-term in vitro tests for genotoxicity, generally held to be prognostic of compound carcinogenic potential. Nevertheless NC has been found to be a weak or non-carcinogen in the rat and mouse model systems and to produce minimal levels of tissue DNA alkylation when dosed p.o. or i.v. to rats. The results from our earlier experiments (D. E. Jensen, Cancer Res., 43: 5258-5267, 1983) indicated that compound denitrosation is the primary fate of NC in the rat and suggested that denitrosation is the blood, mediated by hemoglobin sulfhydryl residues, is perhaps the major detoxification mechanism. We now report that whole blood and hemoglobin isolated from various mammalian species differ in their capacity for NC degradation rate enhancement and for compound denitrosation. The observed whole blood activity in the degradation reaction (rat greater than mouse/guinea pig greater than human/hamster) paralleled the hemoglobin activity. The NC half-life in isolated rat blood, 37 degrees C, was found to be about 2 min and in hamster or human blood 27 min. For reference, the MNU half-life in isolated blood is 8 min. Compound denitrosation accounted for at least 75% of the degradation in rat blood and 40 to 55% in human and hamster blood. Parallel NC denitrosation activity was found in the various hemoglobin preparations. The NC degradation rates in the presence of the several hemoglobin species were roughly proportional to the number of sulfhydryls on the hemoglobin tetramers available for reaction with p-chloromercuribenzoate and approximated the rates observed in solutions containing equivalent concentrations of L-cysteine. The percentage of total decomposition due to compound denitrosation in the presence of rat hemoglobin, 95%, was found to be unique relative to the L-cysteine-mediated reactions (about 35%) and the reactions studied over the pH range 6 through 10, the denitrosation process never accounted for more than 50% of the total degradation. Chemically blocking the sulfhydryls on human hemoglobin using iodoacetamide deleted the NC degradation rate enhancement. We found no evidence for nitrosylhemoglobin formation.(ABSTRACT TRUNCATED AT 400 WORDS)

Defective induction of Jun and Fos-related proteins in phorbol ester-resistant EL4 mouse thymoma cells.

Treatment of sensitive EL4 mouse thymoma cells with phorbol esters causes growth inhibition, adherence to substrate and production of several lymphokines including Interleukin 2. Resistant cells lack all of these responses. Since production of Interleukin 2 mRNA is dependent on protein synthesis, and the Interleukin 2 gene has a phorbol ester responsive element, we examined both cell lines for expression of the various Jun and Fos species which bind to this element. Phorbol ester induced c-fos, jun-B, and jun-D RNAs within 20 min in both cell lines. Fos-B was similarly induced in sensitive cells but induction was delayed and greatly enhanced in resistant cells. C-jun RNA induction was detected only in sensitive cells. Western analysis confirmed the induction of c-Jun and a Fos-related protein in sensitive cells only. Southern analysis indicated that both cell lines contain c-jun and fra-1 genes. These results suggest that defective induction of c-Jun and/or Fos-related proteins may contribute to the absence of phorbol ester-induced lymphokine production in resistant EL4 cells.

BAP1: a novel ubiquitin hydrolase which binds to the BRCA1 RING finger and enhances BRCA1-mediated cell growth suppression.

We have identified a novel protein, BAP1, which binds to the RING finger domain of the Breast/Ovarian Cancer Susceptibility Gene product, BRCA1. BAP1 is a nuclear-localized, ubiquitin carboxy-terminal hydrolase, suggesting that deubiquitinating enzymes may play a role in BRCA1 function. BAP1 binds to the wild-type BRCA1-RING finger, but not to germline mutants of the BRCA1-RING finger found in breast cancer kindreds. BAP1 and BRCA1 are temporally and spatially co-expressed during murine breast development and remodeling, and show overlapping patterns of subnuclear distribution. BAP1 resides on human chromosome 3p21.3; intragenic homozygous rearrangements and deletions of BAP1 have been found in lung carcinoma cell lines. BAP1 enhances BRCA1-mediated inhibition of breast cancer cell growth and is the first nuclear-localized ubiquitin carboxy-terminal hydrolase to be identified. BAP1 may be a new tumor suppressor gene which functions in the BRCA1 growth control pathway.

Reconstitution of the KRAB-KAP-1 repressor complex: a model system for defining the molecular anatomy of RING-B box-coiled-coil domain-mediated protein-protein interactions.

The KRAB domain is a 75 amino acid residue transcriptional repression module commonly found in eukaryotic zinc-finger proteins. KRAB-mediated gene silencing requires binding to the corepressor KAP-1. The KRAB:KAP-1 interaction requires the RING-B box-coiled coil (RBCC) domain of KAP-1, which is a widely distributed motif, hypothesized to be a protein-protein interface. Little is known about RBCC-mediated ligand binding and the role of the individual sub-domains in recognition and specificity. We have addressed these issues by reconstituting and characterizing the KRAB:KAP-1-RBCC interaction using purified components. Our results show that KRAB binding to KAP-1 is direct and specific, as the related RBCC domains from TIF1alpha and MID1 do not bind the KRAB domain. A combination of gel filtration, analytical ultracentrifugation, chemical cross-linking, non-denaturing gel electrophoresis, and site-directed mutagenesis techniques has revealed that the KAP-1-RBCC must oligomerize likely as a homo-trimer in order to bind the KRAB domain. The RING finger, B2 box, and coiled-coil region are required for oligomerization of KAP-1-RBCC and KRAB binding, as mutations in these domains concomitantly abolished these functions. KRAB domain binding stabilized the homo-oligomeric state of the KAP-1-RBCC as detected by chemical cross-linking and velocity sedimentation studies. Mutant KAP-1-RBCC molecules hetero-oligomerize with the wild-type KAP-1, but these complexes were inactive for KRAB binding, suggesting a potential dominant negative activity. Substitution of the coiled-coil region with heterologous dimerization, trimerization, or tetramerization domains failed to recapitulate KRAB domain binding. Chimeric KAP-1-RBCC proteins containing either the RING, RING-B box, or coiled-coil regions from MID1 also failed to bind the KRAB domain. The KAP-1-RBCC mediates a highly specific, direct interaction with the KRAB domain, and it appears to function as an integrated, possibly cooperative structural unit wherein each sub-domain contributes to oligomerization and/or ligand recognition. These observations provide the first principles for RBCC domain-mediated protein-protein interaction and have implications for identifying new ligands for RBCC domain proteins.

Fasting gut hormone levels change with modest weight loss in obese adolescents.

BACKGROUND: Gut hormones change with weight loss in adults but are not well studied in obese youth. OBJECTIVE: The primary aim was to evaluate how gut hormones and subjective appetite measure change with dietary weight loss in obese adolescents. METHODS: Participants were a subset of those taking part in the 'Eat Smart Study'. They were aged 10-17 years with body mass index (BMI) > 90th centile and were randomized to one of three groups: wait-listed control, structured reduced carbohydrate or structured low-fat dietary intervention for 12 weeks. Outcomes were fasting glucose, insulin, leptin, adiponectin, total amylin, acylated ghrelin, active glucagon-like peptide-1, glucose-dependent insulinotropic polypeptide (GIP), pancreatic polypeptide (PP) and total peptide tyrosine-tyrosine. Pre- and postprandial subjective sensations of appetite were assessed using visual analogue scales. RESULTS: Of 87 'Eat Smart' participants, 74 participated in this sub-study. The mean (standard deviation) BMI z-score was 2.1 (0.4) in the intervention groups at week 12 compared with 2.2 (0.4) in the control group. Fasting insulin (P = 0.05) and leptin (P = 0.03) levels decreased, while adiponectin levels increased (P = 0.05) in the intervention groups compared with control. The intervention groups were not significantly different from each other. A decrease in BMI z-score at week 12 was associated with decreased fasting insulin (P < 0.001), homeostatic model of assessment-insulin resistance (P < 0.001), leptin (P < 0.001), total amylin (P = 0.03), GIP (P = 0.01), PP (P = 0.02) and increased adiponectin (P < 0.001). There was no significant difference in appetite sensations. CONCLUSIONS: Modest weight loss in obese adolescents leads to changes in some adipokines and gut hormones that may favour weight regain.

Transcription from TATA-less promoters: dihydrofolate reductase as a model.

The promoters of many of the genes encoding the so-called "housekeeping" enzymes, oncogenes, growth factors and their receptors, and transcription factors, do not contain a canonical TATA box, which is known to direct transcription initiation. The mechanisms through which TATA-less promoters are regulated, and their transcription start sites selected, have begun to yield to investigation. Using the dihydrofolate reductase (DHFR) gene as a model, recent work on this group of genes has been reviewed. Control of transcription initiation and the role of "initiator" sequences, as well as their binding factors, in particular YY1 and E2F, are addressed. In the DHFR gene, neither the E2F site at the major initiation region nor the upstream Sp1 sites can alone produce wild-type initiation, despite the fact that each of these sites has certain properties of initiators. Many TATA-less genes are growth regulated, that is, transcription is increased in response to stimulation of cell proliferation. Although both Sp1 and E2F have been implicated in growth regulation, our recent studies suggest that Sp1 sites alone can confer a growth-dependent increase in transcription in the late G1 and early S phases of the cell cycle. The regulatory role of E2F, which binds to many TATA-less promoters and mediates viral stimulation of transcription, is also reviewed.

Conjugation of microsome generated and synthetic aflatoxin B1-8,9 epoxide and styrene oxide to glutathione by purified glutathione S-transferases from hamster and mouse livers.

Glutathione (GSH) conjugation of microsome-mediated and synthetic aflatoxin B1 (AFB1)-epoxide and styrene oxide has been studied with purified glutathione transferases (GSTs) from mouse and hamster liver cytosols. In hamster, with microsomally activated epoxide, the alpha group of GSTs show about 10-fold more activity than the mu group. With the synthetic AFB1 epoxide, the mu enzymes designated H3B and C show considerable activity although less than alpha, whereas H3A and D demonstrate similar ranges of activity as the alpha group. The pi class of GST could not be assayed due to its absence in the hamster liver. The mouse liver cytosols show 3.6-fold greater activity than hamster cytosol in microsome mediated assay system. The mouse alpha and mu enzymes have similar levels of activity in the microsome mediated system; this activity could not be determined with the pi GST due to shortage of this enzyme. The alpha group has 2- and 5-fold higher activity than mu and pi group of GSTs, respectively, with the synthetic epoxide of AFB1. With styrene oxide, the purified GSTs from hamster liver show total loss of activity whereas in the mouse alpha, mu and pi classes of GSTs have similar range of activity as the cytosol. The role of alpha and mu isozymes of GST in rendering these animals resistant to hepatocarcinogenecity is suggested.

Glutathione conjugation of microsome-mediated and synthetic aflatoxin B1-8,9-oxide by purified glutathione S-transferases from rats.

Glutathione (GSH) conjugation of microsome-mediated and synthetic aflatoxin B1 (AFB1)-epoxide and styrene oxide has been investigated with purified GSH S-transferases (GSTs) from rats. Both styrene oxide and AFB1-epoxide were conjugated preferentially by millimicrons GSTs 3-3, 3-4 and 4-4 as compared to alpha GSTs 1-1, 1-2 and 2-2. The highest catalytic activity with styrene oxide conjugation was associated with GST 4-4. The highest catalytic activity with microsome-mediated AFB1-epoxide conjugation was observed with GST 3-3 whereas with the synthetic AFB1-epoxide conjugation was seen with GST 4-4. The catalytic activity of pi GST 7-7 was intermediate to millimicrons and alpha GSTs. It is suggested that GST 3-3 may play an important role in inactivation of AFB1-epoxide generated in vivo in the rat.

Quantitation of S-methylcysteine formed in O6-methylguanine-DNA:methyltransferase.

The O6-methylguanine-DNA:methyltransferase is known to transfer the methyl group from O6-methylguanine (O6-mG) in DNA to the cysteinyl residue of the methyl acceptor protein which is the methyltransferase itself. We developed a novel method to estimate the amount of S-methylcysteine formed in the acceptor protein, utilizing O6-[methyl-3H]methylguanine-containing DNA as the methyl donor. Following hydrolysis of the methyl-incorporated macromolecules in formic acid--HCl, S-[methyl-3H]methylcysteine is chromatographically isolated on a small column of Dowex-50(H+). Utilizing this method, we measured O6-mG DNA:methyltransferase activity in rat liver during neonatal development; the activity increases from 0.013 pmol methyl transferred/mg protein at 2 days postnatally to 0.06 pmol/mg at 8 weeks, the latter being equal to the adult liver activity.

Enzymic denitrosation of 1,3-dimethyl-2-cyano-1-nitrosoguanidine in rat liver cytosol and the fate of the immediate product S-nitrosoglutathione.

The tumorigenicity of certain N-nitrosoguanidinium compounds is limited, in rodents, by the propensity of these agents to be detoxified by denitrosation. Previous studies have revealed that rodent glutathione transferase isoenzymes are capable of catalyzing this process, generating exclusively the denitrosated guanidinium compound and S-nitrosoglutathione (GSNO). Experiments considering the denitrosation of 1,3-dimethyl-2-cyano-1-nitrosoguanidine (CyanoDMNG) in rat liver cytosol incubates are reported, with emphasis on the fate of GSNO. Incubates composed with equimolar CyanoDMNG and reduced glutathione (GSH) effected 100% denitrosation; the GSNO yield was less than expected as was the quantity of GSH consumed. When the anticipated 100% yield concentration of GSNO was applied to cytosol incubates, 20-40% of it rapidly disappeared. Nitrosated protein thiols accounted for 35% of the NO moiety released, nitrite ion 30%, and nitric oxide production was detectable. Concomitant with GSNO loss, GSH and oxidized glutathione (GSSG) were generated in yields similar to those detected in the CyanoDMNG/GSH incubates. Thus, the fate of GSNO in cytosol determines the yields of glutathione-based products, and the stoichiometry of the glutathione transferase reaction is demonstrated. In incubates composed with equimolar CyanoDMNG, GSH, and NADPH, denitrosation was again 100%, but GSNO yields were very low and residual GSH increased. Inclusion of NADPH in incubates containing the anticipated 100% yield concentration of GSNO resulted in rapid GSNO degradation, producing GSH and a detected but unidentified product; S-nitrosated protein, nitrite, and nitrate yields were minimal, nitric oxide production was abolished, and incubate response to a mercuric chloride/azo dye assay approached zero. The fate of the NO moiety consequent to this GSNO catabolism is presently unknown.

Denitrosation of 1,3-dimethyl-2-cyano-1-nitrosoguanidine in rat primary hepatocyte cultures.

N-Nitrosoguanidines are potential carcinogens. However, the toxicity of these agents is attenuated significantly in laboratory rodents by processes that remove the nitroso group to generate the relatively innocuous parent guanidinium compound. The denitrosation of 1,3-dimethyl-2-cyano-1-nitrosoguanidine (CyanoDMNG) mediated by rat hepatocytes in primary culture was investigated. At concentrations < or = 200 microM, applied CyanoDMNG was converted efficiently to 1,3-dimethyl-2-cyanoguanidine (CyanoDMG). In trials using 50 microM CyanoDMNG (5 mL dosing solutions), it was demonstrated that hepatocytes are capable of denitrosating a 40 microM concentration of the applied compound with little change in the total or oxidized glutathione levels. The process was inhibited by coincidently applied ethacrynic acid, a glutathione transferase inhibitor. Reduction of hepatocyte glutathione to 20% of control levels by buthionine sulfoximine pretreatment had little effect on CyanoDMG production; total depletion of cytosolic glutathione by diethyl maleate pretreatment arrested CyanoDMNG processing. Hepatocyte-mediated CyanoDMNG denitrosation did not generate nitrite; nitrate yields were 10% relative to the CyanoDMG produced. The mercuric chloride/azo dye response of cultures lysed at times during 50 microM CyanoDMNG processing indicated intact CyanoDMNG as the only dye-sensitive material present. At applied CyanoDMNG > 100 microM, S-nitrosoglutathione (GSNO) yields were detectable; 4 microM GSNO was generated (concentration in 5 mL lysates) and maintained during 60 min at the 200 microM CyanoDMNG treatment level; this yield decayed if CyanoDMNG was withdrawn. Based on these and previous findings, it is hypothesized that CyanoDMNG is converted to CyanoDMG and GSNO by glutathione transferases and that GSNO is catabolized to eventually regenerate reduced glutathione. The fate of most of the NO moiety released remains to be determined.

Effect of glutathione modulation using buthionine sulfoximine on DNA methylation by dimethylnitrosamine in the rat.

An in vivo study was carried out in order to determine whether glutathione (GSH) might serve as a scavenger for the supposed electrophilic methylating fragment derived from dimethylnitrosamine (DMN) and thus function to decrease the degree of cellular macromolecule interaction, estimated by measuring the DNA methylation yield. After a 4-hr pretreatment with DL-buthionine-SR-sulfoximine (BSO), a specific inhibitor of GSH synthesis, male Sprague-Dawley rats were dosed with radiolabeled DMN (250 micrograms/kg). Four hours later the animals were killed and the livers and kidneys were excised. The DNA isolated from these organs was hydrolyzed in mild acid, and the liberated purines were quantified utilizing HPLC and liquid scintillation counting. The 70-75% GSH depletion in the liver and kidney resulting from BSO pretreatment did not have any significant effect on the degree of DNA methylation as assessed by the 7-methylguanine/guanine yield. In control experiments we found that DMN doses greater than 1 mg/kg had a marked effect on liver and kidney GSH levels after 4 hr.

Modifications of circular DNA by photoalkylation.

The effects of photoalkylation on superhelical PM2 DNA were examined. The chief product was 8-(2-hydroxy-2-propyl)guanine, formed exclusively in sequences of alternating purines and pyrimidines. Other purine damages included 8-(2-hydroxy-2-propyl)adenine and smaller quantities of two uncharacterized adenine products. DNA strand breaks were formed with increasing irradiation. A small quantity of thymine-containing photodimers was formed. Photoalkylation of poly(dG-dC):poly(dG-dC) reduced the concentration of salt required to effect inversion of the circular dichroic spectrum. This suggests that photoalkylation induces the transition of poly(dG-dC):poly(dG-dC) from the right-handed B form of DNA to the left-handed Z form.

Evidence for metabolism of N-nitrosoproline.

The metabolism of nitrosoproline (NPRO) was re-investigated in uni- and bilaterally nephrectomized rats that have reduced or absent ability to excrete urine. About 1% of the administered radioactivity from L-[U-14C]-NPRO appeared as 14CO2 in the expired air and the production of 14CO2 was time-dependent over a period of 23 h. As compared with sham-operation, uni- or bilateral nephrectomy did not significantly increase the amount of NPRO metabolism, though urinary excretion of radioactivity was decreased in the unilaterally nephrectomized animals. In microsome-mediated and in vitro enzyme-free (Udenfriend-hydroxylating) systems covalent binding of [2,3,4,5-3H]NPRO to exogenous calf thymus DNA was demonstrated. The above findings confirm that in vivo metabolism of NPRO is possible, albeit, to a very small extent.