The role of human glutathione S-transferases (hGSTs) in the detoxification of the food-derived carcinogen metabolite N-acetoxy-PhIP, and the effect of a polymorphism in hGSTA1 on colorectal cancer risk.

Food-derived heterocyclic amines (HCAs), particularly 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhIP), are implicated in the etiology of human colorectal cancer (CRC) via a process of N-oxidation followed by O-acetylation or O-sulfation to form electrophilic metabolites that react with DNA. Glutathione S-transferases (GSTs) detoxify activated carcinogen metabolites by catalysis of their reaction with GSH. However, among HCAs, only N-acetoxy-PhIP has been shown to be a substrate for the GSTs. By using a competitive DNA-binding assay, we confirm that hGSTA1-1 is an efficient catalyst of the detoxification of N-acetoxy-PhIP. Further, we show that hGSTs A2-2, P1-1, M1-1, T1-1 and T2-2 appear to have low activity towards N-acetoxy-PhIP, and that hGSTs A4-4, M2-2, M4-4 and Z1-1 appear to have no activity towards N-acetoxy-PhIP. A genetic polymorphism in the 5'-regulatory sequence of hGSTA1 has been shown to correlate with the relative and absolute levels of expression of GSTA1/GSTA2 in human liver. Examination of hGSTA1 allele frequency in 100 Caucasian CRC patients and 226 Caucasian controls demonstrated a significant over-representation of the homozygous hGSTA1*B genotype among cases compared to controls (24.0 and 13.7%, respectively, P=0.04). This corresponds to an odds ratio for risk of CRC of 2.0 (95% CI 1.0-3.7) when comparing homozygous hGSTA1*B individuals with all other genotypes. Thus, individuals who are homozygous hGSTA1*B, and who would be predicted to have the lowest levels of hGSTA1 expression in their livers, appear to be at risk of developing CRC, possibly as a result of inefficient hepatic detoxification of N-acetoxy-PhIP.

Expression of fas ligand in metastatic prostatic carcinoma: suggestive of possible clonal expansion of subpopulation with metastatic potential.

Fas ligand (FasL) is a type II transmembrane tumor necrosis factor family protein, known to trigger apoptosis in cells that bear the FasL receptor, Fas. The authors found that normal prostate, benign hyperplasia, and most prostatic carcinoma cells at the primary site did not express FasL, whereas metastatic prostatic carcinoma cells in lymph nodes and bone marrow displayed almost uniform, immunohistochemically detectable, FasL expression. However, small foci of FasL-positive prostatic carcinoma cells amid a vast majority of FasL-negative tumor cells were noted at the primary sites in patients with distant metastases. Analysis of the FasL gene and its mRNA by polymerase chain reaction and reverse transcriptase-polymerase chain reaction, respectively, suggested that the expression of immunohistochemically detectable FasL in metastatic tumor cells was not due to mutation in the FasL gene with resulting overexpression. Further, FasL expression was detectable in the acinar epithelial cells of prostates with morphologic atrophic changes, suggesting that FasL also plays a role in the physiologic apoptosis process of noncancerous prostate. The current data suggest that a subpopulation of prostate carcinoma cells clonally expresses FasL, and this subpopulation may have metastatic potential. Evaluation of FasL expression in the primary tumor thus may provide a useful parameter for predicting metastatic potential of the tumor.

An allele-specific polymerase chain reaction method for the determination of the D85Y polymorphism in the human UDP-glucuronosyltransferase 2B15 gene in a case-control study of prostate cancer.

BACKGROUND: UDP-glucuronosyltransferase 2B15 (UGT2B15) catalyzes the inactivation of dihydrotestosterone (DHT) by forming the DHT-glucuronide and is expressed in normal and hyperplastic prostate tissue. Alterations in the activity of this enzyme could be a major contributing factor to the bioavailability of androgens in target tissue such as the prostate. METHODS: A polymorphism (D85 to Y85) has been identified in the UGT2B15 gene that results in a 50% reduction in enzyme activity. Previously, detection of the polymorphic nucleotide has required direct sequencing. We have developed and validated an allele-specific polymerase chain reaction (PCR) assay to identify the polymorphic base pair in the UGT2B15 gene. This assay was used to examine the distribution of the UGT2B15 polymorphism in a small case-control group (64 cases and 64 controls) from a prostate cancer study. RESULTS: The results of this analysis show that prostate cancer patients were significantly more likely to be homozygous for the lower activity D85 UGT2B15 allele than control individuals (41% versus 19%, respectively, odds ratio = 3.0 (95% confidence intervals 1.3-6.5)). CONCLUSIONS: These results suggest that individuals who are homozygous for the lower activity allele may be at increased risk for developing prostate cancer.

Cancer therapy and polymorphisms of cytochromes P450.

Cytochrome P450 (CYP) enzymes are important in the metabolism of some endogenous compounds, environmental and dietary xenobiotics and many drugs. Many of these enzymes have genetic polymorphisms that produce significant changes in metabolic activity, however the function of other polymorphisms is unknown. Genetic polymorphisms have important influences on variability in human pharmacokinetics, including intra-individual differences in drug toxicity, drug interactions and response to chemotherapy. Other factors that influence drug metabolism include differences in enzyme expression due to differences in age, gender, smoking status, exposure to dietary or environmental xenobiotics or co-administration of other drugs. In addition, some xenobiotics and drugs can directly inhibit or induce the activity of CYPs. All of these factors can produce differences in metabolic capacities among individuals which can produce toxicity in some patients and sub-effective dosing in others. Maximum clinical benefit will require a more complete understanding of the influence of these polymorphisms on allele function and their interaction with inducers and inhibitors of enzyme expression or activity. This effort will permit the pharmacogenetic screening of patients before the administration of drugs and result in the identification of individuals who are prone to adverse reactions or poor response, resulting in more effective individualized therapy.

Relationship of phenol sulfotransferase activity (SULT1A1) genotype to sulfotransferase phenotype in platelet cytosol.

Sulfation catalysed by human cytosolic sulfotransferases is generally considered to be a detoxification mechanism. Recently, it has been demonstrated that sulfation of heterocyclic aromatic amines by human phenol sulfotransferase (SULT1A1) can result in a DNA binding species. Therefore, sulfation capacity has the potential to influence chemical carcinogenesis in humans. To date, one genetic polymorphism (Arg213His) has been identified that is associated with reduced platelet sulfotransferase activity. In this study, data on age, race, gender, SULT1A1 genotype and platelet SULT1A1 activity were available for 279 individuals. A simple colorimetric phenotyping assay, in conjunction with genotyping, was employed to demonstrate a significant correlation (r = 0.23, P < 0.01) of SULT1A1 genotype and platelet sulfotransferase activity towards 2-naphthol, a marker substrate for this enzyme. There was also a difference in mean sulfotransferase activity based on gender (1.28 nmol/min/mg, females; 0.94 nmol/min/mg, males, P = 0.001). DNA binding studies using recombinant SULT1A1*1 and SULT1A1*2 revealed that SULT1A1*1 catalysed N-hydroxy-aminobiphenyl (N-OH-ABP) DNA adduct formation with substantially greater efficiency (5.4 versus 0.4 pmol bound/mg DNA/20 min) than the SULT1A1*2 variant. A similar pattern was observed with 2-hydroxyamino-1-methyl-6-phenylimidazo[4,5b]pyridine (N-OH-PhIP) (4.6 versus 1.8 pmol bound/mg DNA/20 min).

Glucuronidation of 2-hydroxyamino-1-methyl-6-phenylimidazo[4, 5-b]pyridine by human microsomal UDP-glucuronosyltransferases: identification of specific UGT1A family isoforms involved.

2-Amino-1-methyl-6-phenylimidazo[4,5-b]pyridine is a heterocyclic aromatic amine found in cooked meats and dietary exposure to PhIP has been implicated in the etiology of colon cancer in humans. PhIP, along with other heterocyclic aromatic amines, requires metabolic activation to exhibit genotoxic effects. PhIP is initially oxidized by the activity of cytochrome P4501A2 to produce 2-hydroxyamino-1-methyl-6-phenylimidazo[4,5-b]pyridine (N-OH-PhIP), a reaction occurring primarily in the liver. Whereas subsequent biotransformation of N-OH-PhIP via acetylation or sulfation can produce reactive electrophiles that readily bind to DNA, N-glucuronidation, catalyzed by UDP-glucuronosyltransferases (UGTs), functions as a detoxification mechanism. Although hepatic glucuronidation of N-OH-PhIP has been well characterized, the extrahepatic metabolism of this compound is poorly understood. Studies in our laboratory now indicate that the intestinal tract, and particularly the colon, is a significant site of glucuronidation of N-OH-PhIP. When assays were performed with microsomes prepared from the mucosa of the intestinal tract, it was determined that glucuronidation of N-OH-PhIP occurs throughout the intestinal tract, with activity approximately three times higher in the colon as that found in the upper intestine. Glucuronidation rates from colon microsomes showed considerable interindividual variability and incubation with N-OH-PhIP yielded two glucuronides. HPLC analysis showed that the predominant product formed is the N-OH-PhIP-N2-glucuronide, while the N3-glucuronide accounts for <10% of the total glucuronidation product. These rates approach the rates found in human liver microsomes, demonstrating the significance of extrahepatic metabolism of this food-borne carcinogen. Subsequent assays with human recombinant UGTs demonstrated that at least four human UGT isoforms, all from the UGT1A subfamily, are capable of catalyzing the biotransformation of N-OH-PhIP. Members of the UGT2B family available for this study did not conjugate N-OH-PhIP, although immunoinhibition studies in human liver microsomes strongly suggest the involvement of a UGT2B isoform(s) in this organ.

Comparison of DNA adduct levels associated with exogenous and endogenous exposures in human pancreas in relation to metabolic genotype.

Recently, we examined normal human pancreas tissue for DNA adducts derived from either exogenous chemical exposure and/or endogenous agents. In an effort to explain the different types and levels of DNA adducts formed in the context of individual susceptibility to cancer, we have focused on gene-environment interactions. Here, we report on the levels of hydrophobic aromatic amines (AAs), specifically those derived from 4-aminobiphenyl (ABP), and DNA adducts associated with oxidative stress in human pancreas. Although these adducts have been reported in several human tissues by different laboratories, a comparison of the levels of these adducts in the same tissue samples has not been performed. Using the same DNA, the genotypes were determined for N-acetyltransferase 1 (NAT1), the glutathione S-transferase (GST) M1, GSTP1, GSTT1, and NAD(P)H quinone reductase-1 (NQO1) as possible modulators of adduct levels because their gene products are involved in the detoxification of AAs, lipid peroxidation products and in redox cycling. These results indicate that ABP-DNA adducts, malondialdehyde-DNA adducts, and 8-oxo-2'-deoxyguanosine (8-oxo-dG) adducts are present at similar levels. Of the metabolic genotypes examined, the presence of ABP-DNA adducts was strongly associated with the putative slow NAT1*4/*4 genotype, suggesting a role for this pathway in ABP detoxification.

Comparison of DNA adduct levels associated with oxidative stress in human pancreas.

DNA adducts associated with oxidative stress are believed to involve the formation of endogenous reactive species generated by oxidative damage and lipid peroxidation. Although these adducts have been reported in several human tissues by different laboratories, a comparison of the levels of these adducts in the same tissue samples has not been carried out. In this study, we isolated DNA from the pancreas of 15 smokers and 15 non-smokers, and measured the levels of 1,N6-etheno(2'-deoxy)guanosine (edA), 3, N4-etheno(2'-deoxy)cytidine (edC), 8-oxo-2'-deoxyguanosine (8-oxo-dG), and pyrimido[1,2-alpha]purin-10(3H)-one (m1G). Using the same DNA, the glutathione S-transferase (GST) M1, GSTT1, and NAD(P)H quinone reductase-1 (NQO1) genotypes were determined in order to assess the role of their gene products in modulating adduct levels through their involvement in detoxification of lipid peroxidation products and redox cycling, respectively. The highest adduct levels observed were for m1G, followed by 8-oxo-dG, edA, and edC, but there were no differences in adduct levels between smokers and non-smokers and no correlation with the age, sex or body mass index of the subject. Moreover, there was no correlation in adduct levels between edA and eC, or between edA or edC and m1G or 8-oxo-dG. However, there was a significant correlation (r=0.76; p<0.01) between the levels of 8-oxo-dG and m1G in human pancreas DNA. Neither GSTM1 nor NQO1 genotypes were associated with differences in any of the adduct levels. Although the sample set was limited, the data suggest that endogenous DNA adduct formation in human pancreas is not clearly derived from cigarette smoking or from (NQO1)-mediated redox cycling. Further, it appears that neither GSTM1 nor GSTT1 appreciably protects against endogenous adduct formation. Together with the lack of correlation between m1G and edA or edC, these data indicate that the malondialdehyde derived from lipid peroxidation may not contribute significantly to m1G adduct formation. On the other hand, the apparent correlation between m1G and 8-oxo-dG and their comparable high levels are consistent with the hypothesis that m1G is formed primarily by reaction of DNA with a base propenal, which, like 8-oxo-dG, is thought to be derived from hydroxyl radical attack on the DNA.

Cloning of a mu-class glutathione S-transferase complementary DNA and characterization of its glucocorticoid inducibility in a smooth muscle tumor cell line.

A cDNA (designated hGSTYBX) encompassing the complete coding sequence of a hamster mu-class glutathione S-transferase (GST) subunit was cloned from a lambda ZAP library constructed with mRNA isolated from triamcinolone acetonide-treated smooth muscle tumor cells (DDT1 MF-2). Analysis of its nucleotide and deduced amino acid sequences demonstrated highest homology to the rat mu-class GST YB2 subunit. In proliferating subconfluent cells, in which constitutive expression of hGSTYBX mRNA was undetectable, glucocorticoid treatment induced hGSTYBX expression after a time lag of 3 h, and maximal induction occurred at 10 h. Nuclear run-on analysis showed that glucocorticoid induction resulted at least in part from an increased rate of transcription. Simultaneous treatment with glucocorticoid and cycloheximide prevented glucocorticoid induction, but had little effect on basal expression in confluent cells. In contrast, cycloheximide treatment 3 h after glucocorticoid treatment resulted in nearly full induction. These results taken together suggest that hGSTYBX induction may be a secondary glucocorticoid response.

Specific binding sites for prohormone atrial natriuretic peptides 1-30, 31-67 and 99-126.

Two peptides with vasodilatory properties consisting of amino acids 1-30 and 31-67 of the 98 a.a. N-terminal end of the prohormone of atrial natriuretic factor (proANF) which circulates in man were investigated to determine if they have specific binding sites on membranes isolated from DDT1 MF-2 smooth muscle cells. Smooth muscle is a known biologic target of these peptides. Competitive binding experiments revealed that proANFs (1-30), (31-67), and (99-126) (i.e., C-terminus; ANF) each had specific and separate binding sites. The dissociation constants for proANFs (1-30), (31-67), and (99-126) binding were 0.11 nM, 4 nM, and 7.3 nM, respectively. The binding site concentrations for proANFs (1-30), (31-67), and ANF were 2.57, 59.91 and 40 fmols/10(6) cells, respectively. The number of binding sites per cell were 1548, 36,087, and 24,090, respectively, for proANFs (1-30), (31-67), and (99-126) (ANF). Each peptide bound to DDT1 MF-2 membranes between 10(-8) to 10(-11) M but could only bind to the other peptides' receptors at concentrations of 10(-6) and 10(-7)M. These results suggest that proANF(1-30) and proANF(31-67) do not work through the ANF receptor but rather have their own separate and distinct receptors that mediate their biologic effects.

Glucocorticoid induction of beta-adrenergic receptors in the DDT1 MF-2 smooth muscle cell line involves synthesis of new receptor.

We have shown that glucocorticoids induce the appearance of beta 2-adrenergic receptors in membranes of the ductus deferens smooth muscle cell line (DDT1 MF-2). A concomitant increase in isoproterenol stimulated adenylate cyclase activity in the absence of exogenously applied GTP was observed as was a significantly increased (p less than 0.05) sensitivity of the adenylate cyclase system to exogenously applied GTP. However, no significant difference in the maximal velocity of adenylate cyclase between control and steroid treatment was measurable in the presence of sodium fluoride. Induction of beta 2-adrenergic receptors in DDT1 MF-2 cells is correlated with the presence of steroid receptors (androgen and glucocorticoid) in the cells since estrogens and progesterones had no effect on receptor levels. Finally, utilizing dense amino acid labeling of cells to measure old versus newly synthesized receptor sites by a density shift method, we have documented that glucocorticoid induction of beta 2-adrenergic receptors involves synthesis of new receptor protein.

Glucocorticoids induce a 29 000 Mr protein in DDT1 MF-2 smooth muscle cells but not in the DDT1 MF-2 GR glucocorticoid resistant variant.

We have demonstrated that glucocorticoids induce in DDT1 MF-2 cells by a glucocorticoid mediated mechanism the synthesis of a methionine-cysteine rich protein of 29 000 Mr (p29). Induction of p29 is not observed in DDT1 MF-2 GR glucocorticoid resistant variants which have only 7% of glucocorticoid receptor site per cell compared to wild type cells. Increased synthesis of p29 is specific to glucocorticoids since neither androgens, estrogens, progesterone nor the glucocorticoid antagonist dexamethasone mesylate are effective inducers. Stimulation of p29 synthesis in wild type cells is observed at 10(-10) M triamcinolone acetonide, reaching a maximum at a concentration of 1 X 10(-8) M. The induction of p29 is not a function of glucocorticoid arrest of DDT1 MF-2 cells since DDT1 MF-2 cells promoted to re-enter the cell cycle by 50 ng/ml platelet derived growth factor (PDGF) continue synthesis of p29. Finally, increased levels of p29 translation products are observed in cell free translation assays carried out utilizing poly A+ RNA transcripts isolated from glucocorticoid treated cells. These data suggest that the glucocorticoid stimulation of p29 synthesis is a transcriptional and/or RNA processing event controlled by glucocorticoid receptor complexes.

Autocrine regulation of growth: II. Glucocorticoids inhibit transcription of c-sis oncogene-specific RNA transcripts.

The ductus deferens smooth muscle tumor cell line (DDT1MF-2) expresses c-sis proto-oncogene poly A+ RNA transcripts which are thought to encode at least one subunit of the potent mitogen platelet derived growth factor (PDGF). We have previously demonstrated that glucocorticoids block DDT1MF-2 cells in G0/G1 stage of the cell cycle, and that exogenously applied PDGF reinitiates cell cycle progression. In this paper we document that glucocorticoids act to inhibit cell cycle progression by inhibiting the expression of c-sis poly A+ transcripts, which we suggest are encoding a PDGF-like molecule for DDT1MF-2 cells.