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Query: UMLS:C0596263 (
carcinogenesis
)
64,820
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Characterization of enzymes mediating the formation of catecholestrogens (CE) by hamster kidney is of importance because of the proposed role of CE in renal cancer induced in this species by estrogens. We have reexamined the potential of hamster kidney to convert estradiol (E2) to 2- and 4-hydroxylated CE because of recent evidence of the limitations of assays used in previous studies, in particular in measuring 4-hydroxylation of estrogens. Under conditions optimized for NADPH-dependent activity, hamster kidney microsomes exhibited high levels of both E2-2- and E2-4-hydroxylase activities. Evidence that the two activities depend on different forms of cytochrome P-450 was obtained by the demonstration that 2- and 4-hydroxylation of E2 were affected differentially 1) by chronic treatment of hamsters with E2 and 2) by fadrozole hydrochloride, a selective cytochrome P-450 inhibitor. NADPH-dependent 2-hydroxylation of E2 from control and E2-treated hamsters, measured by a direct product isolation assay, was 1 order of magnitude higher (apparent maximum velocity, 24-32 and 6-12.5 pmol/mg protein.min in control and E2-treated hamsters, respectively) than that reported previously using radioenzymatic assays. NADPH-dependent 4-hydroxylation of E2 in controls approached and in E2-treated hamsters exceeded 2-hydroxylation of E2 (apparent maximum velocity, 17-21 and 7.5-19 pmol/mg protein.min in control and E2-treated hamsters, respectively). Thus, estrogen treatment reversed the ratios of NADPH-dependent E2-2-/4-hydroxylase activities by causing a much greater decline in 2- than 4-hydroxylation of E2 (P less than 0.007, by analysis of variance).
Fadrozole hydrochloride
caused a marked dose-dependent decrease in 2-hydroxylation of E2, in contrast to a small nondose-dependent inhibition of 4-hydroxylation. Under conditions optimized for peroxidatic organic hydroperoxide-dependent activity, hamster kidney microsomes generated 2- and 4-hydroxylated CE in similar amounts. The amounts of the two CE and, consequently, the ratios remained unaffected by estrogen treatment (1:0.9 and 1:1.0 in control and E2-treated hamsters, respectively). Thus, this study establishes that CE can be generated in the same tissue by three different pathways, i.e. NADPH-dependent E2-2-hydroxylase, NADPH-dependent E2-4-hydroxylase, and organic hydroperoxide-dependent E2-2/4-hydroxylase activities. We also show that these three activities can be regulated differentially and are, thus, probably mediated by different forms of cytochrome P-450. In hamster kidney, the potential to generate 4-hydroxylated CE metabolites with distinct properties could be a factor in this tissue's vulnerability to estrogen-induced
carcinogenesis
.
...
PMID:Elevated 4-hydroxylation of estradiol by hamster kidney microsomes: a potential pathway of metabolic activation of estrogens. 138 3
As part of an ongoing investigation of the role of metabolic activation of estrogens in the genesis of cancers such as estrogen-induced renal tumors in hamsters, we have 1) determined steroid-17 beta-oxidoreductase activity of microsomes and cytosol prepared from hamster kidney and liver; 2) compared the rates of 2-, 4-, and 16 alpha-hydroxylations of estrone by microsomes from hamster kidney and liver; and 3) determined the rates of inactivation of 2- and 4-hydroxyestrone by catechol-O-methyltransferase from hamster kidney and by purified enzyme. Microsomal steroid-17 beta-oxidoreductase activity in hamster kidney and liver was low and favored the conversion of estrone to estradiol. Cytosolic steroid-17 beta-oxidoreductase activity was only barely detectable in both liver and kidney. Using hepatic microsomes, the rate of 2-hydroxylation of estrone was comparable to that found previously using estradiol as substrate, whereas 4-hydroxylation of estrone was double that of estradiol. Using renal microsomes, the rates of 2- and 4-hydroxylation of estrone were 10- to 20-fold higher than those with estradiol as substrate, and the ratio of 2- to 4-hydroxylation was about 2:1.
Fadrozole hydrochloride
was an equally good inhibitor of rates of 2- and 4-hydroxylation of estrone (20 microM) by hepatic microsomes (IC50, approximately 25 microM). Corresponding IC50 values with renal microsomes were less than 2 microM, and 2-hydroxylation of estrone was inhibited by
Fadrozole hydrochloride
up to 15% more than 4-hydroxylation. Treatment of hamsters with estradiol for 2 months decreased rates of 2- and 4-hydroxylation of estrone by renal microsomes by approximately 95%. The rate of conversion of estrone to 16 alpha-hydroxyestrone by hepatic microsomes was 10-20% that of 2-hydroxylation. Renal microsomes catalyzed 16 alpha-hydroxylation of estrone at an even lower rate (approximately 5% of that of 2-hydroxylation). Rates of O-methylation of 2- and 4-hydroxyestrone by hamster kidney cytosol were comparable to those of 2- and 4-hydroxyestradiol. In conclusion, conversion of estrone to its catechol metabolites by microsomes of hamster kidney, a target organ of estrogen-induced
carcinogenesis
, is quantitatively more important than the conversion to 16 alpha-hydroxyestrone. The findings are consistent with the postulated role of catechol estrogens generated in situ in estrone-induced
carcinogenesis
.
...
PMID:Conversion of estrone to 2- and 4-hydroxyestrone by hamster kidney and liver microsomes: implications for the mechanism of estrogen-induced carcinogenesis. 795
