Jeffrey M. Voigt

Expression of a vitamin D-regulated gene (VDUP-1) in untreated-and MNU-treated rat mammary tissue

Previous studies showed that the expression of an mRNA corresponding to VDUP-1 was decreased within MNU-induced rat mammary tumors. RNA from mammary tissue was DNase treated and reverse transcribed and the resulting cDNA was amplified using primers designed to amplify VDUP-1 (382 bp fragment) and glyceraldehyde-6-phosphate dehydrogenase (GAPDH) (416 bp fragment). Analysis of mammary cDNA derived from untreated or MNU-treated rats indicated that VDUP-1 expression within tumor tissue was significantly decreased, a finding which agrees with previous Northern blotting experiments. The differential expression was confirmed in tissue sections using an antisense VDUP-1 riboprobe for in situ hybridization studies which demonstrated that VDUP-1 staining in all cell types within tumor tissue was greatly decreased. VDUP-1 mRNA was expressed to a greater extent within epithelial cells and to a much lesser extent within stromal cells, including endothelial cells, in untreated mammary tissue. A significant decrease in VDUP-1 expression was detected as early as six weeks after MNU treatment, before tumors had formed. Bilateral ovariectomy did not alter VDUP-1 expression in untreated mammary tissue and ovariectomy prior to MNU treatment prevented tumor formation, as well as the associated decrease in VDUP-1 expression. The relative expression of VDUP-1 was higher in lung tissue than in adrenal, heart, kidney, liver, mammary, muscle, and ovary. Treatment of a cell line derived from an MNU-induced rat mammary tumor (MNU cells) with 1,25-dihydroxyvitamin D3 resulted in a significant increase in VDUP-1 expression and also inhibited cell growth in the absence of serum. The data are consistent with a role for VDUP-1 in mediating the inhibitory effects of 1,25-dihydroxyvitamin D3 on tumor cell growth.

Alteration of gene expression in rat mammary tumors induced by N‐methyl‐N‐nitrosourea

Rodents are susceptible to the effects of chemical carcinogens and have been widely used in the study of mammary‐gland carcinogenesis. However, little information is available regarding specific phenotypic changes that occur during mammary‐gland carcinogenesis. In this study, subtraction hybridization was used to identify specific genes whose expression in N‐methyl‐N‐nitrosourea (MNU)‐induced rat mammary tumors had been altered. mRNA isolated from normal rat mammary tissue and tumors induced by treatment of 50‐d‐old female rats with MNU (50 mg/kg) was used to produce normal and tumor cDNA libraries. Total inserts prepared from each cDNA library were used to produce a subtracted tumor‐normal probe. Differential screening of the tumor library with the subtracted probe and normal cDNA yielded 20 clones that appeared to be differentially expressed. Northern analysis of mRNA isolated from normal mammary tissue and tumor tissue confirmed that four of these clones were differentially expressed. The expression of clones 4 and 15 was greatly increased (13‐fold and tenfold, respectively) in most MNU‐induced mammary tumors, whereas the expression of clones 10 and 27 was decreased (13‐fold and fourfold, respectively). Sequence analysis revealed that clones 15 and 27 were highly homologous to calcyclin and a cDNA isolated from HL‐60 cells, respectively. The differential expression of clones 4 and 10 was due to the presence within these clones of retroviral sequences and a fragment of transferrin, respectively. These clones may represent markers useful for studying the development of MNU‐induced mammary‐gland neoplasias.

Inhibition of adrenal cytochromes P450 by 1-aminobenzotriazole in vitro. Selectivity for xenobiotic metabolism.

Studies were done to determine the effects of a P450 suicide inhibitor, 1-aminobenzotriazole (ABT), on adrenal steroid and xenobiotic metabolism. Incubation of guinea pig adrenal microsomes with ABT plus an NADPH-generating system caused a time-dependent decline in total P450 concentrations. The maximal decrease in P450 levels was approximately 35% and was accompanied by an equimolar decrease in heme content. Western blot analyses indicated that ABT had no effect on P450 apoprotein levels. Benzphetamine (BZ) N-demethylase and benzo[a]pyrene (BP) hydroxylase activities were inhibited almost completely by microsomal incubations with ABT. In contrast, neither steroid 17 alpha-hydroxylase nor 21-hydroxylase activity was affected by ABT. The steroid-induced type I spectral change in adrenal microsomes also was not affected by ABT, whereas that induced by BZ was eliminated. Similar studies with adrenal mitochondria indicated that ABT had no effect on mitochondrial P450 concentrations or on mitochondrial steroid metabolism. The results demonstrate that the in vitro actions of ABT on adrenal cytochromes P450 are highly selective for those isozymes that catalyze xenobiotic metabolism. Therefore, ABT should serve as a useful probe for further characterization of adrenal xenobiotic-metabolizing P450 isozymes.

Mitogenic responses of rat nasal epithelium to hexamethylphosphoramide inhalation exposure

Hexamethylphosphoramide (HMPA) is a rat nasal carcinogen that induces squamous cell carcinomas in the anterior portions of the nasal cavity following chronic inhalation exposures as low as 50 ppb. These tumors may arise as a result of P-450-mediated release of formaldehyde (HCHO), a known rat nasal carcinogen. The goal of this research was to investigate early responses of the nasal epithelium to inhaled HMPA. Rats were exposed nose-only to approximately 3 ppm HMPA for 6 h, and killed 18, 48, 96 or 144 h post-exposure. In a separate study, rats were exposed nose-only for 6 h for 1, 2, 3, or 5 consecutive days and killed 18 or 96 h post-exposure. With both single and repeated doses of HMPA, there was no evidence of cytotoxicity in the anterior nose. Olfactory degeneration and necrosis of the dorsal meatus, Bowmans glands and tips of the ethmoid turbinates increased in severity with repeated exposures to HMPA. Cell proliferation was assessed in levels of nasal tissue that included regions of squamous, respiratory, transitional and olfactory epithelium. Regional induction of cell proliferation was measured by BrdU incorporation, and reported as the number of labeled cells/mm basement membrane. At 18 h after a single exposure, there was an increase in cell proliferation in squamous epithelium, which returned to control levels within 48 h. A transitory increase in cell proliferation was observed regions of respiratory and transitional epithelium, although the response of each tissue, in terms of magnitude and peak time of response post-exposure, also differed. Along the dorsal meatus in Level 9, olfactory labeling initially decreased, returned to control levels by 96 h, but again declined at 144 h post-exposure. In repeat dose studies, the squamous epithelium response was variable 18 h post-exposure. For respiratory and transitional epithelium, increased cell proliferation 18 h post-exposure was correlated with increased dose (exposure) of HMPA. Cell proliferation responses following two or more exposures returned to near control levels within 96 h post-exposure. In conclusion, HMPA induced cell proliferation, but not cytotoxicity, in the anterior nose at approximately 3 ppm. These data suggest that HMPA induces proliferative, perhaps mitogenic, responses in the nasal epithelium, and this response may facilitate the fixation of low level genetic damage induced by liberated HCHO.

LOCALIZATION OF CYP2D16 IN THE GUINEA PIG ADRENAL CORTEX BY IMMUNOHISTOCHEMISTRY AND IN SITU HYBRIDIZATION

Recent reports indicate that the cytochrome P450 isozyme, CYP2D16, is expressed at high levels in the inner regions of the guinea pig adrenal cortex and may contribute to xenobiotic and/or steroid metabolism in the gland. In the present studies, immunohistochemical and in situ hybridization techniques were employed to definitively establish the localization of CYP2D16 within the adrenal cortex. In male guinea pigs of various ages, CYP2D16 protein and mRNA were highly localized to the zona reticularis (ZR); none was detectable in the zona fasciculata (ZF), zona glomerulosa (ZG) or the medulla. In contrast, the steroidogenic P450 isozyme, CYP17, was distributed throughout the ZF and ZR. From the earliest stages of development of the ZR, CYP2D16 staining was intense. As guinea pigs aged, the ZR progressively enlarged and comprised a proportionately greater amount of the cortex. At all ages, CYP2D16 was uniformly distributed throughout only the ZR. Coinciding with the age-related growth of the ZR and increase in adrenal CYP2D16 content was an increase in adrenal xenobiotic-metabolizing activity. The results establish that CYP2D16 has an intraadrenal localization that is unique among P450 isozymes, suggesting novel regulatory mechanisms and indicating that CYP2D16 may serve as a specific marker for ZR cells. The increase in CYP2D16 expression with age probably accounts for increasing levels of xenobiotic metabolism and may also contribute to an increase in intraadrenal cortisol degradation in older animals.

Inhibition of adrenal steroid metabolism by administration of 1-aminobenzotriazole to guinea pigs.

Prior in vitro investigations demonstrated that the P450 suicide substrate, 1-aminobenzotriazole (ABT), was a potent inhibitor of xenobiotic metabolism but had no effect on steroidogenic enzymes in the guinea pig adrenal cortex. Studies were done to determine if ABT administration of guinea pigs in vivo also selectively inhibited adrenal xenobiotic metabolism. At single doses of 25 or 50 mg/kg, ABT effected rapid decreases in spectrally detectable adrenal P450 concentrations. The higher dose caused approx. 75% decreases in microsomal and mitochondrial P450 levels within 2 h. The decreases in P450 were sustained for 24 h but concentrations returned to control levels within 72 h. Accompanying the ABT-induced decreases in adrenal P450 content were proportionately similar decreases in P450-mediated xenobiotic and steroid metabolism. Microsomal benzo(a)pyrene hydroxylase, benzphetamine N-demethylase, 17 alpha-hydroxylase and 21-hydroxylase activities were decreased to 20-25% of control values by the higher dose of ABT. Mitochondrial 11 beta-hydroxylase and cholesterol sidechain cleavage activities were similarly diminished by ABT treatment. Adrenal 3 beta-hydroxysteroid dehydrogenase activity, by contrast, was not affected by ABT, indicating specificity for P450-catalyzed reactions. The results demonstrate that ABT in vivo is a non-selective inhibitor of adrenal steroid- and xenobiotic-metabolizing P450 isozymes. The absence of ABT effects on steroid metabolism in vitro suggests that an extra-adrenal metabolite may mediate the in vivo inhibition of steroidogenesis.

Strain differences in adrenal microsomal steroid metabolism in guinea pigs

We recently reported that CYP2D16, a xenobiotic-metabolizing P450 isozyme, was expressed at higher levels in adrenal microsomes from inbred Strain 13 guinea pigs than in those from outbred English Short Hair (ESH) animals. Studies were done to determine if there also were strain differences in adrenal microsomal steroid metabolism. In both inner (zona reticularis) and outer (zona fasciculata plus zona glomerulosa) zone preparations of the adrenal cortex, 21-hydroxylase activities were greater in microsomes from ESH than from Strain 13 guinea pigs. By contrast, 17alpha-hydroxylase activities were similar in the two strains. In both strains, 21-hydroxylase activities were greater in inner than outer zone microsomes, but the opposite was found for 17alpha-hydroxylase activities (outer>inner). Northern and Western analyses revealed higher levels of CYP21 mRNA and protein in adrenals from ESH than Strain 13 guinea pigs, but there were no strain differences in CYP17 mRNA or protein concentrations. Despite the zonal differences in adrenal 17alpha-hydroxylase and 21-hydroxylase activities, CYP17 and CYP21 mRNA and protein levels were similar in the inner and outer zones within each strain of guinea pig. The results demonstrate strain differences in microsomal steroid metabolism that are explained by differences in CYP21 expression. By contrast, the zonal differences in steroid hydroxylase activities may be attributable to post-translational mechanisms.