Characterization of the UDP-glucuronosyltransferase isoenzyme expressed in rat ovary and its regulation by gonadotropins.

Earlier studies have demonstrated that phenol UDP-glucuronosyltransferase (UGT) activity is up-regulated by pregnant mare's serum gonadotropin (PMSG) in rat ovary, but not liver. This phenomenon was investigated in more detail in the present study. Ovaries and livers of immature rats, rats synchronized with respect to their preovulatory and corpus luteal phases by treatment with PMSG, and mature rats hyperstimulated with PMSG were compared. Under all of these conditions, only one immunoreactive band of UGT, shown to be phenol UGT, was detected in the rat ovary. The effects of oestradiol, progesterone and/or human chorionic gonadotropin (hCG) on the level of phenol UGT in immature rat ovary were also examined. Partial up-regulation was caused by progesterone or oestradiol, together with hCG, whereas progesterone or oestradiol alone had no up-regulating effect. Follicle-stimulating hormone also seemed to be required for the up-regulation in ovaries enriched in corpus luteum. The present findings demonstrate that progesterone is involved in the regulation of phenol UGT in rat ovary by gonadotropins. Regulation by both progesterone and oestradiol was dependent on induction of ovulation and steroidogenesis by luteinizing hormone.

Effects of perfluorooctanoic acid--a potent peroxisome proliferator in rat--on Morris hepatoma 7800C1 cells, a rat cell line.

In this study, Morris hepatoma 7800C1 cells (from rat) were exposed to 500 microM perfluorooctanoic acid (PFOA) in the culture medium for 7 days. This treatment resulted in inductions of catalase, lauroyl-CoA oxidase (which catalyzes the first step in peroxisomal beta-oxidation) and of cytochrome P-450IVA (specialized for omega- and omega-1 hydroxylation of fatty acids). Northern blot analysis revealed that the level of mRNA for peroxisomal fatty acyl-CoA oxidase was enhanced in cells treated with PFOA. Inductions of the enzymes mentioned above are generally connected with peroxisome proliferation in vivo. This work also includes a comparison between the activities of catalase, lauroyl-CoA oxidase, DT-diaphorase and glutathione transferase in rat liver homogenate and 7800C1 cells in order to investigate to what extent this cell line differs from the situation in vivo. The findings suggest that the cells selectively lost most of their peroxisomes during transformation into a cell line and subsequent propagation. The control activities of catalase and lauroyl-CoA oxidase (marker enzymes for peroxisomes) were only about 2% of the corresponding enzyme activities in rat liver. In addition, a morphological study revealed that the frequency of peroxisomes in 7800C1 cells is very low. The control activity of glutathione transferase in 7800C1 cells was 11% of the corresponding activity in rat liver homogenate, whereas the level of DT-diaphorase was virtually the same in 7800C1 cells as in rat liver. Electron microscopic investigation of the control cultures revealed all signs of viable cells, with well-developed cell organelles. Treatment of 7800C1 cells with 500 microM PFOA has little effect on cellular morphology.

Further studies on the involvement of selenium in peroxisome proliferation in rat liver. Comparison of effects with clofibric acid and perfluorooctanoic acid and the pharmacokinetics of [14C]clofibrate.

Most effects of the peroxisome proliferator clofibrate on rat liver are marginal or absent in selenium (Se) deficiency. The purpose of the present study was to determine whether the uptake or distribution of clofibrate is altered by Se deficiency. Rats were fed a Se-adequate or -deficient diet for 10-11 weeks and then these same diets with 0.5% (w/w) clofibric acid (the direct acting hydrolysis product of clofibrate) or 0.02% (w/w) perfluorooctanoic acid (PFOA) for 10 days. Other groups of rats received radiolabeled clofibrate by intubation. Clofibric acid was an ineffective as clofibrate in producing effects (i.e. decreased body weight gain, increases in liver somatic index and protein content of the mitochondrial fraction, and increased activities of catalase and peroxisomal fatty acid beta-oxidation) in the liver of Se-deficient rats. Microsomal omega-hydroxylation was, however, equally induced in both dietary groups. In contrast to clofibric acid, the biological effects of PFOA were not affected by Se status. Furthermore, neither the tissue distribution (plasma, liver and kidney) nor the urinary excretion of 14C was affected by Se deficiency. These results demonstrate that the hydrolysis of clofibrate to clofibric acid is not impaired in the Se-deficient rat. In addition, the involvement of Se in the effects of peroxisome proliferators differs for different members of this structurally heterogeneous group of compounds. It is concluded that the Se-deficient rat may provide valuable information concerning the biochemical mechanism(s) underlying peroxisome proliferation.

Effects of selenium deficiency on xenobiotic-metabolizing and other enzymes in rat liver.

The present study was undertaken to characterize effects of selenium (Se) deficiency on 16 enzymes recovered in either one or more of the subcellular fractions of rat liver (as a basis for future studies on the mechanisms underlying the observed changes). Male rats were fed a Torula-yeast based diet with 0.23 mg Se/kg or the same diet with 0.009 mg Se/kg, from weaning and for 10 weeks. Statistically significant effects of Se deficiency were the following: Se-dependent glutathione peroxidase decreased to 0.14% of the Se-adequate controls, while cytosolic glutathione transferase increased 3-fold in Se deficiency when CDNB was the substrate, but decreased significantly when trans-stilbene oxide (diagnostic for subunit 4) was used as the substrate. Cytosolic DT-diaphorase increased about 7-fold in Se deficiency. Further, DT-diaphorase in the microsomal fraction was also significantly increased in Se deficiency, as were the microsomal and mitochondrial epoxide hydrolases and microsomal glutathione transferase. Furthermore, increased activity of the peroxisomal marker enzyme catalase (P < 0.05) was noted in Se-deficient rats. It is our working hypothesis that changes in enzyme activities in Se deficiency are mainly due to changed levels of endogenously generated metabolites or altered functions of endocrine tissues.

Pituitary regulation of cytochrome P-450-mediated metabolism of steroids and xenobiotics in rat liver microsomes.

In a previous paper we reported on the influence of sex and pituitary hormones on the selection of diethylnitrosamine-initiated, enzyme-altered cells by 0.02% (w/w) 2-acetylaminofluorene (2-AAF) and partial hepatectomy in the resistant hepatocyte model (RH-model). The islands of enzyme-altered cells in this model grew faster in male than in female rat liver and the growth rate was markedly decreased in male rats bearing ectopic pituitary grafts during the 2-AAF selection period. Male rats are also generally more susceptible to 2-AAF carcinogenesis than female rats. In order to investigate whether the sex differentiated response to 2-AAF selection and 2-AAF carcinogenesis might be due to pituitary control of xenobiotic metabolism, as previously shown for rat liver metabolism of steroid hormones, we have studied the influence of age, sex and pituitary hormones on the cytochrome P-450-mediated hydroxylations of 2-AAF and benzo[a]pyrene (B[a]P), O-deethylation of 7-ethoxyresorufin and the metabolism of 4-androstene-3,17-dione (androstenedione) in rat liver microsomes. Microsomes from prepubertal rats had a generally higher capacity to metabolize the xenobiotic compounds whereas the capacity for androstenedione hydroxylation was low. In adult rats pronounced sex differences and a marked influence of pituitary hormones were observed in the microsomal formation of several 2-AAF metabolites as well as in B[a]P and androstenedione metabolism. The results clearly show that at least the oxidative pathways of 2-AAF and B[a]P metabolism are controlled by pituitary hormones in a similar way to the rat liver metabolism of steroids. These data do not, however, provide any explanation for the previously mentioned sex differences in the RH-model or in 2-AAF carcinogenesis. We therefore suggest that the pituitary regulation of other pathways of 2-AAF metabolism must be considered in order to clarify the biochemical background behind sexually differentiated 2-AAF carcinogenesis in rat liver.

Characterization of soluble glutathione transferase activity in resting mononuclear leukocytes from human blood.

Glutathione transferase activity in the soluble fraction of resting human mononuclear leukocytes was measured and characterized using [3H] trans-stilbene oxide as a substrate. Because of the low activity of this enzyme in these cells, a published assay procedure developed for rodent liver was slightly modified to improve its sensitivity: the substrate was highly radiolabeled (2 Ci/mmole) and carefully purified, and the incubation time was extended to 30-60 min. The activity measured was linear with cell density up to at least 6 million cells. Soluble glutathione transferase activity measured in this manner has a pH optimum around 7.4 and an optimal temperature of 40 degrees. This activity could be measured in lymphocytes, monocytes, granulocytes, erythrocytes and platelets, but not in plasma. From these measurements it could be calculated that lymphocytes account for somewhat more than half of the total activity in the mononuclear leukocyte fraction and that monocytes account for the rest. The intraindividual variation in soluble glutathione transferase activity towards trans-stilbene oxide in the mononuclear leukocyte fraction from different subjects was only about 10%, whereas the interindividual variation in this same activity was 15-fold. An explanation for this relatively large interindividual variation is now being sought.