Alteration of human UDP-glucuronosyltransferase UGT2B17 regio-specificity by a single amino acid substitution.

The glucuronidation of steroid hormones is catalyzed by a family of UDP-glucuronosyltransferase (UGT) enzymes. Previously, two cDNA clones, UGT2B15 and UGT2B17, which encode UGT enzymes capable of glucuronidating C19steroids, were isolated and characterized. These proteins are 95% identical in primary structure; however, UGT2B17 is capable of conjugating C19steroid molecules at both the 3alpha and 17beta-OH positions, whereas UGT2B15 is only active at the 17beta-OH position. To identify the amino acid residue(s) which may account for this difference in substrate specificity, a comprehensive study on the role of 15 residues which differ between UGT2B15 and UGT2B17 was performed by site-directed mutagenesis. The stable expression of UGT2B17 mutant proteins into HK293 cells demonstrated that the mutation of isoleucine 125, valine 181 and valine 455 to the residues found in UGT2B15 did not alter enzyme activity nor substrate specificity. Furthermore, mutation of the variant residues in UGT2B15 (serine 124, asparagine 125, phenylalanine 165) to the amino acid residues found in UGT2B17 did not alter enzyme activity nor substrate specificity. However, mutation of the serine residue at position 121 of UGT2B17 to a tyrosine, as found in UGT2B15, abolished the ability of UGT2B17 to conjugate androsterone at the 3alpha position, but still retained activity for dihydrotestosterone and 5alpha-androstane-3alpha, 17beta-diol, which have an OH-group at the 17beta position. Interestingly, mutation of tyrosine 121 in UGT2B15 to a serine abolished activity for C19steroids. It is suggested that the serine residue at position 121 in UGT2B17 is required for activity towards the 3alpha and not for the 17beta position of C19steroids, whereas the tyrosine 121 in UGT2B15 is necessary for UGT activity. Despite the high homology between UGT2B15 and UGT2B17, it is apparent that different amino acid residues in the two proteins are required to confer conjugation of C19steroid molecules.

Isolation and characterization of the human UGT2B15 gene, localized within a cluster of UGT2B genes and pseudogenes on chromosome 4.

Glucuronidation is a major pathway of androgen metabolism and is catalyzed by UDP-glucuronosyltransferase (UGT) enzymes. UGT2B15 and UGT2B17 are 95% identical in primary structure, and are expressed in steroid target tissues where they conjugate C19 steroids. Despite the similarities, their regulation of expression are different; however, the promoter region and genomic structure of only the UGT2B17 gene have been characterizedX to date. To isolate the UGT2B15 gene and other novel steroid-conjugating UGT2B genes, eight P-1-derived artificial chromosomes (PAC) clones varying in length from 30 kb to 165 kb were isolated. The entire UGT2B15 gene was isolated and characterized from the PAC clone 21598 of 165 kb. The UGT2B15 and UGT2B17 genes are highly conserved, are both composed of six exons spanning approximately 25 kb, have identical exon sizes and have identical exon-intron boundaries. The homology between the two genes extend into the 5'-flanking region, and contain several conserved putative cis-acting elements including Pbx-1, C/EBP, AP-1, Oct-1 and NF/kappaB. However, transfection studies revealed differences in basal promoter activity between the two genes, which correspond to regions containing non-conserved potential elements. The high degree of homology in the 5'-flanking region between the two genes is lost upstream of -1662 in UGT2B15, and suggests a site of genetic recombination involved in duplication of UGT2B genes. Fluorescence in situ hybridization mapped the UGT2B15 gene to chromosome 4q13.3-21.1. The other PAC clones isolated contain exons from the UGT2B4, UGT2B11 and UGT2B17 genes. Five novel exons, which are highly homologous to the exon 1 of known UGT2B genes, were also identified; however, these exons contain premature stop codons and represent the first recognized pseudogenes of the UGT2B family. The localization of highly homologous UGT2B genes and pseudogenes as a cluster on chromosome 4q13 reveals the complex nature of this gene locus, and other novel homologous UGT2B genes encoding steroid conjugating enzymes are likely to be found in this region of the genome.

Isolation and characterization of a simian UDP-glucuronosyltransferase UGT2B18 active on 3-hydroxyandrogens.

A monkey cDNA, UGT2B18, encoding a UDP-glucuronosyltransferase (UGT) active on 3-hydroxyandrogens, has been isolated and characterized. Previous results suggested that the monkey represents the most appropriate animal model for studying the physiologic relevance of steroid UGTs. UGT2B18 was isolated from a cynomolgus monkey prostate cDNA library using human UGT2B7, UGT2B10 and UGT2B15 cDNA as probes. The cDNA is 1748 bp in length and contains an open reading frame of 1587 bp encoding a protein of 529 residues. The UGT2B18 cDNA clone was transfected into HK293 cells and a stable cell line expressing UGT2B18 protein was established. Western blot analysis of the UGT2B18-HK293 cell line using a human UGT2B17 polyclonal antibody (EL-93) revealed high expression of a 53 kDa UGT2B protein. The transferase activity of UGT2B18 was tested with over 60 compounds and was demonstrated to be principally active on C19 steroids having an hydroxyl group at position 3alpha of the steroid molecule. UGT2B18 was also active on planar phenols and bile acids. Kinetic analysis revealed that UGT2B18 glucuronidates 3-hydroxyandrogens with high velocity and affinity. Using cell homogenates, Km values of 5.1, 7.8 and 23 microM for androsterone (ADT), etiocholanolone and androstane-3alpha, 17beta diol (3alpha-diol) were obtained, respectively. Specific RT-PCR analysis demonstrated the expression of UGT2B18 transcripts in several tissues including liver, prostate, kidney, testis, adrenal, bile duct, bladder, colon, small intestine, cerebellum and pancreas suggesting a contribution of this isoenzyme to the high plasma levels of glucuronidated ADT and 3alpha-diol found in the cynomolgus monkey.

Regulation of steroidogenesis in NCI-H295 cells: a cellular model of the human fetal adrenal.

NCI-H295 is a recently described human adrenocortical carcinoma cell line that makes a variety of steroid hormones. We sought to determine if steroidogenesis in these cells employs the same enzymes as those used in normal adrenal steroidogenesis, and if the genes encoding those enzymes exhibit characteristic responsiveness to activators of the protein kinase-A and -C pathways of intracellular second messengers. Northern blots show that NCI-H295 cells contain abundant mRNAs for three key steroidogenic enzymes, cytochrome P450scc, cytochrome P450c17, and cytochrome P450c21. These mRNAs accumulated in a time- and dose-dependent fashion in response to 8-bromo-cAMP (8Br-cAMP), forskolin, cholera toxin, and 3-isobutyl-1-methylxanthine, all activators of the protein kinase-A pathway. Nuclear run-on assays and actinomycin-D transcriptional inhibition experiments show that cAMP regulates the expression of all three genes primarily at the transcriptional level. Inhibition of protein synthesis with cycloheximide did not prevent the cAMP-induced accumulation of P450scc or P450c17 mRNAs, but did inhibit accumulation of P450c21 mRNA, suggesting that cAMP is acting through a mechanism dependent on protein synthesis to promote accumulation of P450c21 mRNA. Stimulation of the protein kinase-C pathway with phorbol ester decreased P450scc and P450c17 mRNAs, but stimulated the accumulation of P450c21 mRNA. RNase protection experiments, Northern blot hybridizations, and reverse transcription-polymerase chain reaction show that NCI-H295 cells express both the 11 beta-hydroxylase (P450c11 beta) encoded by the P450c11B1 gene and the aldosterone synthetase (P450c11AS) encoded by the P450c11B2 gene. 8Br-cAMP increased the abundance of both of these mRNAs with similar kinetics, with maximal accumulation of both after about 24 h. NCI-H295 cells also contain the mRNAs for aromatase and insulin-like growth factor-II. 8Br-cAMP increased the abundance of aromatase mRNA and decreased the abundance of IGF-II mRNA. These studies show that NCI-H295 cells express most of the enzymes needed for human adrenal steroidogenesis, and that the genes encoding these enzymes respond to stimulation of second messenger pathways in a manner similar to that of human adrenals. NCI-H295 cells appear to be a good model for studying the molecular regulation of human adrenal steroidogenesis.

Identification of positive and negative placenta-specific basal elements and a cyclic adenosine 3',5'-monophosphate response element in the human gene for P450scc.

The chronic regulation of steroiodgenesis is mediated principally by transcriptional regulation of the genes encoding the various steroidogenic enzymes. The cholesterol side-chain cleavage enzyme, P450scc, is rate limiting and hormonally regulated in a tissue-specific fashion. Human placental steroidogenesis is regulated by LH and hCG through increased intracellular cAMP, and forskolin and 8-bromo-cAMP increase the abundance of human P450scc mRNA in human JEG-3 choriocarcinoma cells. We transfected JEG-3 cells with 24 promoter/reporter constructions to examine the tissue-specific and hormonally induced transcription of the human P450scc gene in these cells. A reporter construction containing only bases -79 to +49 of the human P450scc gene was expressed in JEG-3 cells. This basal expression was increased by four elements, especially by a powerful element between -152 to -142. Adding DNA sequences to -177 suppressed the basal expression seen with the -152 construction, indicating that a repressor element lies between -177 and -152. Thus, basal expression of the human P450scc gene in JEG-3 cells is mediated by the interplay of several separate cis-acting DNA elements. Forskolin induction was conferred by sequences between -108 and -89. The mechanism for cAMP induction appears to be direct, as this induction is rapid and is not blocked by inhibiting protein synthesis with cycloheximide. Gel mobility shift experiments identified six specific DNA-protein complexes. Five of these complexes correlate closely with the basal transcription activities identified by the reporter assays. The powerful basal element, the repressor element, and the cAMP element differ from those identified by similar experiments in mouse adrenal Y1 cells, suggesting that the human P450scc gene is regulated by the tissue-specific use of different regulatory elements.

Regulation of steroid glucuronosyltransferase activities and transcripts by androgen in the human prostatic cancer LNCaP cell line.

Although much attention has been focused on the synthesis of dihydrotestosterone (DHT), the inactivation and elimination of active androgens can also be key points in regulating androgen levels in tissues such as the prostate. Recent data suggest that 5alpha-reduced C19 steroids can be converted to glucuronide derivatives in the human prostate, leading to complete inactivation of these steroids. These results are supported by the recent finding of at least two steroid uridine diphosphoglucuronosyltransferase (UGT) enzymes in the prostate as well as in the human prostatic cancer LNCaP cell line. To ascertain the role of UGTs in regulating active steroid levels, we investigated the modulation of UGT levels in response to steroid treatments in LNCaP cells. Results demonstrate the down-regulation of UGT activities specific for 3-hydroxysteroids and 17-hydroxy-steroids after treatment with androgens and estrogens. Treating the cells with DHT or R1881 for 7 days inhibited UGT activity by 60%; however, 80% of the total activity was recovered after 5 days in the absence of the androgens. The inhibition of UGT activities by DHT and R1881 increases with the time of incubation and with increasing concentrations of the androgens used. The decrease in UGT enzyme activity occurred in parallel with a diminution in UGT transcript levels, as observed in Northern blot analyses. A correlation between the effect of steroids on the androgen-dependent growth response of LNCaP cells, the secretion of prostate-specific antigen, and the inhibition of UGT activities was clearly demonstrated, which implicates the androgen signaling pathway. Treating cells with Casodex, an androgen antagonist that binds the mutated androgen receptor expressed in LNCaP cells, partially blocked the androgen- and estrogen-induced decrease in UGT activity, suggesting that the regulation of UGT levels involves the androgen receptor. In addition to the formation of DHT, the inactivation of steroids by glucuronidation, which is regulated by steroids themselves, is an important mechanism controlling the level of androgens in the prostate.

Basal transcriptional activity and cyclic adenosine 3',5'-monophosphate responsiveness of the human cytochrome P450scc promoter transfected into MA-10 Leydig cells.

Mouse Leydig MA-10 tumor cells are a good model of testicular steroidogenesis. The endogenous murine P450scc mRNA in these cells accumulated in response to 8-bromo-cAMP, forskolin, cholera toxin, and 1-methyl-3-isobutylxanthine, but not in response to 1,9-dideoxyforskolin, indicating that this accumulation was stimulated by the protein kinase-A pathway. Inhibiting transcription with actinomycin-D showed that the half-life of cytochrome P450scc mRNA in these cells was not altered by cAMP, consistent with earlier nuclear run-on data showing that the effect of cAMP on P450scc is at the transcriptional level. A series of 17 fragments of 5'-flanking DNA from the human P450scc gene were fused to the gene for firefly luciferase and transiently transfected into MA-10 cells. The longest construct, containing 2327 basepairs of 5'-flanking DNA, responded 4-fold to forskolin and, hence, was used to optimize the forskolin dose response, showing that 30 microM forskolin elicited a 90% maximal effect. Examination of the activity of the deletion constructs located basal and cAMP-responsive sequences. Constructions containing 79 basepairs of 5'-flanking DNA had basal activity; adding sequences between -79 and -110 had minimal effect, but adding sequences between -110 and -127 increased basal activity 3-fold. Adding sequences beyond -127 did not increase basal transcription further, indicating the presence of a basal transcription element between -110 and -127. These serial deletion mutants were used similarly to locate cAMP responsiveness between -1620 and -1676, indicating the presence of a cAMP response element in this region. The locations of these basal and cAMP-responsive sequences correspond well with those previously identified when human P450scc promoter/reporter constructions were transfected into mouse adrenocortical Y-1 cells, but differ from those identified when such constructions were transfected into human JEG-3 choriocarcinoma cells.

The monkey and human uridine diphosphate-glucuronosyltransferase UGT1A9, expressed in steroid target tissues, are estrogen-conjugating enzymes.

Considering the physiologic importance of the steroid response, which is regulated in part by steroid levels in a given tissue, relatively little is known about steroid glucuronidation, which is widely accepted as a major pathway involved in the catabolism and elimination of steroid hormones from the human body. In a previous study, it was ascertained that the monkey may be the most appropriate model in which to examine the role of steroid glucuronidation. Northern blot analysis of simian RNA, hybridized with human UGT complementary DNA (cDNA) probes demonstrate the similarity of the transcripts. The simian UGT1A09 cDNA isolated from a liver library is 2396 bp and contains an open reading frame encoding 530 amino acids. The predicted primary structure is most homologous to the human UGT1A9 (hUGT1A9) enzyme, which share 93% identity. Stable transfection of the monkey UGT1A09 (monUGT1A09) cDNA into HK293 cells, expresses a microsomal protein with an apparent molecular mass of 55 kDa. Of the more than 30 endogenous substrates tested, both proteins show the highest activity on 4-hydroxyestradiol and 4-hydroxyestrone, followed by 2-hydroxyestradiol and estradiol. RT-PCR analysis demonstrate that UGT1A9 transcript is expressed in several tissues, which include the prostate, testis, breast, ovary, and skin of the monkey and humans. The expression of UGT1A9 in extrahepatic estrogen-responsive tissues, and its high activity on estrogens is consistent with this enzyme having a role in estrogen metabolism.

UGT2B23, a novel uridine diphosphate-glucuronosyltransferase enzyme expressed in steroid target tissues that conjugates androgen and estrogen metabolites.

Glucuronidation is widely accepted as a mechanism involved in the catabolism and elimination of steroid hormones from the body. However, relatively little is known about the enzymes involved, their specificity for the different steroids, and their site of expression and action. To characterize the pathway of steroid glucuronidation, a novel uridine diphosphate glucuronosyltransferase (UGT) enzyme was cloned and characterized. A 1768-bp complementary DNA, encoding UGT2B23 was isolated from a monkey liver library. Stable expression of UGT2B23 in human HK293 cells and Western blot analysis demonstrated the presence of a 51-kDa protein. The UGT2B23 transferase activity was tested with 62 potential endogenous substrates and was demonstrated to be active on 6 steroids and the bile acid, hyodeoxycholic acid. Kinetic analysis yielded apparent Michaelis constant (Km) values of 0.9, 13.5, 1.6, and 5.7 microM for the conjugation of androsterone (ADT), 3alpha-Diol, estriol, and 4-hydroxyestrone, respectively. RT-PCR analysis revealed that UGT2B23 transcript is expressed in several tissues, including the prostate, mammary gland, epididymis, testis, and ovary. Primary structure analysis shows that UGT2B23 is in the same family of enzymes as the previously characterized monkey isoforms UGT2B9 and UGT2B18, which are active on hydroxyandrogens. The characterization of UGT2B23 as a functional enzyme active on 3alpha-hydroxysteroids, and its expression in extrahepatic tissues, indicate that it may potentially play an important role in estrogen and androgen catabolism in peripheral steroid target tissues.

Effect of interleukins on UGT2B15 and UGT2B17 steroid uridine diphosphate-glucuronosyltransferase expression and activity in the LNCaP cell line.

Cytokines are known to modulate the level of both phase 1 and phase 2 drug-metabolizing enzymes in hepatocytes. Although the effects of cytokines on cytochrome P450 (CYP450) enzymes are well understood, there is limited knowledge on how cytokines may affect steroid UDP-glucuronosyltransferase (UGT) phase 2 enzyme activity and expression in different cell types, including hepatocytes and steroid target cells. LNCaP cells, which is a human prostate cancer cell line, is a good model to study the effect of cytokines in steroid target cells because it is known to express steroidogenic enzymes, including UGT2B15 and UGT2B17, which are widely expressed steroid UGT enzymes known to conjugate androgens. In this study, we examined the possible interaction among interleukin-1alpha (IL-1alpha), IL-4, IL-6, and steroid UGT enzymes (UGT2B15 and UGT2B17). Treatment of LNCaP cells with IL-1alpha led to a dose-dependent inhibition of dihydrotestosterone (DHT) glucuronidation. IL-1alpha decreased both UGT activity and LNCaP cell proliferation in the absence and presence of DHT (0.5 nM); a maximal inhibition of 70% was observed. IL-6 inhibited LNCaP cell proliferation as well as the DHT-induced proliferation of these cells. However, neither IL-4 nor IL-6 significantly affected the formation of DHT glucuronide. Ribonuclease protection and Western blot analyses demonstrated a specific reduction of UGT2B17 transcript and protein levels in IL-1alpha-treated LNCaP cells. The level of UGT2B15 was not affected by cytokine treatments, indicating a differential regulation between these two UGT enzymes. Transfection experiments performed with the UGT2B17 gene promoter region indicates that the regulation occurs at the transcription level via putative cis-acting elements. This study indicates that cell proliferation and UGT expression in steroid-responsive cancer cells are differentially regulated depending on the cytokines present in the cell microenvironment.

Differential regulation of two uridine diphospho-glucuronosyltransferases, UGT2B15 and UGT2B17, in human prostate LNCaP cells.

Although androgens are important regulators in the prostate, other effectors such as growth factors may also act to maintain normal function of the gland. Human prostate and human prostate cancer LNCaP cells express steroid conjugating uridine diphospho-glucuronosyltransferase (UGT) enzymes, and it was shown that the level of UGT activities and transcripts is down-regulated by androgens, especially dihydrotestosterone (DHT). In the present study, we examined the interaction between androgen, epidermal growth factor (EGF), and steroid UGT enzymes. The formation of DHT glucuronide (DHT-G) was inhibited by 47% when LNCaP cells were treated for 6 days with 10 ng/ml of EGF. Northern blot analysis also demonstrated a decrease in the steady-state level of UGT2B transcripts. Treatment with both DHT (0.5 nM) and EGF (10 ng/ml) caused a greater decrease of DHT glucuronidation and UGT2B messenger RNA levels than when the cells were treated with either compound alone. RNase protection assays showed that treatment with DHT and EGF caused a specific decrease of UGT2B17 transcript in LNCaP cells treated; however, the level of UGT2B15 messenger RNA was not affected. As well, Western blot analysis demonstrated a diminution of UGT2B17 protein level in response to DHT and EGF. These results demonstrate a differential regulation of different isoforms of steroid conjugating UGTs present in human prostate LNCaP cells. UGT2B17 was shown to be more labile than UGT2B15, indicating that regulation of UGT2B17 expression would lead to a more rapid change in the level of glucuronidated steroids.

Distribution of uridine diphosphate-glucuronosyltransferase (UGT) expression and activity in cynomolgus monkey tissues: evidence for differential expression of steroid-conjugating UGT enzymes in steroid target tissues.

Based on the similarity of pathways and enzymes involved in steroid metabolism, simians represent a relevant animal model to study steroid elimination by glucuronidation. In this study the tissue distribution of UDP-glucuronosyltransferase (UGT) transcripts, proteins, and enzymatic activities were examined in 24 different cynomolgus monkey tissues. RT-PCR and Western blot analysis on total RNA and microsomal proteins demonstrated the presence of UGT1A and UGT2B transcripts and proteins in a wide range of tissues including steroid target tissues. Glucuronidation activity on eugenol, 5alpha-androstane-3alpha,17beta-diol, androsterone, and 4-hydroxyestradiol was measured using tissue homogenates and radiolabeled [14C]UDP-glucuronic acid. All tissues contained conjugation activity on these substrates, but glucuronidation rates were significantly lower in steroid target tissues than in liver, kidney, or gut. However, the ratio of steroid glucuronidation vs. eugenol glucuronidation was higher in steroid target tissues, suggesting a differential expression of steroid-conjugating enzymes in these tissues. Taken together, these results clearly demonstrate the presence of steroid glucuronidation enzymes in extrahepatic steroid target tissues and support the hypothesis that steroid glucuronidation is an important intracrine pathway involved in termination of steroid signaling.

Relative enzymatic activity, protein stability, and tissue distribution of human steroid-metabolizing UGT2B subfamily members.

Androgens and estrogens play major roles in cell differentiation, cell growth, and peptide secretion in steroid target tissues. In addition to the binding of these hormones to their receptors, formation and metabolism are important in the action of steroids. Metabolism of the potent steroid hormones includes glucuronidation, a major pathway of steroid elimination in liver and several steroid target tissues. Glucuronidation is catalyzed by UDP-glucuronosyltransferases (UGTs), which transfer the polar moiety from UDP-glucuronic acid to a wide variety of endogenous compounds, including steroid hormones. The UGT superfamily of enzymes is subdivided into two families, UGT1 and UGT2, on the basis of sequence homology. To date, six UGT2B proteins have been isolated, namely UGT2B4, UGT2B7, UGT2B10, UGT2B11, UGT2B15, and UGT2B17, all of which have been demonstrated to be active on steroid molecules, except for UGT2B10 and UGT2B11, for which no substrate was found. The relative activity of these enzymes on steroidal compounds remains unknown due to variable levels of UGT2B expression in different in vitro cell line models and various conditions of the enzymatic assays. Comparison of the glucuronidation rates of these enzymes requires a unique system for UGT2B protein expression, protein normalization, and enzymatic assays. In this study we have stably expressed UGT2B4, UGT2B7, UGT2B15, and UGT2B17 in the HK293 cell line, which is devoid of steroid UGT activity; characterized their kinetic properties relative to UGT protein expression; determined their transcript and protein stabilities; and established extensively their tissular distributions. UGT2B7 was demonstrated to glucuronidate estrogens, catechol estrogens, and androstane-3alpha,17beta-diol more efficiently than any other human UGTB isoform. UGT2B15 and UGT2B17 showed similar glucuronidation activity for androstane-3alpha,17beta-diol (30% lower than that of UGT2B7), whereas UGT2B17 demonstrated the highest activity for androsterone, testosterone, and dihydrotestosterone. UGT2B4 demonstrates reactivity toward 5alpha-reduced androgens and catechol estrogens, but at a significantly lower level than UGT2B7, 2B15, and 2B17. Cycloheximide treatment of stably transfected HK293 cells demonstrated that the UGT2B17 protein is more labile than the other enzymes; the protein levels decrease after 1 h of treatment, whereas other UGT2B proteins were stable for at least 12 h. Treatment of stable cells with actinomycin D reveals that UGT2B transcripts are stable for 12 h, except for the UGT2B4 transcript, which was decreased by 50% after the 12-h incubation period. Tissue distribution of the UGT2B enzymes demonstrated that UGT2B isoforms are expressed in the liver as well as in several extrahepatic steroid target tissues, namely, kidney, breast, lung, and prostate. This study clearly demonstrates the relative activities and the major substrates of human steroid-metabolizing UGT2B enzymes, which are expressed in a wide variety of steroid target tissues.

The androgen-conjugating uridine diphosphoglucuronosyltransferase-2B enzymes are differentially expressed temporally and spatially in the monkey follicle throughout the menstrual cycle.

UDP-glucuronosyltransferase (UGT) enzymes enhance the polarity of steroid hormones by catalyzing their conjugation with the sugar group from UDP-glucuronic acid. Previous results have shown that the monkey is a suitable animal model to study steroid glucuronidation in steroid target tissues. In humans, as in the monkey, the main androgen metabolites found in the circulation are 5alpha-androstane-3alpha,17beta-diol-glucuronide and androsterone glucuronide, and high levels of androsterone glucuronide were also measured in human follicular fluid. Ovarian androgens play a significant role as precursors for estrogens and may modulate the recruitment and growth of follicles. To analyze the expression pattern of UGT2B enzymes involved in androgen metabolism throughout the menstrual cycle, cynomolgus monkey ovaries were collected during the mid and late follicular and luteal phases. Microsomal proteins and total RNA were analyzed for UGT2B expression in the whole ovary. Western blot and specific RT-PCR analyses demonstrated no significant changes in the expression of UGT2B protein or transcripts during the menstrual cycle. Immunocytochemistry analysis showed that UGT2B proteins are expressed in the cytoplasm of thecal and granulosa cells of growing follicles. Interestingly, the thecal cells of secondary follicles and of corpus luteum were extensively stained, whereas luteal granulosa cells were not labeled. These results suggest an important regulation of cell type-specific UGT2B expression during follicular development. Previous results demonstrated similar changes in the expression of the androgen receptor. The colocalization of the androgen receptor and UGT2B enzymes in the same cell types of the ovary provide evidence for a potential role of glucuronidation as a modulator of the intracellular androgen response during follicular development.

Transcription of the human genes for cytochrome P450scc and P450c17 is regulated differently in human adrenal NCI-H295 cells than in mouse adrenal Y1 cells.

Human NCI-H295 cells, which express all of the genes for the steroidogenic enzymes in a hormonally regulated fashion, should be an ideal system in which to study the transcriptional regulation of these genes. Using deletional promoter/reporter constructions for the human P450scc and P450c17 genes, we identified the regions conferring basal and cAMP-induced transcription of these two genes in NCI-H295 human adrenal cells. In the P450scc gene, both basal and cAMP-induced transcriptional activation elements lie within the first 79 bp upstream (-79) from the transcriptional start site. In the P450c17 promoter, both basal and cAMP-responsive elements lie within the first upstream 63 bp, and a second basal element lies between -184 and -206 bp. The locations of these elements are substantially different from the locations of elements that appear to be functionally equivalent when these human gene promoters are transfected into mouse adrenal Y1, mouse testicular MA-10, or human choriocarcinoma JEG-3 cells. These data indicate that the transcriptional regulation of these genes in their native species and cell type differs substantially from their regulation in cells from other species and tissues, and suggests that the results from transfection experiments examining genes for steroidogenic enzymes in heterologous cells may not reflect events in vivo.

Point mutation of Arg440 to His in cytochrome P450c17 causes severe 17 alpha-hydroxylase deficiency.

Genetic disorders in the gene encoding P450c17 cause 17 alpha-hydroxylase deficiency. The consequent defects in the synthesis of cortisol and sex steroids cause sexual infantilism and a female phenotype in both genetic sexes as well as mineralocorticoid excess and hypertension. A 15-yr-old patient from Germany was seen for absent pubertal development and mild hypertension with hypokalemia, high concentrations of 17-deoxysteroids, and hypergonadotropic hypogonadism. Analysis of her P450c17 gene by polymerase chain reaction amplification and direct sequencing showed mutation of codon 440 from CGC (Arg) to CAC (His). Expression of a vector encoding this mutated form of P450c17 in transfected nonsteroidogenic COS-1 cells showed that the mutant P450c17 protein was produced, but it lacked both 17 alpha-hydroxylase and 17,20-lyase activities. To date, 15 different P450c17 mutations have been described in 23 patients with 17 alpha-hydroxylase deficiency, indicating that mutations in this gene are due to random events.

Cellular localization of uridine diphosphoglucuronosyltransferase 2B enzymes in the human prostate by in situ hybridization and immunohistochemistry.

UDP-glucuronosyltransferase (UGT) enzymes catalyze the transfer of the glucuronide group from UDP-glucuronic acid to several exogenous or endogenous compounds, including steroid hormones. Although it is widely recognized that the liver is a major site of steroid glucuronidation, RT-PCR analysis has shown the expression of UGT2B transcripts in extrahepatic steroid target tissues such as the prostate. Measurement of androgen metabolites in human prostate revealed high levels of C(19) steroid glucuronides such as androsterone glucuronide and 3alpha-diol glucuronide, thus suggesting an important role of UGT2B enzymes in androgen metabolism. To investigate the cellular localization of UGT2B expression in the human prostate, the present in situ hybridization studies demonstrated the presence of UGT2B transcripts in epithelial cells lining the acinii. All basal cells were intensively labeled, whereas the luminal secretory cells were moderately labeled. To confirm these results, an immunohistological analysis was performed using a specific anti-UGT2B antibody. The presence of UGT2B proteins was observed in both basal and luminal cells of prostate epithelium, in fibrocytes of stroma and blood vessels, and in endothelial cells of blood vessels. Using a specific anti-UGT2B17 antibody, the expression of this androsterone-conjugating UGT enzyme was found exclusively in basal cells of the epithelium. These results demonstrate the expression of androgen-conjugating UGT2B enzymes in human prostatic epithelium. Moreover, they show for the first time a cell type-specific expression of an UGT2B isoform.

Artificial mutations in P450c11AS (aldosterone synthase) can increase enzymatic activity: a model for low-renin hypertension?

The conversion of 11-deoxycorticosterone (DOC) to aldosterone is catalyzed by a single enzyme, termed P450c11AS, which has 11 beta-hydroxylase, 18-hydroxylase and 18-oxidase activities. The normotensive Dahl salt-resistant (R) rat has two mutation in P450c11AS that increase its aldosterone synthase activity. If such a mutation were to occur in human patients the predicted phenotype would be low-renin hypertension with elevated ratios of plasma aldosterone to plasma renin activity. Before searching for P450c11AS mutations in such patients we sought to determine if mutations in human P450c11AS could increase enzymatic activity in a fashion analogous to the Dahl R rat. We used site-directed mutagenesis of the human P450c11AS cDNA to create the mutants Glu 136-->Asp, Lys 251-->Arg and the combination of the two; these mutations correspond to those seen in the Dahl R rat. Cells transfected with these mutant human P450c11AS sequences could convert [14C]DOC to corticosterone, 18OH-corticosterone, and aldosterone. In particular the Lys 251-->Arg mutant produced 4 times as much 18OH-corticosterone and 50-80% more aldosterone than the wild type. These data show that mutations of human P450c11AS can increase enzymatic activity, suggesting that such mutations could, in theory, be the basis of some forms of human low-renin hypertension.

Gene conversion in the CYP11B2 gene encoding P450c11AS is associated with, but does not cause, the syndrome of corticosterone methyloxidase II deficiency.

Cytochrome P450c11AS (aldosterone synthase) has 11 beta-hydroxylase, 18-hydroxylase, and 18-oxidase activities and is expressed solely in the adrenal zona glomerulosa. Corticosterone methyloxidase II (CMOII) deficiency denotes a rare disorder of adrenal steroidogenesis in which only the 18-oxidase activity of P450c11AS is disrupted, while the 11 beta-hydroxylase and 18-hydroxylase activities persist. Such patients have elevated serum concentrations of corticosterone and 18-hydroxycorticosterone and very low or unmeasurable concentrations of aldosterone, often resulting in a clinical salt-losing crisis in infancy. One pair of point mutations, Arg181-->Trp and Val386-->Ala, has been previously characterized to cause this disorder in an inbred Iranian Jewish population. We have sought mutations causing CMOII deficiency in outbred populations. In three of four unrelated P450c11AS alleles from two unrelated patients with CMOII deficiency, we found a gene conversion event in which exons 3 and 4 of the CYP11B2 gene encoding P450c11AS were changed to the sequence of the nearby CYP11B1 gene, which encodes the related enzyme P450c11 beta. This conversion resulted in a mutant P450c11AS protein carrying three changes: Asp141-->Glu, Lys151-->Asn, and Ile246-->Thr. We built seven vectors expressing P450c11AS carrying each mutation singly, each of the three possible pairs of mutations, and the triple mutation as found in the proband. The activities of both the normal P450c11AS and the various mutants in transfected nonsteroidogenic COS-1 cells were very low, but their activities in steroidogenic MA-10 and JEG-3 cells were 10- to 20-fold higher. In these systems all of the mutants retained normal 18-oxidase activity, indicating that the detected gene conversion event is associated with but does not cause CMOII deficiency. None of the four CYP11B2 alleles in these two patients bore other identifiable mutations. These patients might have mutations in the promoters or other noncoding regions, or mutations in genes other than CYP11B2 may cause the syndrome of CMOII deficiency.

Characterization and substrate specificity of UGT2B4 (E458): a UDP-glucuronosyltransferase encoded by a polymorphic gene.

Variations in glucuronidation activities among different individuals have been reported; however, genetic polymorphisms in the genes encoding phase II drug metabolizing UDP-glucuronosyltransferases have not been studied extensively. A novel UGT2B cDNA clone UGT2B4(E458) was isolated from human prostate and LNCaP cell cDNA libraries. The cDNA encoding UGT2B4(E458) is 2097 bp in length and has an open reading frame of 1584 nucleotides encoding a protein of 528 amino acids. Characterization of the UGT2B4(E458) cDNA revealed nucleotide differences with the previously published UGT2B4 and UGT2B11 cDNAs. These variations in the UGT2B4 sequence lead to an amino acid change from aspartic acid to glutamic acid at position 458. In the previous UGT2B11 cDNA (which has subsequently been renamed UGT2B4 (L109,396, D458)), leucine residues are found at positions 109 and 396, whereas phenylalanines are present at these positions in the UGT2B4(D458) and UGT2B4(E458) enzymes. Analysing the genomic DNA of 26 unrelated Caucasian individuals demonstrated the presence of variant alleles encoding UGT2B4(D458) and UGT2B4(E458). Stable expression of UGT2B4(E458) cDNA in HK293 cells demonstrates the presence of a 52 kDa protein, which is in agreement with other characterized (UGT2B proteins. UGT2B4(E458) conjugates hyodeoxycholic acid (HDCA) as well as 4-hydroxyestrone (4-OH-E1), androstane-3alpha,17beta-diol (3alpha-diol) and androsterone (ADT). Specific reverse transcriptase-polymerase chain reaction analysis revealed expression of UGT2B4(D458) and UGT2B4(E458) transcripts in a wide range of extrahepatic tissues, including the liver, kidney, testis, mammary gland, prostate, placenta, adipose, adrenal, skin and lung. Our results suggest that UGT2B4(E458) and UGT2B(E458) are two widely expressed isoenzymes, and that polymorphism in the UGT2B4 gene might be responsible for differences in UGT2B4 enzymatic properties.