Xenopus laevis Ovarian CYP17 Is a Highly Potent Enzyme Expressed Exclusively in Oocytes

EVIDENCE THAT OOCYTES PLAY A CRITICAL ROLE IN XENOPUS OVARIAN ANDROGEN PRODUCTION*

Wei-Hsiung Yang, Lindsey B. Lutz, and Stephen R. HammesDagger

From the Department of Internal Medicine, Division of Endocrinology and Metabolism, Department of Pharmacology, University of Texas Southwestern Medical Center, Dallas, Texas 75390-8857

Received for publication, November 25, 2002, and in revised form, January 6, 2003

    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Progesterone has long been considered the primary mediator of Xenopus oocyte maturation. We have recently shown, however, that androgens, which are equal or more potent promoters of maturation and are present at higher levels in ovulating frogs, may also be playing an important physiologic role in mediating maturation. Here, we examined the role of CYP17, a key enzyme mediating sex steroid synthesis, in Xenopus ovarian androgen production. We found that the 17,20-lyase activities of Xenopus CYP17 exceeded the 17alpha -hydroxylase activities in both the Delta 4 and Delta 5 pathways; thus, Xenopus CYP17 rapidly converted pregnenolone and progesterone to dehydroepiandrosterone (DHEA) and androstenedione, respectively. This remarkably robust activity exceeds that of CYP17 from most higher vertebrates, and likely explains why virtually no progesterone is detected in ovulating frogs. Additionally, ovarian CYP17 activity was present exclusively in oocytes, although all other enzymes involved in sex steroid production were expressed almost entirely in surrounding follicular cells. This compartmentalization suggests a "two-cell" model whereby Xenopus ovarian androgen production requires both follicular cells and oocytes themselves. The requirement of oocytes for ovarian androgen production further introduces the unusual paradigm whereby germ cells may be responsible for producing important steroids used to mediate their own maturation.

    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The phenomenon of steroid-induced maturation of Xenopus oocytes has served as a model for studying cell cycle and nongenomic steroid signaling for several decades (1-5). During this time, progesterone has been considered the primary physiologic mediator of oocyte maturation, perhaps through interactions with classical progesterone receptors expressed in the oocyte (6, 7). We have recently shown, however, that testosterone, rather than progesterone, may be the primary physiologic mediator of Xenopus oocyte maturation (8). This dominant role of testosterone is evidenced by the observation that testosterone is a substantially more potent activator of oocyte maturation than progesterone, and that testosterone levels are significantly higher than progesterone (which is nearly undetectable) in the serum and ovaries of beta -HCG1-stimulated frogs. In addition, we have shown that, in vitro, isolated oocytes rapidly convert exogenously added progesterone to the androgen androstenedione (AD), which is an equally potent promoter of maturation when compared with progesterone. These data suggest that both AD and progesterone are likely inducing maturation under in vitro conditions typical for "progesterone-mediated" maturation.

The high levels of ovarian testosterone in the absence of detectable progesterone imply that Xenopus ovaries are extremely efficient at metabolizing progesterone. Additionally, the ability of isolated oocytes to rapidly convert progesterone to androgens suggests that the oocytes themselves may be important contributors to progesterone metabolism in the ovary. To explain the lack of in vivo progesterone accumulation, as well as to characterize the role of oocytes in ovarian androgen production, we separated oocytes from surrounding follicular cells and examined the ability of both cell types to metabolize progesterone and other androgen precursors. We focused on the function of the cytochrome P450 enzyme CYP17 in ovarian androgen production, as it is known to play a pivotal role in the synthesis of androgens (Fig. 1). CYP17, an endoplasmic reticulum membrane-bound multifunctional enzyme (9-11), exhibits two enzymatic activities. Its 17alpha -hydroxylase activity converts pregnenolone and progesterone into their respective 17alpha -hydroxylated products 17alpha -hydroxypregnenolone (17OHPreg) and 17alpha -hydroxyprogesterone (17OHProg). The second 17,20-lyase activity cleaves the steroid side chains of 17OHPreg and 17OHProg to yield dehydroepiandrosterone (DHEA) and AD, respectively. CYP17 is expressed in several steroidogenic tissues (12, 13), including adrenal cortex, ovary, and testis. Whereas earlier work implicates the presence of CYP17 in oocytes (8), the kinetic characteristics of the Xenopus CYP17 (XeCYP17), as well as its expression levels in other ovarian cell types, is not known. Furthermore, expression levels of other important steroidogenic enzymes in various ovarian cell types have not been examined.


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Fig. 1.   Ovarian steroid biosynthesis. The sex steroid synthesis pathway, including several key enzymes, is shown. CYP17 is highlighted with a box, and the 17alpha -hydroxylase and 17,20-lyase activities are indicated on the right. The Delta 5 and Delta 4 pathways are indicated on the top, with the Delta 5 steroids on the left and Delta 4 steroids on the right.

We show here that XeCYP17 has high 17alpha -hydroxylase, and even more pronounced 17,20-lyase, activities in both the Delta 5 (pregenenolone) and Delta 4 (progesterone) pathways (Fig. 1). This differs from most known CYP17 isoforms, which generally favor one pathway over the other, and rarely have 17,20-lyase activity that rivals their 17alpha -hydroxylase activity. Furthermore, we show that ovarian CYP17 activity is present exclusively in oocytes, whereas other important steroidogenic enzymes, including 3beta -HSD and 17beta -HSD, are located primarily in the surrounding follicular cells. Finally, we propose a "two-cell" model for androgen synthesis in the Xenopus ovary that involves both oocytes and follicular cells. This model implies that germ cells themselves are critical for Xenopus ovarian androgen production, which in turn may play an important physiologic role in promoting their own maturation.

    EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Oocyte and Follicular Cell Preparation-- Ovaries were harvested from Xenopus laevis (Nasco, Fort Atkinson, WI) and oocytes were isolated by incubation with 1 mg/ml collagenase A (Roche Molecular Biochemicals) at room temperature for 4 h in modified Barth's solution (MBSH) as previously described (14, 15). Oocytes were then washed and incubated overnight at 16 °C in MBSH with 1 mg/ml bovine serum albumin, 1 mg/ml Ficoll, 100 units/ml penicillin, and 0.1 mg/ml streptomycin. Stage V-VI oocytes were selected and examined microscopically to confirm the absence of follicular cells.

Follicular cells were isolated by incubating ovaries in collagenase as above for 1 h. Oocytes were allowed to settle by gravity for ~5 min, and the supernatant containing follicular cells was then centrifuged at 800 × g for 5 min. The pelleted cells were washed 3 times with MBSH, and any remaining oocytes were removed manually under a dissecting microscope. Similar numbers of follicular cells were used in all of the metabolism experiments. In addition, nearly identical results were obtained using follicular cells removed from oocytes after up to 4 h of treatment with collagenase, or using follicular cells separated from oocytes by incubation with trypsin (16).

Preparation of Oocyte Membranes-- Crude oocyte membranes were prepared as previously described (17). In short, stage V-VI oocytes were homogenized in membrane buffer (83 mM NaCl, 1 mM MgCl2, 1 mM phenylmethylsulfonyl fluoride, 0.5 µg/ml aprotinin, 0.5 µg/ml leupeptin, 0.5 µg/ml pepstatin, 10 mM Hepes, pH 7.6) at 4 °C. The homogenate was centrifuged at 800 × g for 5 min and the supernatant containing the membranes was removed and centrifuged two more times at 800 × g. The supernatant was then centrifuged at 15,000 × g for 15 min, and the membrane pellet was resuspended in membrane buffer. Membranes were centrifuged two more times at 15,000 × g and resuspended in MBSH. Protein concentrations were then measured using the BCA kit (Pierce), and samples were frozen at -80 °C until needed. We saw no significant drop in CYP17 activity after a single freeze/thaw cycle of the membranes.

CYP17 Enzyme Assays in Oocyte Membranes-- 17alpha -Hydroxylase and 17,20-lyase activities in oocyte membranes were performed as previously described (18). Membranes were assayed under initial rate kinetics by incubation in 50 mM potassium phosphate buffer (pH 7.4) with 0.03-1 µM steroid (Sigma and Steraloids, Newport, RI) and 1 mM of the cofactor NADPH in a 500-µl total volume at 16 °C for 30 min. Each reaction contained 50 µg of membranes and 50,000 cpm of [7-3H]pregnenolone (19), [3H]17alpha -hydroxypregnenolone, [1,2,6,7-3H]progesterone, or [1,2,6,7-3H]17alpha -hydroxyprogesterone (PerkinElmer Life Sciences). Steroids were extracted with 3 ml of 3:2 ethyl acetate:hexane. Amounts of radioactivity were measured using a scintillation counter, with >90% recovery from medium. Steroids were concentrated under nitrogen and separated by TLC using 3:1 chloroform:ethyl acetate. Quantitation of steroids was measured by cutting out the steroid spots on the TLC plate and measuring radioactivity using liquid scintillation (20). Kinetic behavior was approximated as a Michaelis-Menten system for data analysis. The identities of all steroids in these and the other metabolism experiments were confirmed by high performance liquid chromatography.

CYP17 Enzyme Assays in Transfected HEK-293 Cells-- HEK-293 cells were grown in complete medium consisting of Dulbecco's modified Eagle's medium, 10% fetal bovine serum, 100 units/ml penicillin, and 0.1 mg/ml streptomycin (Invitrogen). Experiments were performed on 12-well plates. Cells were transfected by calcium phosphate precipitation (8, 21) with either pcDNA3.1 (mock) or pcDNA3.1 containing cDNA encoding the Xenopus or human CYP17 protein (8). After 48 h, cells were placed in fresh complete medium containing 5% charcoal-stripped fetal bovine serum and 60,000 cpm/well of radiolabeled progesterone, 17alpha -hydroxyprogesterone, pregnenolone, or 17alpha -hydroxypregnenolone at the indicated concentrations. Cells were incubated at 37 °C, and medium was removed at the specified times. Steroids were extracted with 5 ml of 3:2 ethyl acetate:hexane, the organic layer was concentrated, and TLC followed by autoradiography and quantitation was performed as described above.

Steroid Metabolism Assays in Ovaries, Oocytes, and Follicular Cells-- Ovaries (~500 mg/sample), isolated oocytes (30 oocytes per sample), follicular cells, or recombined follicular cells and oocytes (20 oocytes per sample) were incubated with ~500,000 cpm of [1,2,6,7-3H]progesterone, [7-3H]pregnenolone, [1,2,6,7-3H]androstenedione, or [1,2,6,7-3H]DHEA in 1 ml of MBSH for 4 h at 16 °C. Medium was removed from the ovaries, oocytes, or follicular cells, and steroids were extracted with 3:2 ethyl acetate:hexane and treated as above.

beta -HCG-mediated Maturation of Oocyte in Ovarian Fragments-- Ovarian fragments of ~100-200 mg were washed in MBSH and treated for 1 h in 2 ml of MBSH with either ethanol or 100 nM VN/85-1 (a gift from A. Brodie, University of Maryland). Ethanol concentrations were kept constant. beta -HCG was then added at a concentration of 100 units/ml, and the ovarian fragments were incubated at 16 °C for ~12 h. The MBSH was removed, and steroids were extracted and analyzed by radioimmunoassay (8). Oocytes were manually removed from the ovarian fragments and maturation was determined by visualization of a white spot on the animal pole.

    RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Sex Steroid Precursors Pregnenolone and Progesterone Are Rapidly Metabolized to Testosterone by Xenopus Ovaries-- Previous work in our laboratory demonstrated that beta -HCG or pregnant mare serum gonadotropin (PMSG) stimulation of Xenopus ovaries in vivo and in vitro produced high levels of testosterone and small to moderate amounts of androstenedione. In contrast, little to no androgen precursors, including pregnenolone, 17OHPreg, progesterone, and 17OHProg, were detected (8). To determine whether Xenopus ovaries could convert sex steroid precursors to androgens in the absence of gonadotropins, we examined pregnenolone and progesterone metabolism by incubating ovarian tissue with the respective radiolabeled steroids. Both pregnenolone and progesterone were rapidly converted to testosterone (Fig. 2), with more than 90% loss of each steroid by 2 h. Virtually no intermediates or further metabolites of testosterone (e.g. estrogen or dihydrotestosterone) were detected in both the pregnenolone- and progesterone-treated ovaries (<10% of total counts at all time points). These data suggest that Xenopus ovaries contain all of the enzymatic machinery necessary for the conversion of sex steroid precursors to testosterone independent of gonadotropin stimulation. Furthermore, this ability to rapidly metabolize pregnenolone and progesterone likely explains why both steroids are nearly undetectable in gonadotropin-stimulated ovaries both in vivo and in vitro (8).


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Fig. 2.   Pregnenolone and progesterone are rapidly metabolized to testosterone by Xenopus ovaries. Pregnenolone (A) or progesterone (B) metabolism was examined by incubating 0.1 g of ovarian tissue for the times indicated with 100 nM radiolabeled pregnenolone or progesterone (~60,000 cpm/sample). Steroids were extracted from the media and examined by TLC. Locations of pregnenolone (PREG), progesterone (PROG), testosterone (TEST), and AD are indicated. The identities of these steroids were confirmed by high performance liquid chromatography. These indicated steroids represent >90% of the total counts in each TLC lane. Experiments were performed at least three times with nearly identical results.

CYP17 in Xenopus Oocyte Membranes Possesses High 17alpha -Hydroxylase and 17,20-Lyase Activity in Both the Delta 5 and Delta 4 Pathways-- The rapid conversion of progesterone and pregenenolone to androgens implies that the Xenopus ovary contains CYP17, the first key enzyme in the conversion of these sex steroid precursors to androgens (22, 23). Indeed, we previously cloned the XeCYP17 enzyme from an oocyte cDNA library and demonstrated its ability to catalyze two enzymatic reactions: the hydroxylation of progesterone to 17OHProg, and the conversion of 17OHProg to AD (8). To further characterize the XeCYP17 enzyme, and to determine its role in Xenopus ovarian androgen production, we used membrane preparations from isolated oocytes to measure the kinetic characteristics of XeCYP17. Representative Lineweaver-Burk plots for the 17alpha -hydroxylase and 17,20-lyase activities in both the Delta 4 and Delta 5 pathways are shown in Fig. 3, with the calculated average Km and Vmax values for five separate experiments shown in Table I. The Km values for the 17alpha -hydroxylase and 17,20-lyase activities in both the Delta 4 and Delta 5 pathways ranged between 26 and 117 nM. The maximal velocities (Vmax) for 17alpha -hydroxylase activity in both the Delta 4 and Delta 5 pathways were similar in magnitude, ranging from 1.3 to 5.2 pmol/mg of protein/min. Surprisingly, XeCYP17 contained remarkably high 17,20-lyase activity in both the Delta 4 and Delta 5 pathways, with Vmax = 2.3 pmol/mg of protein/min for the conversion of 17OHPreg to DHEA (Delta 5 pathway), and Vmax = 12.3 pmol/mg of protein/min for the conversion of 17OHProg to AD (Delta 4 pathway). This relatively high 17,20-lyase activity could be seen more clearly by examining the ratio of Vmax values for the 17,20-lyase versus 17alpha -hydroxylase reactions in both pathways (Table I). The lyase/hydroxylase values were 1.8 in the Delta 5 pathway, and 2.5 in the Delta 4 pathway, indicating that XeCYP17 catalyzed the 17,20-lyase reaction even more quickly than the 17alpha -hydroxylase reaction in both pathways. Furthermore, these results suggest that, in the Xenopus ovary, androgens can be rapidly and efficiently produced via both the Delta 4 or Delta 5 pathways.


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Fig. 3.   Representative Lineweaver-Burk plots of 17alpha -hydroxylase and 17,20-lyase activities in oocyte membranes. Oocyte membranes were prepared and treated as described under "Experimental Procedures." Lines were derived from least-squared fit to the data points, with r2 values are indicated. Starting steroids are indicated, with the Delta 5 steroids on the left (A and C) and Delta 4 steroids on the right (B and D). 17alpha -Hydroxylase reactions are represented on the top (A and B), whereas 17,20-lyase reactions are shown on the bottom (C and D).

                              
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Table I
Kinetic parameters of XeCYP17 in Xenopus oocyte membranes
The kinetic parameters of XeCYP17 expressed in Xenopus oocyte membranes were measured as described under "Experimental Procedures." The 17alpha -hydroxylase and 17,20-lyase activities in both the Delta 4 and Delta 5 pathways are indicated, as are the steroid substrates and end products for each reaction (parentheses). The Vmax ratios of lyase: hydroxylase activity for the two pathways are indicated in the right column. Values are expressed as mean ± S.D. (n = 5).

Xenopus CYP17 Expressed in HEK-293 Cells Completely Metabolizes Sex Steroid Precursors in Both the Delta 4 and Delta 5 Pathways, whereas Human CYP17 Favors the Delta 5 Pathway-- The high 17,20-lyase activity of XeCYP17 in both the Delta 4 and Delta 5 pathways is rather unusual, as most CYP17 isoforms favor one pathway over the other (12, 18, 24). For example, the human CYP17 (HuCYP17) has little to no 17,20-lyase activity in the Delta 4 pathway; thus, human sex steroid synthesis is felt to involve primarily the Delta 5 pathway (18). To directly compare the kinetic profiles of the Xenopus and human CYP17 enzymes, and to confirm that the observed enzymatic activities in the Xenopus oocyte membranes were in fact mediated by the cloned XeCYP17 enzyme, we expressed the human and Xenopus CYP17 proteins individually in HEK-293 cells. Fig. 4, A and B, shows that XeCYP17 converted progesterone to 17OHProg, and then to AD (40% of total counts by 8 h), confirming that both 17alpha -hydroxylase and 17,20-lyase activities are carried by this protein. In contrast, HuCYP17 contained high 17alpha -hydroxylase, but very little 17,20-lyase, activity in the Delta 4 pathway (Fig. 4, A and C, 6% conversion to AD by 8 h). Calculated Km values for HuCYP17-mediated 17alpha -hydroxylase reactions in the Delta 4 and Delta 5 pathways were ~0.54 and 0.28 µM, respectively (data not shown), which correlate well with published values (18). This confirms that the enzyme is functioning as expected in our HEK-293 expression system.


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Fig. 4.   XeCYP17 contains more 17,20-lyase activity than HuCYP17 in HEK-293 cells. A, either empty vector (pcDNA3.1) or pcDNA3.1 containing cDNA clones encoding XeCYP17 or HuCYP17 were expressed in HEK-293 cells. After 48 h, cells were incubated with 100 nM radiolabeled progesterone, at 60,000 cpm/well. Medium was removed at the specified times, steroids were extracted, and TLC was performed. Locations of progesterone (PROG), AD, and 17OHProg are indicated. Steroid levels are displayed as the percentage of total steroids extracted from cells expressing XeCYP17 (B) or HuCYP17 (C), with background subtracted (A) for the 17OHProg and AD spots. Progesterone, 17OHProg, and AD represent >90% of the total counts in each TLC lane. All experiments were performed at least three times with nearly identical results. D, the lyase/hydroxylase ratios of the Vmax values in the Delta 4 and Delta 5 pathways for both human and Xenopus CYP17 in HEK-293 cells were calculated as described under "Experimental Procedures." Each bar represents the average of three individual experiments, with the error bars representing the mean ± S.D. Each individual Vmax ratio was calculated from the 17alpha -hydroxylase and 17,20-lyase reactions performed in the same transfections to control for enzyme expression.

Comparison of the calculated lyase/hydroxylase Vmax ratios in HEK-293 cells confirmed that XeCYP17 had high 17,20-lyase activity in both pathways, with lyase/hydroxylase Vmax ratios of approximately unity (Fig. 4D). In contrast, the 17alpha -hydroxylase reaction was dominant in both pathways for the HuCYP17, with ratios of ~0.3 in the Delta 5 pathway and <0.05 in the Delta 4 pathway. The lower lyase/hydroxylase ratios of XeCYP17 expressed in the HEK-293 cells when compared with the oocyte membranes could be because of many factors, including the availability of important cofactors such as NADPH and the flavoprotein reductase(s), or the species compatibility of the 17,20-lyase cofactor cytochrome b5 in human versus Xenopus tissues. The 17,20-lyase activity in HEK-293 cells was still relatively high, however, thus these experiments appear to confirm that the cloned XeCYP17 enzyme is indeed responsible for the potent 17,20-lyase activity seen in oocyte membranes. Notably, similar results were qualitatively seen in COS cells; however, the presence of endogenous CYP17 in these cells precluded their use for quantitative studies.

Xenopus Oocytes Possess High CYP17 Activity, but Little to No 3beta -HSD or 17beta -HSD Activity-- Having established that Xenopus CYP17 can metabolize sex steroid precursors equally well in both the Delta 4 and Delta 5 pathways, we next determined which cells within the ovary contained CYP17 activity. As mentioned, we had previously shown that isolated Xenopus oocytes possess high CYP17 activity in the Delta 4 pathway (8). To confirm the presence of CYP17 in Xenopus oocytes, we separated oocytes from surrounding follicular cells and performed steroid metabolism experiments. Notably, isolated oocytes were examined very carefully both under the dissecting microscope and by staining of oocyte sections to exclude the presence of follicular cell contamination in our preparations. Fig. 5 represents one of over 50 different hematoxylin/eosin-stained oocyte sections, with no detectable follicular cell contamination.


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Fig. 5.   Isolated oocytes contain no visible follicular cells. Isolated oocytes were fixed, imbedded with paraffin, and stained with hematoxylin/eosin. The nucleus and cytoplasm are indicated, and the bar represents 0.1 mm. This photo represents one of over 50 sections from several different oocytes and oocyte preparations, all of which demonstrate the same lack of follicular cells, which would be detected by blue nuclear staining if present.

As expected, isolated oocytes contained high CYP17 activity in both the Delta 5 and Delta 4 pathways, as radiolabeled pregnenolone and progesterone were rapidly metabolized to only DHEA and AD, respectively (Fig. 6A). Interestingly, the isolated oocytes did not appear to significantly express any of the other enzymes responsible for the various stages in the production of sex steroids. For example, 3beta -HSD is responsible for the conversion of Delta 5 to Delta 4 steroids (Fig. 1). The rapid conversion of radiolabeled pregnenolone to DHEA in the absence of detectable Delta 4 steroid production (Fig. 6A, left panel) argues strongly that oocytes lack significant 3beta -HSD activity. Likewise, 17beta -HSD is necessary for the conversion of DHEA to androstenediol, and of androstenedione to testosterone (Fig. 1). The lack of detectable androstenediol in the pregnenolone-treated cells, as well as the near absence of testosterone in progesterone-treated cells (<10% of the total counts at all time points measured), suggests that oocytes contain little 17beta -HSD activity (Fig. 6A). Finally, stimulation of isolated oocytes with beta -HCG did not promote significant steroid production by radioimmunoassay (data not shown), suggesting that they contain little CYP11A1 or steroidogenic acute regulatory protein (stAR) activity, both of which are necessary to augment formation of pregnenolone (Fig. 1).


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Fig. 6.   Oocytes exclusively express CYP17, whereas follicular cells contain all the 3beta -HSD and 17beta -HSD activity in Xenopus ovaries. Pregnenolone, progesterone DHEA, and AD metabolism were examined in isolated oocytes (A), follicular cells (B), or recombined follicular cells and oocytes (C), by incubating cells with the respective radiolabeled steroids at 100 nM for the indicated times. Steroids were then extracted from the medium and examined by TLC. Locations of steroids are indicated. All experiments were performed at least three times using similar numbers of cells with nearly identical results.

Xenopus Ovarian Follicular Cells Contain 3beta -HSD and 17beta -HSD Activities, but No CYP17 Activity-- If oocytes have no significant 3beta -HSD and 17beta -HSD activity, then these enzymes must be present in the surrounding ovarian follicular cells to complete ovarian androgen synthesis. In support of this hypothesis, small amounts of radiolabeled pregnenolone were converted to progesterone by isolated ovarian follicular cells, indicating the presence of 3beta -HSD in these cells (Fig. 6B, left panel). Similar numbers of follicular cells converted radiolabeled DHEA to AD at a significantly higher rate (Fig. 6B, middle panel), thus confirming the presence of 3beta -HSD and suggesting that DHEA may be preferred over progesterone as a substrate for Xenopus ovarian 3beta -HSD. Finally, radiolabeled AD was very efficiently converted to testosterone (Fig. 6B, middle and right panels), thereby demonstrating the presence of 17beta -HSD in the follicular cells as well. Surprisingly, follicular cells did not hydroxylate progesterone or pregnenolone at all (Fig. 6B, left panel, and data not shown), indicating that ovarian CYP17 activity is contained exclusively in the oocytes themselves.

Because separation of oocytes and follicular cells revealed differential expression of the steroidogenic enzymes, the isolated cell types were recombined to determine whether the complete steroidogenic pathway from pregnenolone to testosterone could be reconstituted. The recombination of follicular cells and oocytes resulted in testosterone production (Fig. 6C), confirming that these two populations of cells were indeed sufficient to mediate complete steroidogenesis. Several intermediate steroids were also produced, including progesterone, DHEA, and AD, suggesting that the reconstituted system was less efficient than the intact ovary in producing testosterone.

Blockade of Androgen Production Attenuates beta -HCG-stimulated Maturation of Xenopus Oocytes in Intact Ovarian Follicles-- To confirm the physiologic importance of CYP17-mediated androgen production in Xenopus oocyte maturation, intact ovarian follicles were stimulated with beta -HCG alone or in combination with the potent CYP17 inhibitor VN/85-1. The maximum amount of oocyte maturation induced by 100 units/ml beta -HCG over 12 h was 47% (Table II, ethanol), which is consistent with more than 8 similar studies using identical conditions (data not shown). This amount of maturation is also similar to that seen when ovarian follicles were treated with 500 nM AD (Table II),2 suggesting that ~50% maturation is likely the maximum attainable under these conditions. Inhibition of CYP17 with VN/85-1 significantly decreased beta -HCG-mediated oocyte maturation by 28%. As expected, VN/85-1 also decreased, but did not eliminate, both testosterone and AD production. Interestingly, although progesterone production increased slightly in the presence of VN/85-1, progesterone levels still remained quite low, suggesting that very little was being produced in vivo, even the presence of a CYP17 inhibitor. This result confirms the data in Fig. 6, where pregnenolone was shown to be inefficiently converted to progesterone by follicular cells. Together, these data suggest that CYP17-mediated androgen production may indeed be important for maturation in vivo. Incomplete inhibition of maturation by VN/85-1 was likely because of induction by the remaining AD and testosterone (which is 10-fold more potent than AD and progesterone (8)), as well as perhaps by the slightly higher amounts of progesterone. Addition of 500 nM AD rescued the inhibitory effects of VN/85-1 by increasing AD and testosterone levels (Table II). Addition of exogenous progesterone also rescued the effects of VN/85-1 by increasing progesterone levels while androgen levels remained low. These data are consistent with earlier work where progesterone promoted maturation of isolated oocytes treated with ketoconazole (8), and suggest that, although low endogenous progesterone production precludes its importance relative to androgens in vivo, exogenous progesterone is still capable of promoting maturation in vitro.

                              
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Table II
Inhibition of beta -HCG-induced oocyte maturation in Xenopus ovaries
Ovarian fragments were treated with 100 units/ml of beta -HCG in the presence of the indicated antagonist and steroids. Steroids were extracted from the medium and mature oocytes were counted after 12 h. Values are expressed as mean ± S.D. (n = 3). Similar experiments were performed 3 times with ovaries from three different frogs with nearly identical results.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Ovarian sex steroid production is essential for follicular growth and subsequent ovulation in nearly every animal (25-27). In frogs and fish, these steroids also appear to be critical regulators of oocyte maturation (28, 29), which is defined as the resumption of meiosis from prophase I to metaphase II. Fish oocyte maturation is regulated by various hydroxylated progesterone metabolites (30, 31), whereas testosterone may be an important physiologic mediator of Xenopus oocyte maturation (8). Sex steroids may be involved in higher vertebrate oocyte maturation as well; however, evidence for or against such a role is still minimal at this point in time.

Sex steroid production requires the cytochrome P450 enzyme CYP17 to catalyze both its 17alpha -hydroxylase and 17,20-lyase reactions, respectively. Whereas all mammalian CYP17 isoforms have relatively equal 17alpha -hydroxylase activities in both the Delta 4 (progesterone) and Delta 5 (pregnenolone) pathways, most have preferential 17,20-lyase activity for one of the two pathways. For example, in small mammals, such as rats (32), mice (33), hamsters (34), and guinea pigs (35), CYP17 is more active in the Delta 4 pathway. In contrast, human and primate CYP17s prefer the Delta 5 pathway (18, 20). We have found that XeCYP17 has high 17,20-lyase activities in both the Delta 4 (progesterone) and Delta 5 (pregnenolone) pathways (Table I), suggesting that, unlike most mammals, Xenopus frog ovaries can utilize both pathways to produce sex steroids. Furthermore, the rate of the XeCYP17-mediated 17,20-lyase reaction equals (HEK-293 cells, Fig. 4D) or exceeds (oocyte membranes, Fig. 3 and Table I) that of the 17alpha -hydroxylase reaction in both pathways. These high lyase activities dramatically contrast with nearly every mammalian isoform of CYP17, where the 17alpha -hydroxylase activities markedly exceed the 17,20-lyase activities (18, 36) (Fig. 5D). Interestingly, the eel, fish, and shark CYP17 enzymes, which are most closely related to XeCYP17 by phylogenetic analysis (Fig. 7), appear to have robust 17,20-lyase activities in both pathways as well (37, 38), although no exact measurements of 17,20-lyase activity have been reported.


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Fig. 7.   CYP17 phylogenetic tree. The neighbor joining method was used to create a CYP17 phylogenetic tree based on amino acid sequence homology (MacVector, Accelrys, San Diego, CA). The x axis represents relative evolutionary distance. See text for details.

Taken together, these data lead us to speculate that the level of CYP17-mediated 17,20-lyase activity, as well the preferential use of one or both (Delta 4 and Delta 5) of the steroidogenic pathways, may reflect the need of the enzyme to produce reproductive steroids versus cortisol in various organisms. In humans, for example, cortisol is essential for normal growth and development. Cortisol is derived primarily from the 21-hydroxylation of 17alpha -hydroxyprogesterone; thus, the relatively low 17,20-lyase activities of human CYP17, which leads to the accumulation of 17alpha -hydroxylated steroids, may be necessary to permit cortisol production in human adrenal glands. In contrast, frogs, as well as sharks, eels, and most fish, do not appear to need cortisol; instead, they rely on corticosterone or corticosterone metabolites as their primary glucocorticoids (39-41). CYP17 is therefore not required for glucocorticoid production in these lower vertebrates; its sole function appears to be to generate sex steroids. In short, CYP17 may have evolved from favoring primarily sex steroid production in lower vertebrates, which do not require cortisol, to promoting both cortisol and sex steroid production in higher vertebrates. Accordingly, the lower vertebrate CYP17s appear to form a closely related phylogenetic family by sequence homology, whereas the more evolved higher vertebrate CYP17s appear to be part of a distinctly separate family of proteins (Fig. 7).

The mechanism behind the unusually high 17,20-lyase activity of XeCYP17 relative to other CYP17 isoforms is an intriguing issue. One clearly important factor that regulates 17,20-lyase activity of human CYP17 is the presence of the co-factor protein cytochrome b5 (18, 42). Perhaps the high 17,20-lyase activity of XeCYP17 is because of differences in the influence of or dependence on cytochrome b5 as a cofactor for this reaction. Alternatively, Xenopus CYP17 may contain sequences that enhance its ability to bind to 17-hydroxylated steroids or other important cofactors. Given its relatively high 17,20-lyase activity, the Xenopus isoform may serve as a useful tool in teasing apart the mechanisms controlling the two enzymatic activities of the CYP17 enzyme.

The exclusive expression of XeCYP17 in oocytes suggests an unusual mechanism of sex steroid production driving oocyte maturation in the frog ovary. Taking into account the results reported in this study, we propose a model for steroid biosynthesis and steroid-induced maturation of oocytes (Fig. 8). In this model, pregnenolone would be produced in the follicular cells. Because pregnenolone is inefficiently converted to progesterone (Fig. 6), even in the presence of a CYP17 inhibitor (Table II), very little progesterone is likely being produced by 3beta -HSD at any time. Because the follicular cells do not express CYP17, pregnenolone must then enter the surrounding oocytes to be converted to DHEA. Additionally, because CYP17 is equally active in the Delta 4 pathway, any small amounts of progesterone that are produced by the follicular cells would be rapidly converted to AD in the oocyte, thus further preventing significant accumulation of progesterone. DHEA and AD would then be transported back to the follicular cells, where 17beta -HSD and 3beta -HSD would complete testosterone synthesis. Finally, testosterone from the follicular cells would re-enter the oocyte to promote its maturation. Because AD is also capable of promoting maturation, one cannot rule out the possibility that AD also plays a role in oocyte maturation in vivo; however, given the significantly higher potency and ovarian concentrations of testosterone relative to AD (8), testosterone is most likely the primary physiologic mediator of maturation in Xenopus oocytes. Although progesterone appears capable of promoting maturation in vitro, the lack of significant progesterone production at all times by beta -HCG-stimulated frog ovaries, even in the presence of a CYP17 inhibitor, argues against a major role for progesterone in oocyte maturation in vivo.


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Fig. 8.   Proposed model for steroid biosynthesis and steroid-induced oocyte maturation in X. laevis ovaries. The dominant pathway is represented in bold. See text for details.

Our model bears some similarity to the two-cell models put forth to explain sex steroid biosynthesis in other systems (43, 44). In this case, we do not actually know how many different cell types exist within our follicular fraction; however, it is quite clear that these cells contain all of the important steroid synthetic enzymes except CYP17, whereas oocytes contain CYP17 but no other relevant activities. It is still possible that our oocyte preparations contain a small population of follicular cells that contain all of the detected CYP17 activity; however, this explanation seems less likely for the following reasons. First, this population of cells would have to be so tightly associated with oocytes that it was completely resistant to separation by both collagenase and trypsin, as the follicular cell preparations contained no detectable CYP17. Second, this contaminating population of cells would have to be very small, as it was undetectable by both stereoscopic and histologic examination. Third, in order for such a small contamination to be mediating the high velocities recorded in Table I, which are very similar to the velocities of other CYP17 enzymes overexpressed in fibroblast or COS cells, as well as with those seen in cultured thecal cells (45-47), the turnover rate of the Xenopus CYP17 would have to be extremely high. We know that this is not the case, as comparison of the human and Xenopus CYP17 17alpha -hydroxylase activities in HEK cells (Fig. 5), and recently in yeast microsomes (data not shown), reveals that they have nearly identical turnover rates (~6 min-1). Finally, progesterone injected directly into oocytes is immediately converted to AD (8), arguing that the enzymatic activity is within the oocyte itself.

We are left with the intriguing notion that, in the frog ovary, germ cells, or oocytes, play a critical role in the production of the steroid used for their own maturation. To our knowledge, this is the first example of germ cells being directly involved in steroid production, although it has not been carefully examined in other lower vertebrates, such as fish. Because oocytes make up >90% of the ovarian volume in frogs and fish, one could speculate that such lower vertebrate animals might require their oocytes to contribute to ovarian sex steroid production. In contrast, higher vertebrates, in which the ovarian volume primarily consists of follicular cells, may no longer need oocytes to subserve this function.

Interestingly, this concept of oocytes actively participating in their own maturation (in our case through the production of androgens) is consistent with the recently described work in mammalian systems, where oocytes have been shown to communicate with surrounding somatic cells to promote granulosa cell proliferation and differentiation (48). Oocytes may therefore utilize many different mechanisms to assist in orchestrating proper follicular development and subsequent ovulation.

Finally, these studies further explain and support earlier work suggesting that, although progesterone is capable of promoting maturation in vitro, androgens may be the primary mediators of maturation in vivo, where very little progesterone is ever produced. Steroid-induced maturation of Xenopus oocytes has been a puzzling field of investigation for many years, as it appears to occur independent of transcription and may involve signaling via classical steroid receptors acting outside of the nucleus (6-8, 49). Further studies of Xenopus oocyte maturation by androgens, in addition to progesterone, may aid in finally determining the details behind this complex and fascinating process.

    ACKNOWLEDGEMENT

We thank Dr. Richard Auchus for valuable advice and input.

    FOOTNOTES

* This work was supported in part by National Institutes of Health Grant DK59913 and Welch Foundation Grant I-1506.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger W. W. Caruth, Jr. Endowed Scholar in Biomedical Research. To whom correspondence should be addressed. Tel.: 214-648-4793; Fax: 214-648-7934; E-mail: stephen.hammes@utsouthwestern.edu.

Published, JBC Papers in Press, January 9, 2003, DOI 10.1074/jbc.M212027200

2 W-H. Yang, L. B. Lutz, and S. R. Hammes, unpublished data.

    ABBREVIATIONS

The abbreviations used are: beta -HCG, beta -human chorionic gonadotropin; AD, androstenedione; DHEA, dehydroepiandrosterone; XeCYP17, Xenopus CYP17; HuCYP17, human CYP17; HSD, hydroxysteroid dehydrogenase; 17OHPreg, 17-hydroxypregnenolone; 17OHProg, 17-hydroxyprogesterone; HEK, human embryonic kidney; MBSH, modified Barth's solution.

    REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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