Characterization of gonadal and extra-gonadal forms of the cDNA encoding the Atlantic stingray (Dasyatis sabina) cytochrome P450 aromatase (CYP19)

New Insights Into the Role of Estrogens in Male Fertility Based on Findings in Aromatase-Deficient Zebrafish

It has been demonstrated that estrogens are indispensable for male fertility in mammals. Aromatase (encoded by CYP19) catalyzes the final step of estradiol biosynthesis. However, less is known about the role of aromatase in male fertility in nonmammalian species. Fish aromatase is encoded by two separate genes: the gonad-specific cyp19a1a and the brain-specific cyp19a1b. In a recent study, we used transcription activatorlike effector nucleases to systematically generate cyp19a1a and cyp19a1b mutant lines and a cyp19a1a;cyp19a1b double-mutant line in zebrafish and demonstrated that cyp19a1a was indispensable for sex differentiation. In this study, we focused on male fertility in these aromatase-deficient zebrafish. Our results showed that all aromatase-deficient male fish had normal fertility even at 1 year after fertilization. Interestingly, we observed more spermatozoa in the cyp19a1a and double-mutant males than in the wild-type and cyp19a1b mutant males. The whole-body androgen levels, follicle-stimulating hormone β and luteinizing hormone β protein levels in the pituitary, and transcript levels of genes known to be involved in spermatogenesis and steroidogenesis in the testes were significantly higher in the cyp19a1a mutant and aromatase double-mutant males than in the wild-type and cyp19a1b mutant males. These results might explain why more spermatozoa were observed in these fish. Collectively, our findings indicate that estrogens are not needed to achieve and maintain normal fertility in male zebrafish. This finding challenges the traditional view that estrogens are indispensable for male fertility.

Targeted Disruption of Aromatase Reveals Dual Functions of cyp19a1a During Sex Differentiation in Zebrafish

Aromatase (encoded by the cyp19a1a and cyp19a1b genes) plays a central role in sex differentiation in fish, but its precise roles during sex differentiation are still largely unknown. Here, we systematically generated cyp19a1a and cyp19a1b mutant lines as well as a cyp19a1a;cyp19a1b double mutant line in zebrafish using transcription activatorlike effector nucleases. Our results showed that cyp19a1a mutants and cyp19a1a;cyp19a1b double mutants, but not cyp19a1b mutants, had impaired sex differentiation, and all cyp19a1a mutants and cyp19a1a;cyp19a1b double mutants were males. During sex differentiation, the ovary-like gonads were not observed and the male sex differentiation program was delayed in the cyp19a1a-null fish, and these phenotypes could be partially rescued by 17β-estradiol treatment. Gene expression analysis indicated that male and female sex differentiation-related genes were significantly decreased in the cyp19a1a mutant. Collectively, our results revealed dual functions of the cyp19a1a gene during sex differentiation: cyp19a1a is not only indispensable for female sex differentiation but also required for male sex differentiation.

Molecular cloning and characterization of brain and ovarian cytochrome P450 aromatase genes in the catfish Heteropneustes fossilis: Sex, tissue and seasonal variation in, and effects of gonadotropin on gene expression

Cytochrome P450 aromatase (Cyp19arom) is the rate-limiting enzyme controlling estrogen biosynthesis, coded by Cyp19a1 in most gnathostomes. Most teleosts have two forms expressed differentially in ovary (cyp19a1a) and neural tissue (cyp19a1b). In this study, full length cDNAs of 2006 bp and 1913 bp with ORFs of 1575 bp and 1488 bp were isolated from the brain and ovary, respectively, of the catfish Heteropneustes fossilis, an air-breathing species with high aquaculture potential. The ORFs encode predicted proteins of 495 and 524 amino acid residues, respectively. The proteins show 62% identity with each other and cluster in two distinct clades (the brain type and ovary type) in the teleost taxon, separated from the tetrapod type. In the in situ localization study, both cyp19a1a and cyp19a1b transcripts were localized in the brain but the signal intensity was higher for the brain type paralog. The transcript signals were observed in the radial glial cells and in neuronal populations of the dorso-lateral region of the telencephalon, pre-tectum, hypothalamus and medulla oblongata. In the ovary, both paralogs were expressed in the follicular layer with a high signal intensity of the ovarian type (cyp19a1a). The differential expression of the gene paralogs was evident from qPCR analysis. Cyp19a1b has relatively a high abundance in the female brain, followed by other peripheral tissues (gonads, liver, gill, kidney and muscle). On the other hand, cyp19a1a has relatively a high transcript abundance in the ovary and female brain, followed by the testis and male brain, and female liver and muscle. The expression was low in male liver and muscle, and the lowest in the gill and kidney. The expression of the two paralogs exhibit brain regional differences; both types have relatively a high transcript abundance in telencephalon-preoptic area with the cyp19a1b expression higher in females than males. In hypothalamus, the expression of both types is higher in males than females. In medulla, the expression of the cyp19a1b is higher than cyp19a1a, and the transcript abundance of the ovarian type is higher in females than males. The expression of the gene paralogs elicits significant seasonal variations in the ovary and brain. In both tissues, the expression increases from the resting to preparatory phases, and decreases through the prespawning phase to low levels in spawning phase. In vivo and/or in vitro treatments with human chorionic gonadotropin (hCG) stimulated the expression of the gene paralogs in the brain and ovary, time-dependently. In conclusion, both paralogs have an overlapping distribution at different levels of the brain-pituitary-gonad axis and may function as a single functional unit as far as the estrogen synthesis is concerned.

Genes encoding aromatases in teleosts: evolution and expression regulation

Cytochrome P450 aromatases, encoded by cyp19a1 genes, catalyzes the conversion of androgens to estrogens and plays important roles in the reproduction of vertebrates. Vertebrate cyp19a1 genes showed high synteny in chromosomal locations and conservation in sequences during evolution. However, amphioxus cyp19a1 does not show synteny to vertebrate cyp19a1. Teleost fish possess two copies of the cyp19a1 gene, which were postulated to result from a fish-specific genome duplication. The duplicated copies of fish cyp19a1 genes evolved into the brain and ovarian forms of cytochrome P450 aromatase genes, cyp19a1a and cyp19a1b, respectively, with different regulatory mechanisms of expression, through subfunctionalization under long-term selective pressure. In addition to the estradiol (E2) auto-regulatory loop, there may be other mechanisms responsible for the high expression of aromatase in the teleost brain. The study of the two cyp19a1 copies in teleost fish will shed light on the general evolution, function, and regulation of vertebrate cyp19a1.

Aromatase, estrogen receptors and brain development in fish and amphibians

Estrogens affect brain development of vertebrates, not only by impacting activity and morphology of existing circuits, but also by modulating embryonic and adult neurogenesis. The issue is complex as estrogens can not only originate from peripheral tissues, but also be locally produced within the brain itself due to local aromatization of androgens. In this respect, teleost fishes are quite unique because aromatase is expressed exclusively in radial glial cells, which represent pluripotent cells in the brain of all vertebrates. Expression of aromatase in the brain of fish is also strongly stimulated by estrogens and some androgens. This creates a very intriguing positive auto-regulatory loop leading to dramatic aromatase expression in sexually mature fish with elevated levels of circulating steroids. Looking at the effects of estrogens or anti-estrogens in the brain of adult zebrafish showed that estrogens inhibit rather than stimulate cell proliferation and newborn cell migration. The functional meaning of these observations is still unclear, but these data suggest that the brain of fish is experiencing constant remodeling under the influence of circulating steroids and brain-derived neurosteroids, possibly permitting a diversification of sexual strategies, notably hermaphroditism. Recent data in frogs indicate that aromatase expression is limited to neurons and do not concern radial glial cells. Thus, until now, there is no other example of vertebrates in which radial progenitors express aromatase. This raises the question of when and why these new features were gained and what are their adaptive benefits. This article is part of a Special Issue entitled: Nuclear receptors in animal development.

Molecular players involved in temperature-dependent sex determination and sex differentiation in Teleost fish

The molecular mechanisms that underlie sex determination and differentiation are conserved and diversified. In fish species, temperature-dependent sex determination and differentiation seem to be ubiquitous and molecular players involved in these mechanisms may be conserved. Although how the ambient temperature transduces signals to the undifferentiated gonads remains to be elucidated, the genes downstream in the sex differentiation pathway are shared between sex-determining mechanisms. In this paper, we review recent advances on the molecular players that participate in the sex determination and differentiation in fish species, by putting emphasis on temperature-dependent sex determination and differentiation, which include temperature-dependent sex determination and genetic sex determination plus temperature effects. Application of temperature-dependent sex differentiation in farmed fish and the consequences of temperature-induced sex reversal are discussed.

Neural and hormonal mechanisms of reproductive-related arousal in fishes

The major classes of chemicals and brain pathways involved in sexual arousal in mammals are well studied and are thought to be of an ancient, evolutionarily conserved origin. Here we discuss what is known of these neurochemicals and brain circuits in fishes, the oldest and most species-rich group of vertebrates from which tetrapods arose over 350 million years ago. Highlighted are case studies in vocal species where well-delineated sensory and motor pathways underlying reproductive-related behaviors illustrate the diversity and evolution of brain mechanisms driving sexual motivation between (and within) sexes. Also discussed are evolutionary insights from the neurobiology and reproductive behavior of elasmobranch fishes, the most ancient lineage of jawed vertebrates, which are remarkably similar in their reproductive biology to terrestrial mammals.

Ovarian aromatase and estrogens: a pivotal role for gonadal sex differentiation and sex change in fish

The present review focuses on the roles of estrogens and aromatase (Cyp19a1a), the enzyme needed for their synthesis, in fish gonadal sex differentiation. Based on the recent literature, we extend the already well accepted hypothesis of an implication of estrogens and Cyp19a1a in ovarian differentiation to a broader hypothesis that would place estrogens and Cyp19a1a in a pivotal position to control not only ovarian, but also testicular differentiation, in both gonochoristic and hermaphrodite fish species. This working hypothesis states that cyp19a1a up-regulation is needed not only for triggering but also for maintaining ovarian differentiation and that cyp19a1a down-regulation is the only necessary step for inducing a testicular differentiation pathway. When considering arguments for and against, most of the information available for fish supports this hypothesis since either suppression of cyp19a1a gene expression, inhibition of Cyp19a1a enzymatic activity, or blockage of estrogen receptivity are invariably associated with masculinization. This is also consistent with reports on normal gonadal differentiation, and steroid-modulated masculinization with either androgens, aromatase inhibitors or estrogen receptor antagonists, temperature-induced masculinization and protogynous sex change in hermaphrodite species. Concerning the regulation of fish cyp19a1a during gonadal differentiation, the transcription factor foxl2 has been characterized as an ovarian specific upstream regulator of a cyp19a1a promoter that would co-activate cyp19a1a expression, along with some additional partners such as nr5a1 (sf1) or cAMP. In contrast, upstream factors potentially down-regulating cyp19a1a during testicular differentiation are still hypothetical, such as the dmrt1 gene, but their definitive characterization as testicular repressors of cyp19a1a would strongly strengthen the hypothesis that early testicular differentiation would need active repression of cyp19a1a expression.

Comparative transcriptomic analysis of follicle-enclosed oocyte maturational and developmental competence acquisition in two non-mammalian vertebrates

BACKGROUND

In vertebrates, late oogenesis is a key period during which the oocyte acquires its ability to resume meiosis (i.e. maturational competence) and to develop, once fertilized, into a normal embryo (i.e. developmental competence). However, the molecular mechanisms involved in these key biological processes are far from being fully understood. In order to identify key mechanisms conserved among teleosts and amphibians, we performed a comparative analysis using ovarian tissue sampled at successive steps of the maturational competence acquisition process in the rainbow trout (Oncorhynchus mykiss) and in the clawed toad (Xenopus laevis). Our study aimed at identifying common differentially expressed genes during late oogenesis in both species. Using an existing transcriptomic analysis that had previously been carried out in rainbow trout, candidate genes were selected for subsequent quantitative PCR-based comparative analysis.

RESULTS

Among the 1200 differentially expressed clones in rainbow trout, twenty-six candidate genes were selected for further analysis by real-time PCR in both species during late oogenesis. Among these genes, eight had similar expression profiles in trout and Xenopus. Six genes were down-regulated during oocyte maturation (cyp19a1, cyp17a1, tescalcin, tfr1, cmah, hsd11b3) while two genes exhibited an opposite pattern (apoc1, star). In order to document possibly conserved molecular mechanisms, four genes (star, cyp19a1, cyp17a1 and hsd11b3) were further studied due to their known or suspected role in steroidogenesis after characterization of the orthology relationships between rainbow trout and Xenopus genes. Apoc1 was also selected for further analysis because of its reported function in cholesterol transport, which may modulate steroidogenesis by regulating cholesterol bioavailability in the steroidogenic cells.

CONCLUSIONS

We have successfully identified orthologous genes exhibiting conserved expression profiles in the ovarian follicle during late oogenesis in both trout and Xenopus. While some identified genes were previously uncharacterized during Xenopus late oogenesis, the nature of these genes has pointed out molecular mechanisms possibly conserved in amphibians and teleosts. It should also be stressed that in addition to the already suspected importance of steroidogenesis in maturational competence acquisition, our approach has shed light on other regulatory pathways which may be involved in maturational and developmental competence acquisitions that will require further studies.

Alternative 5'-untranslated first exons of the mouse Cyp19A1 (aromatase) gene

The human aromatase gene (CYP19A1) has eleven tissue-specific untranslated first exons, while only three have been described in the mouse Cyp19A1 namely brain-, ovary- and testis-specific exons 1. The present study aims to elucidate the complete structure of the mouse Cyp19A1 gene. We detected aromatase transcripts in mouse bone, aorta, hypothalamus, adipose, gonads and placenta, but not nulliparous mammary fat pad. BestFit algorithm analysis against the human CYP19A1 has identified ten putative first exons upstream of mouse Cyp19A1. Based on these putative sequences, we were able to design specific primers for RT-PCR and detected for the first time, the presence of exons I.4 and I.3 in murine fat and gonads, respectively. These are novel 5'UTRs of mouse Cyp19A1. Using RT-PCR and 5' RACE, we confirmed the expression of exon 1f in the hypothalamus and proximal exon P2 in the ovary. The testis-specific exon 1 begins 217bp further upstream than previously reported. Putative exons 2a, I.5, I.7, I.6 and I.2 were not detected in mouse tissues. Therefore, we showed that mouse Cyp19A1 contains more tissue-specific first exons than previously thought and displays a similar genomic organization to human CYP19A1.

Interference of endocrine disrupting chemicals with aromatase CYP19 expression or activity, and consequences for reproduction of teleost fish

Many natural and synthetic compounds present in the environment exert a number of adverse effects on the exposed organisms, leading to endocrine disruption, for which they were termed endocrine disrupting chemicals (EDCs). A decrease in reproduction success is one of the most well-documented signs of endocrine disruption in fish. Estrogens are steroid hormones involved in the control of important reproduction-related processes, including sexual differentiation, maturation and a variety of others. Careful spatial and temporal balance of estrogens in the body is crucial for proper functioning. At the final step of estrogen biosynthesis, cytochrome P450 aromatase, encoded by the cyp19 gene, converts androgens into estrogens. Modulation of aromatase CYP19 expression and function can dramatically alter the rate of estrogen production, disturbing the local and systemic levels of estrogens. In the present review, the current progress in CYP19 characterization in teleost fish is summarized and the potential of several classes of EDCs to interfere with CYP19 expression and activity is discussed. Two cyp19 genes are present in most teleosts, cyp19a and cyp19b, primarily expressed in the ovary and brain, respectively. Both aromatase CYP19 isoforms are involved in the sexual differentiation and regulation of the reproductive cycle and male reproductive behavior in diverse teleost species. Alteration of aromatase CYP19 expression and/or activity, be it upregulation or downregulation, may lead to diverse disturbances of the above mentioned processes. Prediction of multiple transcriptional regulatory elements in the promoters of teleost cyp19 genes suggests the possibility for several EDC classes to affect cyp19 expression on the transcriptional level. These sites include cAMP responsive elements, a steroidogenic factor 1/adrenal 4 binding protein site, an estrogen-responsive element (ERE), half-EREs, dioxin-responsive elements, and elements related to diverse other nuclear receptors (peroxisome proliferator activated receptor, retinoid X receptor, retinoic acid receptor). Certain compounds including phytoestrogens, xenoestrogens, fungicides and organotins may modulate aromatase CYP19 activity on the post-transcriptional level. As is shown in this review, diverse EDCs may affect the expression and/or activity of aromatase cyp19 genes through a variety of mechanisms, many of which need further characterization in order to improve the prediction of risks posed by a contaminated environment to teleost fish population.

Tissue-specific transcriptional initiation of the CYP19 genes in rainbow trout, with analysis of splicing patterns and promoter sequences

The rainbow trout (Oncorhynchus mykiss Walbaum) genome contains three separate CYP19 genes for distinct isoforms of cytochrome P450arom: CYP19A encoding the prevalently ovarian isoform P450aromA, and CYP19B-I and II, encoding forms I and II of the mainly cerebral variant P450aromB. RNA Ligase-Mediated 5'-Rapid Amplification of cDNA Ends analysis was used to determine the 5'-untranslated terminal regions (5'-UTRs) of the corresponding mRNAs, which are actually all expressed in the ovary, brain and gills. CYP19A is transcribed at different transcription start sites (TSSs) in each tissue, the most distal TSS being found in the brain, the intermediate one in the gills, and the proximal one in the ovary. CYP19B-I also displays tissue-specific TSSs, but transcripts undergo three distinct splicing patterns: the same pattern as previously reported for the brain and occurring also in the gills, and two novel patterns, established in the ovary and brain, which include two cryptic 3'-splice sites in intron 1, leading to the inclusion of intronic sequences of 92/94 and 66 b in the 5'-UTRs. Lastly, the CYP19B-II transcript in the ovary shows the same splicing pattern previously described for the brain. A PCR-based gene walking strategy was used to explore the promoter regions of the rainbow trout CYP19 genes, which were found to contain potential binding sites for a variety of transcription factors.

Brain aromatase: new lessons from non-mammalian model systems

This review highlights recent studies of the anatomical and functional implications of brain aromatase (estrogen synthase) expression in two vertebrate lineages, teleost fishes and songbirds, that show remarkably high levels of adult brain aromatase activity, protein and gene expression compared to other vertebrate groups. Teleosts and birds have proven to be important neuroethological models for investigating how local estrogen synthesis leads to changes in neural phenotypes that translate into behavior. Region-specific patterns of aromatase expression, and thus estrogen synthesis, include the vocal and auditory circuits that figure prominently into the life history adaptations of vocalizing teleosts and songbirds. Thus, by targeting, for example, vocal motor circuits without inappropriate steroid exposure to other steroid-dependent circuits, such as those involved in either copulatory or spawning behaviors, the neuroendocrine system can achieve temporal and spatial specificity in its modulation of neural circuits that lead to the performance of any one behavior.

Cloning and functional characterization of a second urea transporter from the kidney of the Atlantic stingray, Dasyatis sabina

The cloning of cDNAs encoding facilitated urea transporters (UTs) from the kidneys of the elasmobranchs indicates that in these fish renal urea reabsorption occurs, at least in part, by passive processes. The previously described elasmobranch urea transporter clones from shark (shUT) and stingray (strUT-1) differ from each other primarily because of the COOH-terminus of the predicted strUT-1 translation product being extended by 51-amino acid residues compared with shUT. Previously, we noted multiple UT transcripts were present in stingray kidney. We hypothesized that a COOH terminally abbreviated UT isoform, homologous to shUT, would also be present in stingray kidney. Therefore, we used 5'/3' rapid amplification of cDNA ends to identify a 3'UTR-variant (strUT-1a) of the cDNA that encodes (strUT-1), as well as three, 3'UTR-variant cDNAs (strUT-2a,b,c) that encode a second phloretin-sensitive, urea transporter (strUT-2). The 5'UTR and the first 1,132 nucleotides of the predicted coding region of the strUT-2 cDNAs are identical to the strUT-1 cDNAs. The remainder of the coding region contains only five novel nucleotides. The strUT-2 cDNAs putatively encode a 379-amino acid protein, the first 377 amino acids identical to strUT-1 plus 2 additional amino acids. We conclude that 1) a second UT isoform is expressed in the Atlantic stingray and that this isoform is similar in size to the UT previously cloned from the kidney of the dogfish shark, and 2) at least five transcripts encoding the 2 stingray UTs are derived from a single gene product through alternative splicing and polyadenylation.

Molecular Biology of Ovarian Aromatase in Sex Reversal: Complementary DNA and 5′-Flanking Region Isolation and Differential Expression of Ovarian Aromatase in the Gilthead Seabream (Sparus aurata)1

To elucidate the involvement of aromatase in sex reversal, the gilthead seabream ovarian P450 aromatase (cyp19a1a) cDNA and its 5'-flanking region were isolated and characterized. Northern blot analysis revealed that only one cyp19a1a transcript (2.0 kb) is expressed in the ovary. Four cAMP-responsive elements were identified at the 5'-flanking region of seabream cyp19a1a indicating a high potential to respond to gonadotropin signaling. Studying the seasonal profile, two expression peaks of cyp19a1a transcripts in the ovarian tissues were found in July (about 15000 copies/ng total RNA) for ambisexual fish and in December (about 12000 copies/ng total RNA) for spawning females. Starting from September, transcript levels of cyp19a1a in the ovarian portions of the male-developing gonads gradually decreased. Furthermore, the ovarian portions of the female gonads expressed cyp19a1a at a significantly higher level than the ovarian portions of the male gonads after November. Taken together with levels of plasma estradiol in reversing females being significantly higher than those in developing males, the above results reinforce the importance of cyp19a1a in sex reversal. In vitro exposure of ovarian fragments to gonadotropins (hCG) at 1, 10, and 100 IU/ml significantly (P < 0.05) upregulated cyp19a1a expression. Additionally, expression of cyp19a1a displayed a stronger and significant correlation with the transcript expression of ovarian Lh receptor rather than Fsh receptor during the ambisexual stage. Our results indicate that the differential expression of cyp19a1a gene is associated with sex reversal and that gonadotropin signals (particularly Lh) may serve as major players in regulating the expression of cyp19a1a during the process of sex reversal.

Differential expression of neural and gonadal aromatase enzymatic activities in relation to gonadal development in Japanese eel, Anguilla japonica

The objectives of the present study were to investigate the enzymatic characteristics of brain aromatase in Japanese eel, Anguilla japonica, as well as the correlations between aromatase activities in various tissues (brain regions, pituitary, and gonads) and ovarian development. Eel brain aromatase exhibited a K(m) of 75 nM and a V(max) of 1.14 fmol/min mg protein (91.5 fmol/h mg protein), indicating an enzymatic activity much lower than in other teleosts but similar to that in mammals. This supports the hypothesis of the occurrence of a single aromatase gene in eels (representative of an ancient group of teleosts, Elopomorphs), as in mammals, but unlike what is observed in more recent teleosts. Aromatase inhibitors could significantly suppress brain and pituitary aromatase activity. There was no significant sex difference in aromatase activity in the forebrain, midbrain, hindbrain, or pituitary, but there was in the gonads, where aromatase could be detected in the ovaries but not in the testes, in accordance with the role of this enzyme in ovarian differentiation. Comparison with another teleost, black porgy (Percomorph), under the same experimental conditions, further confirmed the low activity of aromatase in the eel. We investigated variations in brain, pituitary, and gonad aromatase activity in relation to ovarian development in control female eels (gonadosomatic index, GSI, 0.1-1.6%) as well as in eels treated with pituitary extract (experimental ovarian maturation; GSI up to 25%). Differential expression of neural and gonadal aromatase was observed in relation to the course of gonadal development. Pituitary aromatase activity increased with GSI at all stages. Brain (specially forebrain) aromatase activity significantly increased in early vitellogenic control eels (GSI>0.8%) and in treated eels. The low activity of eel aromatase may be related to the characteristic life cycle of the eel, in which there is a long delay of the onset of puberty before oceanic reproductive migration.

The genomic environment around the Aromatase gene: evolutionary insights

Background

The cytochrome P450 aromatase (CYP19), catalyses the aromatisation of androgens to estrogens, a key mechanism in vertebrate reproductive physiology. A current evolutionary hypothesis suggests that CYP19 gene arose at the origin of vertebrates, given that it has not been found outside this clade. The human CYP19 gene is located in one of the proposed MHC-paralogon regions (HSA15q). At present it is unclear whether this genomic location is ancestral (which would suggest an invertebrate origin for CYP19) or derived (genomic location with no evolutionary meaning). The distinction between these possibilities should help to clarify the timing of the CYP19 emergence and which taxa should be investigated.

Results

Here we determine the "genomic environment" around CYP19 in three vertebrate species Homo sapiens, Tetraodon nigroviridis and Xenopus tropicalis. Paralogy studies and phylogenetic analysis of six gene families suggests that the CYP19 gene region was structured through "en bloc" genomic duplication (as part of the MHC-paralogon formation). Four gene families have specifically duplicated in the vertebrate lineage. Moreover, the mapping location of the different paralogues is consistent with a model of "en bloc" duplication. Furthermore, we also determine that this region has retained the same gene content since the divergence of Actinopterygii and Tetrapods. A single inversion in gene order has taken place, probably in the mammalian lineage. Finally, we describe the first invertebrate CYP19 sequence, from Branchiostoma floridae.

Conclusion

Contrary to previous suggestions, our data indicates an invertebrate origin for the aromatase gene, given the striking conservation pattern in both gene order and gene content, and the presence of aromatase in amphioxus. We propose that CYP19 duplicated in the vertebrate lineage to yield four paralogues, followed by the subsequent loss of all but one gene in vertebrate evolution. Finally, we suggest that agnathans and lophotrocozoan protostomes should be investigated for the presence of aromatase.

Molecular cloning of cytochrome P450 aromatases in the protogynous wrasse, Halichoeres tenuispinis

P450 aromatase (P450arom, CYP19), a CYP19 gene product, is a member of the cytochrome P450 superfamily that catalyzes the formation of aromatic C(18) estrogen from C(19) androgen. To begin to understand the molecular mechanisms of P450 aromatase action in the protogynous wrasse, we isolated two cDNAs: one encoding CYP19a from ovary and the other encoding CYP19b from brain. The full-length cDNA of wrasse CYP19a, isolated from ovary cDNA library, is 2020 bp long and encodes 519 amino acids. The amino acid sequence of CYP19a has 62-83% identity with ovary-type aromatases of other teleosts. The full-length cDNA of wrasse CYP19b obtained using 5' and 3' RACE consists of 2666 bp, and its open reading frame encodes 496 amino acids. The deduced amino acid sequence has 62-83% identity with brain-type aromatases of other teleosts. Northern blot analysis identified a single 2.2-kb transcript in the ovary (CYP19a), and a single 2.6-kb transcript in the brain (CYP19b), suggesting that there are single forms of CYP19a and CYP19b, respectively, in the wrasse. RT-PCR assay showed that two CYP19 genes were expressed ubiquitously in various tissues, although each CYP19 subtype was expressed at highest level in the ovary and brain of the wrasse. These results suggest that CYP19 genes act in diverse tissue types, in addition to their effects on the physiological and reproductive functions of estrogen.

Relationships between aromatase and estrogen receptors in the brain of teleost fish

Teleost fish are known for exhibiting a high aromatase activity mainly due to the expression of the cyp19b gene, encoding aromatase B (AroB). Recent studies based on both in situ hybridization and immunohistochemistry have demonstrated in three different species that this activity is restricted to radial glial cells. In agreement with measurements of aromatase activity, such aromatase-expressing cells are more abundant in the telencephalon, preoptic area, and mediobasal hypothalamus, although positive cells are also found in the midbrain and hindbrain. Comparative distribution of AroB and estrogen receptor (ERalpha, ERbeta1, and ERbeta2) expression indicates that the preoptic region and hypothalamus are major target for locally produced estradiol (E2) which is likely involved in controlling expression of genes implicated in neuroendocrine regulations. However, AroB and ER have never been reported to be co-expressed in the same cells which is intriguing given that, at least in some species, AroB is strongly up-regulated by E2 itself in agreement with the presence of an estrogen-responsive element (ERE) in the proximal promoter of the cyp19b gene. In vivo data in zebrafish have shown that E2 up-regulates AroB only in radial glial cells. This is in agreement with in vitro transfection experiments indicating that this ERE is functional, but not sufficient, as the E2 regulation of AroB only occurs in glial cell contexts, suggesting a cooperation between ER and so far unidentified glial-specific factors. These data also suggest that radial glial cells may express low amounts of ER that escaped detection until now. The expression of AroB in radial cells, well known for their roles in neurogenesis and now considered as progenitor cells, suggests that local E2 production within these cells could influence the well-documented capacity of the brain of teleosts to grow during adulthood.

Two types of aromatase with different encoding genes, tissue distribution and developmental expression in Nile tilapia (Oreochromis niloticus)

We isolated a novel type of aromatase cDNA from a Nile tilapia (Oreochromis niloticus) ovary cDNA library. Because this aromatase is phylogenetically related to brain aromatase (CYP19b) of goldfish, zebrafish and sea bass, we named it tilapia CYP19b (tCYP19b). tCYP19b encodes a protein that is predicted to consist of 495 residues and have 63.8% homology with the aromatase (tCYP19a) we previously isolated from the same source. In vitro transient transfection of cultured COS7 cells demonstrated that tCYP19b codes a functional protein to catalyze estrogen production from an androgen substrate. RT-PCR and Northern hybridization analysis showed that tCYP19b was expressed at a high level in the brain and at a low level in a wide variety of other tissues, whereas tCYP19a was mainly present in the ovary and its level significantly increased during the vitellogenic stage. RT-PCR also detected tCYP19b expression in brain and gonad tissues of both female and male tilapia during sex differentiation, but tCYP19a was only found in the ovary of the fry at that period. These results suggest that tCYP19a plays a key role in sex differentiation and ovarian development. We also isolated genes of two tilapia aromatases. Based on the location of the transcription initiation site, we predicted that there is one promoter for tCYP19a and three promoters for tCYP19b. Although the two aromatase isoforms have similar gene structures in the coding region, we found that the binding regions of SF-1/Ad4 BP region, WT1-KTS and SRY, which are sex-determining factors in mammals, are present in the 5' flank region of tCYP19a but not tCYP19b. A similar situation is present in promoters of zebrafish and goldfish aromatase isoforms. This data indicates that CYP19a plays a decisive role in sex differentiation of those species. The unique presence of the ERE motif in the tCYP19b promoter and the high expression of tCYP19b in the brain support that CYP19b is mainly involved in estrogen-mediated neural estrogen synthesis.

Aromatase distribution and regulation in fish

Cytochrome P450 aromatase is the enzyme complex responsible for the synthesis of estrogens by the aromatization of androgens. In the vast majority of tetrapods examined so far, aromatase is the product of the Cyp19 gene, which exists as a single copy per haploid genome. In contrast, in teleosts there are two isoforms of the aromatase gene, Cyp19a and Cyp19b, which encode two structurally different proteins, P450aromA and P450aromB, respectively, with similar catalytic activities. The promoter region of both genes has been characterized in several teleost species and more than 20 different regulatory sites have been identified to date. These include response elements for members of the nuclear receptor superfamily, notably sex steroid receptors, and at least five transcription factors related to neurogenesis. This supports the idea that, besides other functions such as the control of reproduction, aromatase and therefore estrogens are actively involved in neurogenesis. Aromatase mRNA expression studies revealed that P450aromA and P450aromB are preferentially, but not exclusively, expressed in the gonads and brain, respectively. Other organs and tissues where aromatase is expressed, albeit at much lower levels include the pituitary, retina, anterior kidney, testis, liver and visceral fat, suggesting local actions of estrogens in several peripheral targets. Gene expression levels are usually matched by actual catalytic activity, with K (m) usually in the range 5-50 nM and V (max) in the order of a few pmol/mg protein/h. The current challenge is to understand the regulation of both aromatase genes, especially in the context of sex differentiation and as a response to environmental factors, including temperature, social interactions, and endocrine disruptors, which is briefly reviewed. It is also important to gain a better understanding of the specific functions of estrogen in different tissues and key developmental and reproductive events throughout the fish life.

Genomic organization of the CYP19b genes in the rainbow trout (Oncorhynchus mykiss Walbaum)

We report the occurrence of two CYP19b genes, namely CYP19b-I and CYP19b-II, encoding forms I and II of cytochrome P450aromB, the prevalently cerebral variant of aromatase in fish, in the nuclear genome of the rainbow trout. The CYP19b-I gene is 7.6 kbp-long, more than double the size of the known fish CYP19a and b genes, owing to the presence of three introns (1, 4 and 5) that enclose repeated sequences and are longer than 1 kbp. Unlike the CYP19a genes, but similarly to the CYP19b gene of the Nile tilapia, it contains 10, and not 9, exons, including an untranslated exon 1 (83 bp), as found also in the 5' non-coding region of mammalian CYP19 genes. The 5'-UTR is composed by exon 1 and the first 41 bp of exon 2 (150 bp), whose coding region covers the first 36 amino acid residues that incorporate the transmembrane domain. The CYP19b-II gene is only 2.5 kbp-long, because it contains only one intron, corresponding to the third intron of CYP19b-I, and lacks also its first two exons. Thus, it encodes for a presumably soluble protein. Apart from this difference, the rest of the coding region is virtually the same as that of the CYP19b-I gene. The 5'-UTR corresponds in part to the 3'-end (132 bp) of the second intron of the CYP19b-I gene, while the remaining portion (208 bp) bears no homology. CYP19b-II could be regarded as a pseudogene of the CYP19b-I gene, though it is unclear whether it is a processed or a duplicated pseudogene. Moreover, since it is transcriptionally active, it may retain a functional role for the overall brain aromatase activity in the rainbow trout.

Sequence and expression of cytochrome P450 aromatase and FTZ-F1 genes in the protandrous black porgy (Acanthopagrus schlegeli)

In this study, a cDNA encoding cytochrome P450 aromatase (P450arom) was cloned from black porgy Acanthopagrus schlegeli ovary. The deduced amino acid sequence had high homology with ovarian P450arom of other teleost fish. Moreover, we partially cloned two FTZ-F1 homologues (asff1a and asff1b) from black porgy. Comparative sequence analysis grouped asff1a and asff1b in NR5A2 and NR5A4 clades, respectively. Among the various tissues tested, P450arom mRNA was highly expressed in the ovary and weakly in the brain and testis, asff1a was expressed in brain, liver, intestine, kidney, testis, and ovary, asff1b was expressed in brain, kidney, testis, and ovary. The transcript levels of P450arom, asff1a, and asff1b were measured in the ovary and testis of 1+ -year-old, 2+ -year-old, and 5+ -year-old black porgy. The transcript level of P450arom in the ovary of 2+ -year-old fish was significantly higher than those of 1+ -year-old and 5+ -year-old fish. The results suggest that P450arom gene may be involved in the mechanism of natural sex change of protandrous black porgy. No change in ovarian expression of asff1a or asff1b was observed among different ages. These results suggest that up-regulation of the transcript levels of P450arom during the course of natural sex change of black porgy was not regulated via FTZ-F1.

Cloning and developmental expression of the cytochrome P450 aromatase gene (CYP19) in the European eel (Anguilla anguilla)

To characterize the involvement of the aromatase gene during the process of sex determination in the European eel (Anguilla anguilla), the expression of its gonadal form was determined during various developmental stages. The cloned cDNA from the European eel gonad (EeCYP19) contains an open reading frame of 1539 bp, encoding a deduced protein of 513 residues. The predicted amino acid sequence shows 97% identity with that of the Japanese eel, and 59-69% of identity with those of the CYP19 gonadal and brain forms of other teleost fish. Two potential initiation sites (ATG) were found downstream of the first ATG codon. A fluorescent-based method of real-time PCR was developed to quantify EeCYP19 expression. The expression levels of EeCYP19 in the gonads of adult males were approximately 12- and 30-fold lower than the levels in adult females and juvenile eels previously treated with E2, respectively. Expression of aromatase was found only in a single specimen in the control group. In contrast, no difference was found among sexes in the aromatase expression in the brain. Treatment with aromatase inhibitor (AI) of juvenile eel resulted in the total loss of aromatase expression in the gonads and brains. The results of this work revealed that AI treatment not only reduces the synthesis of estradiol, but reduces the expression levels of EeCYP19 as well. No evidence for the presence of a distinct extra-gonadal (brain) form of aromatase in the European eel could be provided.

Two distinct cytochrome P450 aromatases in the orange-spotted grouper (Epinephelus coioides): cDNA cloning and differential mRNA expression

The cDNA sequences encoding two distinct cytochrome P450 aromatases, namely P450aromB and P450aromA, were isolated from brain and ovary cDNA libraries of the orange-spotted grouper, respectively. The P450aromB cDNA consists of 1892 bp, and the open reading frame (ORF) encodes a putative protein of 506 amino acids. The P450aromA cDNA consists of 1836 bp, and the ORF encodes a putative protein of 518 amino acids. Northern blot analysis revealed a transcript of about 1.9 kb for P450aromB in the brain and kidney, and 2.1 kb for P450aromA in the ovary. The expression of both P450aromB and P450aromA genes in different tissues was further examined using one-step RT-PCR followed by Southern blot analysis. High levels of P450aromB mRNA expression were detected in the olfactory bulb, forebrain, midbrain, hypothalamus, medulla, pituitary, gill filament, gill arch, kidney, muscle, adipose tissue, and blood cells, but low levels in the hindbrain and ovary. High levels of P450aromA mRNA expression were detected in the ovary, pituitary, gill filament, gill arch, and spleen, but low levels in the forebrain, hindbrain, hypothalamus, and blood cells. In addition, the expression of P450arom genes in the orange-spotted grouper of different gonadal stages as induced by 17 alpha-methyltestosterone (MT) was investigated. The mRNA expression of P450aromB in the hypothalamus was highest in the intersexual stage, whereas the mRNA expression of P450aromA in the gonads was highest in the female stage, decreased in the intersexual stage, and lowest in the male stage. Results from current study indicate that P450aromB and P450aromA genes of the orange-spotted grouper have distinct tissue patterns of mRNA expression, and both of them may be involved in the MT-induced sex change.

Characterization of two types of cytochrome P450 aromatase in the serial-sex changing gobiid fish, Trimma okinawae

To investigate the role of estrogen in the serial-sex changing fish Trimma okinawae, we isolated complementary DNAs encoding two distinct cytochrome P450 aromatase isoforms from adult ovary and brain (termed P450aromA and P450aromB, respectively). Sequence and phylogenic analyses showed that the goby P450arom forms belong to two separate CYP19 subfamilies. Transient expression of these cDNAs in HEK293 cells caused conversion of exogenous testosterone to estradiol-17beta. RT-PCR showed that P450aromA was expressed in the brain, spleen, testis and ovary. P450aromB was expressed in the brain, liver, testis and ovary. In situ hybridization studies showed that P450aromA mRNA, but not P450aromB mRNA, was present in both ovary and testis. Positive signals were restricted to granulosa cells of vitellogenic follicles and interstitial cells of mature testis. Ovarian expression of both P450arom genes during the spawning cycle was examined by quantitative real-time RT-PCR. P450aromA transcripts increased during vitellogenesis and decreased prior to spawning. In contrast, P450aromB transcripts were barely detectable and did not correlate with ovarian development. These findings suggest that P450aromA, but not P450aromB, is involved in regulating ovarian vitellogenesis in goby.

Cloning, sequence analysis, tissue distribution, and sex-specific expression of the neural form of P450 aromatase in juvenile sea bass (Dicentrarchus labrax)

The teleost brain is characterized by exceptionally high levels of aromatase, the enzyme that converts androgens into estrogens, and by its continuous growth throughout life. Gonadal estrogens have been implicated in sex differentiation and the control of reproduction in adult fish, but the role of neural estrogens during early development is far from clear. The present study describes the isolation and characterization of the cDNA sequence from brain aromatase (P450aromB) in the European sea bass (Dicentrarchus labrax L.), a well established model for neuroendocrine research in fish. P450aromB was cloned from a brain cDNA library and encoded a predicted protein of 505 residues, with a calculated molecular weight of 57.2 kDa. Comparisons of the deduced amino acid sequence to that of the ovarian aromatase (P450aromA) in the same species revealed 62% identity, lower than the 84% identity shared between sea bass and tilapia brain aromatases. Phylogenetic analysis showed the occurrence of a gene duplication for P450arom in the teleost lineage after its divergence from the tetrapods. Moreover, the low percentage of identity between brain and ovarian forms within the same species suggests that both genes evolved separately right after the appearance of the teleosts. Tissue-specific expression of P450aromA and P450aromB mRNA was studied in adult sea bass. P450aromB was preferentially expressed in brain of both males and females but also present at much lower levels in testis, ovary and head kidney, an organ known for its steroidogenic capabilities in fish. However, P450aromA expression was restricted to testis and ovary. A semiquantitative PCR was developed to measure P450aromB mRNA levels. Analysis of the expression of P450aromB in the brain of juvenile sea bass showed that females exhibited higher mRNA levels than males at 200 days post fertilization (dpf), by the time of gonadal sex differentiation. A switch in expression occurred thereafter, between 200 and 250 dpf, with males exhibiting higher levels than females. This situation was maintained by 300 dpf and is in agreement with measured levels of enzymatic activity in adults. These changes and sex-related differences in expression profiles may imply differences in the functionality of the enzyme between males and females, suggesting an important role for P450aromB in sea bass sex differentiation. However, due to the continuous growth of the teleost brain throughout life, a role in neurogenesis for brain aromatase should also be considered.

Characterization of a cDNA encoding P-450 aromatase (CYP19) from Japanese eel ovary and its expression in ovarian follicles during induced ovarian development

A cDNA encoding P450 aromatase (CYP19) was isolated from a Japanese eel (Anguilla japonica) ovarian cDNA library. This cDNA contains a complete open reading frame encoding 511 amino acid residues. The deduced amino acid sequence is 59% and 65% identical to the catfish and rainbow trout forms, respectively, and 52-54% to mammalian and chicken forms. Non-steroidogenic COS-7 cells transfected with the eel CYP19 cDNA converted exogenous androstenedione to estrone, thus verifying its identity. Northern blot analysis indicated that there was a single 2.1 kb transcript in the ovary. A 2.1 kb transcript was also found in the brain but not in the spleen, head kidney, kidney, or liver. Throughout ovarian development induced by weekly injections of salmon pituitary homogenate (SPH, 20 microg/g body weight), the 2.1 kb transcript was barely or not detectable in the ovaries. However, signals greatly increased in intensity in oocytes in the migratory nucleus stage and then decreased slightly in the post-ovulatory ovary. These changes in transcript levels are consistent with the changes in aromatase activity of ovarian follicles, suggesting that aromatase activity in ovarian follicles is mainly regulated at the transcriptional level. In addition, fadrozole was found to significantly inhibit aromatase activity in a heterologous expression system using COS-7 cells, which indicates that fadrozole treatment could be useful to control E(2) production during artificial maturation of eels.

European sea bass (Dicentrarchus labrax L.) cytochrome P450arom: cDNA cloning, expression and genomic organization

Cytochrome P450arom, a key enzyme in the hormonal steroidogenic pathway, mediates the conversion of androgens to estrogens. This work describes the molecular cloning of the cDNA encoding the European sea bass (Dicentrarchus labrax L.) cytochrome P450arom by means of reverse transcriptase and polymerase chain reaction (RT-PCR) and 5' and 3'-rapid amplification of cDNA ends (RACE) analyses. The cDNA is 1822bp in length and encodes a putative protein of 517 amino acids. Northern blot analysis revealed that the ovary expressed a transcript of about 2.2kb in size. Analysis of the deduced amino acid sequence indicated 62-86% identity with ovarian P450arom of other teleost fish, the highest identity being found with the Japanese flounder, Paralichthys olivaceous. Identity was lower (56-65%) with the P450arom forms first reported in teleost brain. Only 52% identity was observed with the corresponding fragment of the cartilaginous fish, Dasyatis sabina. RT-PCR revealed that the sea bass P450arom mRNA was also expressed, at low levels, in testis and brain. Between the 5' and 3'-untranslated terminal regions (UTR), the sea bass CYP19 gene contains eight introns. All introns conform to the GT/AG rule for RNA splicing and are inserted in exactly the same positions as those found in Oryzias latipes and the human CYP19 gene.

Differential tissue distribution, developmental programming, estrogen regulation and promoter characteristics of cyp19 genes in teleost fish

Teleost fish are characterized by exceptionally high levels of brain estrogen biosynthesis when compared to the brains of other vertebrates or to the ovaries of the same fish. Goldfish (Carassius auratus) and zebrafish (Danio rerio) have utility as complementary models for understanding the molecular basis and functional significance of exaggerated neural estrogen biosynthesis. Multiple cytochrome P450 aromatase (P450arom) cDNAs that derive from separate gene loci (cyp19a and cyp19b) are differentially expressed in brain (P450aromB>>A) and ovary (P450aromA>>B) and have a different developmental program (B>>A) and response to estrogen upregulation (B only). As measured by increased P450aromB mRNA, a functional estrogen response system is first detected 24-48 h post-fertilization (hpf), consistent with the onset of estrogen receptor (ER) expression (alpha, beta, and gamma). The 5'-flanking region of the cyp19b gene has a TATA box, two estrogen response elements (EREs), an ERE half-site (ERE1/2), a nerve growth factor inducible-B protein (NGFI-B)/Nur77 responsive element (NBRE) binding site, and a sequence identical to the zebrafish GATA-2 gene neural specific enhancer. The cyp19a promoter region has TATA and CAAT boxes, a steroidogenic factor-1 (SF-1) binding site, and two aryl hydrocarbon receptor (AhR)/AhR nuclear translocator factor (ARNT) binding motifs. Both genes have multiple potential SRY/SOX binding sites (16 and 8 in cyp19b and cyp19a, respectively). Luciferase reporters have basal promoter activity in GH3 cells, but differences (a>>b) are opposite to fish pituitary (b>>a). When microinjected into fertilized zebrafish eggs, a cyp19b promoter-driven green fluorescent protein (GFP) reporter (but not cyp19a) is expressed in neurons of 30-48 hpf embryos, most prominently in retinal ganglion cells (RGCs) and their projections to optic tectum. Further studies are required to identify functionally relevant cis-elements and cellular factors, and to determine the regulatory role of estrogen in neurodevelopment.

A comparative approach to structure-function studies of mammalian aromatases

To date, structure--function studies of aromatase cytochrome P450 (P450arom) have been advanced by point mutation analyses utilizing almost exclusively the human enzyme, in conjunction with computer-generated models of the three-dimensional form of the enzyme based on prokaryotic cytochromes P450. Recent studies have identified duplicated isozymes of porcine P450arom, the gonadal and placental forms of which appear to differ substantially in substrate utilization and inhibitor sensitivity. We present a comparative approach to define regions of P450arom responsible for specific functional characteristics using complimentary DNAs encoding the porcine isozymes. Constructs encoding the native and chimeric porcine and human P450arom enzymes were transiently expressed and activity was assessed using the tritiated water assay. Sensitivity to inhibition by the imidazole etomidate was investigated, and P450arom expression was assessed by immunoblot analysis. All constructs yielded active P450arom, suggesting that exchanging entire structural elements does not preclude catalytic function. The activity of the gonadal isozyme was shown to be inhibited by etomidate at concentrations 185 and 300-fold lower than those required to induce a similar inhibition of the placental and human enzymes, respectively. In contrast, there was only a two-fold difference in the sensitivity of the gonadal and placental isozymes to inhibition by CGS16949A. Analysis of chimeric constructs indicated that the sensitivity to etomidate was associated with residues in the B, B' and C helices of the gonadal P450arom encompassing only one of six putative substrate recognition sites. Additionally, sensitivity to etomidate was not correlated with enzyme activity among the chimeric enzymes. Therefore, it appears that residues of the porcine gonadal P450arom that are responsible for etomidate binding may be distinct from those involved in substrate recognition and metabolism. These data support the notion that a comparative approach employing the use of chimeric enzymes provides a useful tool in directing point mutational analysis to determine residues important in inhibitor and perhaps substrate recognition of P450 enzymes such as P450arom. These studies are currently in progress.

Developmental expression of cytochrome P450 aromatase genes (CYP19a and CYP19b) in zebrafish fry (Danio rerio)

Cytochrome P450 aromatase (CYP19) is the terminal enzyme in the steroidogenic pathway that converts androgens (e.g., testosterone) into estrogens (e.g., estradiol). Regulation of this gene dictates the ratio of androgens to estrogens; therefore, appropriate expression of this enzyme is critical for reproduction as well as being pivotal in sex differentiation for most vertebrates. It is assumed that most vertebrates have a single CYP19 gene that is regulated by multiple tissue-specific promoter regions. However, the zebrafish (Danio rerio) has two genes (CYP19a and CYP19b), each encoding a significantly different protein and possessing its own regulatory mechanism. The primary purpose of this study was to determine the pattern of expression of each of the CYP19 genes in the developing zebrafish. A fluorescent-based method of real-time, quantitative RT-PCR provided the sensitivity and specificity to determine transcript abundance in single embryos/juveniles harvested at days 0 through 41 days post-fertilization (dpf), which encompasses the developmental events of sex determination and gonadal differentiation. CYP19 transcripts could be detected as early as 3 or 4 dpf, (CYP19a and CYP19b, respectively) and peak abundance was detected on day five. In general, the CYP19 genes differed significantly in the ontogeny of their expression. In most cases, the gonadal form of CYP19 (CYP19a) was more abundant than the brain form (CYP19b); however, unlike CYP19a, the pattern of CYP19b expression could be clearly segregated into two populations, suggesting an association with sex differentiation. Pharmacological steroids (ethinylestradiol and 17 alpha-methyltestosterone) enhanced the expression of the CYP19b gene at all three days examined (4, 6, and 10 dpf). These data suggest that the timely and appropriate expression of CYP19 is important in development and that the expression of CYP19b (the "extra-gonadal" form) may be associated with sexual differentiation if not sexual determination. J. Exp. Zool. 290:475-483, 2001.