Masatoshi Nakamoto

Two DM domain genes, DMY and DMRT1, involved in testicular differentiation and development in the medaka, Oryzias latipes

The recent discovery of the DMY gene (DM domain gene on Y chromosome and one of the DMRT1 family genes) as a key determinant of male development in the medaka (Oryzias latipes) has led to its designation as the prime candidate gene for sex‐determination in this species. This study focused on the sites and pattern of expression of DMY and DMRT1 genes during gonadal differentiation of medaka to further determine their roles in testis development. DMY mRNA and protein are expressed specifically in the somatic cells surrounding primordial germ cells (PGCs) in the early gonadal primordium, before morphological sex differences are seen. However, somatic cells surrounding PGCs never express DMY during the early migratory period. Expression of DMY persists in Sertoli cell lineage cells, from PGC‐supporting cells to Sertoli cells, indicating that only DMY‐positive cells enclose PGCs during mitotic arrest after hatching. DMRT1 is expressed in spermatogonium‐supporting cells after testicular differentiation (20–30 days after hatching), and its expression is much higher than that of DMY in mature testes. In XX sex‐reversed testes, DMRT1 is expressed in the Sertoli cell lineage, similar to the expression of DMY in XY testes. These results suggest strongly that DMY regulates PGC proliferation and differentiation sex‐specifically during early gonadal differentiation of XY individuals and that DMRT1 regulates spermatogonial differentiation. Developmental Dynamics 231:518–526, 2004.

Expression of gonadal soma derived factor (GSDF) is spatially and temporally correlated with early testicular differentiation in medaka

In the teleost fish, medaka (Oryzias latipes), the sex is genetically determined at the time of fertilization. The males are heterogametic with XY chromosome composition, while females are of XX chromosome composition. The male sexual differentiation is initiated in XY embryos of medaka by the sex-determining gene Dmy. In this study, we have cloned the gonadal soma derived factor (Gsdf) from medaka and characterized its expression pattern during the initiation of morphological testicular differentiation. By real-time PCR, an XY-specific up-regulation was detected in the expression levels of Gsdf in the whole embryos of medaka at 6days post fertilization (dpf), coincident with the initiation of testicular differentiation in the XY gonads. Whole mount and section in situ hybridizations reaffirmed that Gsdf was expressed exclusively in primordial gonads of only the genetic males at 6dpf. Conversely, the expression of Gsdf was found to be very weak in the XX gonads during embryogenesis. Importantly, Gsdf and Dmy were found to be co-localized in the same somatic cells in the XY gonads. When the XY embryos were treated with estradiol-17beta, in order to reverse their phenotypic sex, a decline was observed in the expression of Gsdf in these embryos by real-time PCR.

Gonadal sex differentiation and expression of Sox9a2, Dmrt1, and Foxl2 in Oryzias luzonensis.

Oryzias luzonensis is closely related to the medaka, O. latipes. The sex of both species is determined by an XX‐XY system. However, the testis determining gene (DMY/Dmrt1bY) found in O. latipes does not exist in O. luzonensis. Instead, a different gene is thought to act as a testis determining gene. In this study, we focused the gonadal sex differentiation process in O. luzonensis under different testis determining gene. First, we observed the gonadal development of O. luzonensis histologically. We then analyzed the expression of Sox9a2/Sox9b, Dmrt1, and Foxl2 during early development. Our results suggest that the sexual differentiation of germ cells in O. luzonensis is initiated later than in O. latipes. However, the timing of the sexual differentiation of the supporting cell linage is similar between the species. genesis 47:289–299, 2009.

Effects of Estradiol-17β on Germ Cell Proliferation and DMY Expression during Early Sexual Differentiation of the Medaka Oryzias latipes

Abstract Sex reversal of XY male to functional females was induced by estrogen treatment during the embryonic period in the medaka Oryzias latipes. The present study aimed to examine whether exogenous estrogen (estradiol-17β; E2) affects early sex differentiation, paying particular attention to DMY expression and proliferation activity of germ cells in estrogen treated XY individuals. Our results showed that germ cell number was not affected by E2 treatment at hatching, and that DMY expression was not suppressed under conditions of sex reversal. Therefore, male differentiation of germ cells, which is triggered by the expression of DMY in the supporting cell lineage, proceeds even in E2 treated XY individuals until hatching, and early sex differentiation is not altered by estrogen. However, sex reversal occurred after hatching probably because of estrogen remaining in the yolk. Interestingly, DMY expression was also detected in the large follicle layer of E2 treated XY ovary. These results suggested that DMY regulates male determination in early embryonic stage but does not suppress female follicle development.

Expression of 3β-hydroxysteroid dehydrogenase (hsd3b), star and ad4bp/sf-1 during gonadal development in medaka (Oryzias latipes).

In most vertebrates, sex steroids play a critical role in gonadal development, maturation of germ cells, and development of secondary sexual characteristics. Sex steroids are synthesized in steroid-producing cells (SPCs) in the testis known as Leydig cells, as well as in thecal and granulosa cells in the ovary. In SPCs, cholesterol is sequentially catalyzed by a set of steroidogenic factors and enzymes in order to produce sex steroids. Therefore, integrated expression of the genes involved in steroidogenesis is critical for the proper production of sex steroids. In the present study, regulatory mechanisms of steroidogenic factors and enzymes were examined. We focused on hsd3b, star and ad4bp/sf-1 as well as the description of temporal and spatial expression of these genes during gonadal development in medaka (Oryzias latipes). During testicular development, hsd3b, star and ad4bp/sf-1 were co-expressed in the interstitial somatic cells subsequent to the formation of the seminiferous tubule precursor, suggesting that ad4bp/sf-1 regulated the transcription of both hsd3b and star. During ovarian development, the expression pattern of hsd3b coincided with that of cyp11a1, but not with that of aromatase. Although ad4bp/sf-1 was mainly expressed in presumptive follicular cells, it was also detected in hsd3b positive interstitial cells in the developing ovary. Contrary to our expectations, the onset of star expression occurred during a later stage of ovarian development than the expression of other steroidogenic enzymes. Thus, the regulation mechanism of star transcription appears to differ from that of the other steroidogenic enzymes in the developing ovary, but not in the developing testis.

Cloning and expression of medaka cholesterol side chain cleavage cytochrome P450 during gonadal development.

Cholesterol side chain cleavage cytochrome P450 (P450scc, Cyp11a) is responsible for the first step in steroidogenesis, catalyzing the conversion of cholesterol to prognenolone. To investigate the differentiation of steroid‐producing cells and the function of sex steroids during gonadal differentiation in the teleost fish, medaka (Oryzias latipes), we isolated the full length cDNA of medaka P450scc and analyzed the expression pattern of P450scc mRNA during gonadal development using in situ hybridization. At hatching, and just after the initiation of morphological sex differentiation, we did not detect any P450scc expression in both sexes. In male gonads, expression of P450scc was detected in the interstitial somatic cells 15 days after hatching following the formation of the seminiferous tubule precursor, and was maintained in the interstitial somatic cells throughout testicular development. In the female gonad, expression of P450scc was initially detected in interstitial somatic cells 5 days after hatching. Subsequently, the expression of P450scc was continuously detected in the interstitial somatic cells of the developing ovary. This expression pattern of P450scc differed from that of female specific steroidogenic enzyme P450arom. Both P450scc and P450arom expressing cells, only P450scc expressing cells, and only P450arom expressing cells were observed. Our results suggest that expression of steroidogenic enzymes is regulated by various mechanisms during ovarian development.

Endocrine Regulation of Oogenesis in the Medaka, Oryzias latipes

Regulation of ovarian activity is an integrated process encompassing both extraovarian signals and intrafollicular factors. The medaka, Oryzias latipes, has served as an excellent experimental model for studying the regulation of various processes of oogenesis such as oocyte growth, maturation, and ovulation. The advantage of the medaka model is the precise daily ovarian cyclicity and the ease of isolating large numbers of oocytes for in vitro studies. In addition, because of the identification of maturation-inducing hormones (steroids) in fish oocytes, the endocrine regulation of oocyte maturation has been investigated most extensively in fishes, including medaka. Here we provide a brief overview of the gene regulation of hormonally controlled processes of oocyte growth, maturation, and ovulation mainly in medaka, and present some novel data on the steroidogenic shift occurring in ovarian follicles during oocyte growth and maturation.