Sexual phenotype of avian chimeric gonads with germinal and stromal cells of opposite genetic sexes

The respective roles of germinal and stromal cells in determining the sexual phenotype of the gonad were analyzed in chimeric gonads obtained by surgical recombination between young avian blastodiscs in ovo. Equivalent territories were exchanged between two blastodisc, in order that the germinal crescent and the gonad territory had a different origin (fig. 3). Embryos used for these experiments carried a sex linked pigment mutation, that made it possible to diagnose the genetic sexes of germ cells and stroma at the time when the gonad was retrieved for examination. On the basis of species, three types of combination were performed: chick germ cells in chick or quail stroma, quail germ cells in chick stroma. In each chimera, the genetic sexes of the two gonadal cell populations could be identical or opposite. However it appeared that the germ cell population was not always homogeneous. In some grafting schemes, ectopic germ cells, located outside the germinal crescent, contributed to the colonization of the experimental gonad. These germ cells were from the same territory as the stroma element of the gonad, i.e., they were of the same species and the same genetic sex. Whatever the case, in 87 chimeras that were studied, the sex phenotype of the gonads always corresponded to the genetic sex of the stroma. Thus the genetic sex of germ cells has no role in the sexual differentiation of the gonadal rudiments.     

Proliferation of germ cells during gonadal sex differentiation in medaka: Insights from germ cell-depleted mutant zenzai

The proliferation of germ cells becomes sexually dimorphic during gonadal sex differentiation, although the underlying dynamics of this are not well understood in vertebrates. By tracing GFP-labeled germ cells in vivo and analyzing the germ cell-depleted mutant, zenzai, we show that the proliferation and differentiation of germ cells are regulated in a sexually dimorphic manner in the teleost fish medaka. In the undifferentiated gonads, germ cells resume proliferation by slow intermittent division (type I), producing isolated daughter cells. While germ cells in the male gonads continue this mode of proliferation, some germ cell fractions in the female gonads initiate two to four rounds of continuous division (type II), forming cysts of four, eight, or sixteen cells, which subsequently enter meiosis synchronously. Thus, female germ cells become differentiated much earlier than do male germ cells. In the zenzai mutant, a defect in slow intermittent division eventually leads to the depletion of germ cells in the adult gonads in both sexes, despite the fact that cyst-forming division is unaffected. This argues that slow intermittent division is essential for the maintenance of germ cells. The proliferation and differentiation of germ cells are thus important components of gonadal sex differentiation in vertebrates.     

Chick gonad differentiation following excision of primordial germ cells

The differentiation of embryonic chick gonads lacking germ cells was compared to that of normal chick gonads to determine whether the somatic elements of sterile avian gonads will undergo normal sexual differentiation. Primordial germ cells were removed by surgical excision of anterior germinal crescent from early embryos, Hamburger and Hamilton stages 6–11. Surgically treated and control embryos were sacrificed at 6, 15, and 20 days of incubation, and their gonads were studied histologically. Analysis of differentiation was based on morphological criteria at the cellular, tissue, and organ levels. In both male and female embryos, the somatic elements of the gonads differentiated normally in the absence of germ cells. The significance of these results for understanding the controls of differentiation of both the somatic gonad and the germ cells in birds is discussed and correlated with similar results in mammals.     

Male-specific cell migration into the developing gonad is a conserved process involving PDGF signalling

Male-specific migration of cells from the mesonephric kidney into the embryonic gonad is required for testis formation in the mouse. It is unknown, however, whether this process is specific to the mouse embryo or whether it is a fundamental characteristic of testis formation in other vertebrates. The signalling molecule/s underlying the process are also unclear. It has previously been speculated that male-specific cell migration might be limited to mammals. Here, we report that male-specific cell migration is conserved between mammals (mouse) and birds (quail-chicken) and that it involves proper PDGF signalling in both groups. Interspecific co-cultures of embryonic quail mesonephric kidneys together with embryonic chicken gonads showed that quail cells migrated specifically into male chicken gonads at the time of sexual differentiation. The migration process is therefore conserved in birds. Furthermore, this migration involves a conserved signalling pathway/s. When GFP-labelled embryonic mouse mesonephric kidneys were cultured together with embryonic chicken gonads, GFP+ mouse cells migrated specifically into male chicken gonads and not female gonads. The immigrating mouse cells contributed to the interstitial cell population of the developing chicken testis, with most cells expressing the endothelial cell marker, PECAM. The signalling molecule/s released from the embryonic male chicken gonad is therefore recognised by both embryonic quail and mouse mesonephric cells. A candidate signalling molecule mediating the male-specific cell migration is PDGF. We found that PDGF-A and PDGF receptor-alpha are both up-regulated male-specifically in embryonic chicken and mouse gonads. PDGF signalling involves the phosphotidylinositol 3-kinase (PIK3) pathway, an intracellular pathway proposed to be important for mesonephric cell migration in the mammalian gonad. We found that a component of this pathway, PI3KC2alpha, is expressed male-specifically in developing embryonic chicken gonads at the time of sexual differentiation. Treatment of organ cultures with the selective PDGF receptor signalling inhibitor, AG1296 (tyrphostin), blocked or impaired mesonephric cell migration in both the mammalian and avian systems. Taken together, these studies indicate that a key cellular event in gonadal sex differentiation is conserved among higher vertebrates, that it involves PDGF signalling, and that in mammals is an indirect effect of Sry expression.     

Freemartin in the amphibian Pleurodeles waltl: parabiosis between individuals from opposite sex triggers both germ and somatic cells alterations during female gonad development

Wild type embryos of the newt Pleurodeles waltl were used to realize parabiosis, a useful model to study the effect of endogenous circulating hormones on gonad development. The genotypic sex of each parabiont (ZZ male or ZW female) was determined early from the analysis of the sex chromosome borne marker peptidase-1. In ZZ/ZZ and ZW/ZW associations, gonads develop according to genetic sex. In ZZ/ZW associations, the ZZ gonads differentiate as normal testes while ZW gonads development shows numerous alterations. At the beginning of sex differentiation, these ZW gonads possess a reduced number of germ cells and a reduced expression of steroidogenic factor 1 and P450-aromatase mRNAs when compared to gonads from ZW/ZW associations. During gonad differentiation, conversely to the control situation, these germ cells do not enter meiosis as corroborated by chromatin status and absence of the meiosis entry marker DMC1; the activity of the estradiol-producing enzyme P450-aromatase is as low as in ZZ gonads. At adulthood, no germ cells are observed on histological sections, consistently with the absence of VASA expression. At this stage, the testis-specific marker DMRT1 is expressed only in ZZ gonads, suggesting that the somatic compartment of the ZW gonad is not masculinized. So, when exposed to ZZ hormones, ZW gonads reach the undifferentiated status but the ovary differentiation does not occur. This gonad is inhibited by a process affecting both somatic and germ cells. Additionally, the ZW gonad inhibition does not occur in the case of an exogenous estradiol treatment of larvae.     

Ultrastructural aspects of gonadal morphogenesis in Bufo bufo (Amphibia Anura) 1. Sex differentiation

The morphogenesis of gonads in Bufo bufo tadpoles was studied, and ultrastructural differences between sexes were identified. All specimens analyzed initially developed gonads made up of a peripheral fertile layer (cortex) surrounding a small primary cavity. Subsequently a central layer of somatic cells (medulla) developed. Both layers were separated by two uninterrupted basal laminae between which a vestige of the primary cavity persisted. During female differentiation, the peripheral layer continued to be the fertile layer. In males, the central layer blended into the peripheral layer and the basal laminae disappeared. The somatic cells of the central layer came into direct contact with the germ cells; this did not occur in females. Testicular differentiation continued with the migration of germ cells towards the center of the gonad. The somatic elements surrounding the germ cells appeared to play an active role in their transfer to the center of the gonad. The peripheral layer shrank and became sterile. Two basal laminae then re-formed to separate the fertile central layer from the peripheral sterile one. Germ cells have always been thought to perform a passive role in sex differentiation in amphibians. Following the generally accepted "symmetric model", the mechanism of gonad development is symmetrical, with cortical somatic cells determining ovarian differentiation and medullary somatic cells determining testicular differentiation. In contrast, we found that sex differentiation follows an "asymmetric" pattern in which germ cells tend primarily toward a female differentiation and male differentiation depends on a secondary interaction between germ cells and medullary somatic cells.     

Induction of meiosis in fetal mouse testis in vitro

Fetal mouse testes and ovaries with their urogenital connections were cultured singly or in pairs on Nuclepore filters. When a testis in which the sex was not yet morphologically detectable was cultured together with older ovaries containing germ cells which were progressing through the meiotic prophase, the male germ cells were triggered to enter meiosis. When older fetal testes in which the testicular cords have developed were cultured together with ovaries of the same age with germ cells in meiosis, the oocytes were prevented from reaching diplotene stage. It was concluded that the fetal male and female gonads secrete diffusable substances which influence germ cell differentiation. The male gonad secretes a "meiosis-preventing substance" (MPS) which can arrest the female germ cells within the meiotic prophase. The female gonad secretes a "meiosis-inducing substance" (MIS) which can trigger the nondifferentiated male germ cells to enter meiosis.     

RSPO1/β-catenin signaling pathway regulates oogonia differentiation and entry into meiosis in the mouse fetal ovary

Differentiation of germ cells into male gonocytes or female oocytes is a central event in sexual reproduction. Proliferation and differentiation of fetal germ cells depend on the sex of the embryo. In male mouse embryos, germ cell proliferation is regulated by the RNA helicase Mouse Vasa homolog gene and factors synthesized by the somatic Sertoli cells promote gonocyte differentiation. In the female, ovarian differentiation requires activation of the WNT/β-catenin signaling pathway in the somatic cells by the secreted protein RSPO1. Using mouse models, we now show that Rspo1 also activates the WNT/β-catenin signaling pathway in germ cells. In XX Rspo1(-/-) gonads, germ cell proliferation, expression of the early meiotic marker Stra8, and entry into meiosis are all impaired. In these gonads, impaired entry into meiosis and germ cell sex reversal occur prior to detectable Sertoli cell differentiation, suggesting that β-catenin signaling acts within the germ cells to promote oogonial differentiation and entry into meiosis. Our results demonstrate that RSPO1/β-catenin signaling is involved in meiosis in fetal germ cells and contributes to the cellular decision of germ cells to differentiate into oocyte or sperm.     

Sexual differentiation of germ cell deficient gonads in the medaka, Oryzias latipes

To determine whether germ cells perform any function in gonadal sexual differentiation, development of gonads in the medaka, Oryzias latipes, after exposure to busulfan was investigated. Busulfan suppressed proliferation of early germ cells, thus significantly reducing the number of germ cells and generating regions without germ cells in the developing gonads. Globular structures were observed in the parenchyma in these regions. The structure was male specific, developed at the same time as acinus (seminiferous tubule precursor), surrounded by the basal lamina, and contained characteristic desmosomes. These results strongly suggest that these globular structures are the precursors of seminiferous tubules devoid of germ cells. In the ovary, no follicles were observed but a well-developed ovarian cavity was evident. From these results we conclude that differentiation of gonadal parenchyma cells, except for follicular ones, is not germ cell dependent, though morphological differentiation of the somatic cells seems to follow the differentiation of germ cells.     

Cross talk between germ cells and gonadal somatic cells is critical for sex differentiation of the gonads in the teleost fish, medaka (Oryzias latipes)

To evaluate the possible role of germ cells on sex differentiation of the gonads in vertebrates, the teleost fish, medaka ( Oryzias latipes ), was used to generate a gonad without germ cells. The germ cell-deficient medaka reveals multiple effects of germ cells on the process of sex differentiation. The previously isolated mutant medaka, hotei , with the excessive number of germ cells may support the contention that the proliferation of germ cells is related to feminization of the gonad. Futhermore, we show that two modes of proliferation for either maintenance of germ cells or commitment to gametogenesis are important components of the sex differentiation of medaka developing gonads. An intimate cross talk between germ cells and gonadal somatic cells during the sex differentiation will be discussed.     

CYP1A1 based on metabolism of xenobiotics by cytochrome P450 regulates chicken male germ cell differentiation

This study aimed to explore the regulatory mechanism of metabolism of xenobiotics by cytochrome P450 during the differentiation process of chicken embryonic stem cells (ESCs) into spermatogonial stem cells (SSCs) and consummate the induction differentiation system of chicken embryonic stem cells (cESCs) into SSCs in vitro. We performed RNA-Seq in highly purified male ESCs, male primordial germ cells (PGCs), and SSCs that are associated with the male germ cell differentiation. Thereinto, the metabolism of xenobiotics by cytochrome P450 was selected and analyzed with Venny among male ESC vs male PGC, male PGC vs SSC, and male ESC vs SSC groups and several candidates differentially expressed genes (DEGs) were excavated. Finally, quantitative real-time PCR (qRT-PCR) detected related DEGs under the condition of retinoic acid (RA) induction in vitro, and the expressions were compared with RNA-Seq. By knocking down CYP1A1, we detected the effect of CYP1A1-mediated metabolism of xenobiotics by cytochrome P450 on male germ cell differentiation by qRT-PCR and immunocytochemistry. Results showed that 17,742 DEGs were found during differentiation of ESCs into SSCs and enriched in 72 differently significant pathways. Thereinto, the metabolism of xenobiotics by cytochrome P450 was involved in the whole differentiation process of ESCs into SSCs and several candidate DEGs: CYP1A1, CYP3A4, CYP2D6, ALDH3B1, and ALDH1A3 were expressed with the same trend with RNA-Seq. Knockdown of CYP1A1 caused male germ cell differentiation under restrictions. Our findings showed that the metabolism of xenobiotics by cytochrome P450 was significantly different during the process of male germ cell differentiation and was persistently activated when we induced cESCs to differentiate into SSCs with RA in vitro, which illustrated that the metabolism of xenobiotics by cytochrome P450 played a crucial role in the differentiation process of ESCs into SSCs.     

Differentiation of female chicken primordial germ cells into spermatozoa in male gonads

In avian species, the developmental fate of different-sex germ cells in the gonads is unclear. The present study attempted to confirm whether genetically female germ cells can differentiate into spermatozoa in male gonads using male germline chimeric chickens produced by the transfer of primordial germ cells (PGC), and employing molecular biological methods. As a result of Southern hybridization, specific sequences of the W chromosome (the female specific sex chromosome in birds) were detected in the genomic DNA extracted from one out of four male germline chimeric chickens. When two-color in situ hybridization was conducted on the spermatozoa of this germline chimera, 0.33% (average) of the nuclei of each semen sample showed the fluorescent signal indicating the presence of the W chromosome. The present study shows that female PGC can differentiate into spermatozoa in male gonads in the chicken. However, the ratio of produced W chromosome-bearing (W-bearing) spermatozoa fell substantially below expectations. It is therefore concluded that most of the W-bearing PGC could not differentiate into spermatozoa because of restricted spermatogenesis.     

Sex reversal of genetic females (XX) induced by the transplantation of XY somatic cells in the medaka,Oryzias latipes

In order to investigate the function of gonadal somatic cells in the sex differentiation of germ cells, we produced chimera fish containing both male (XY) and female (XX) cells by means of cell transplantation between blastula embryos in the medaka, Oryzias latipes. Sexually mature chimera fish were obtained from all combinations of recipient and donor genotypes. Most chimeras developed according to the genetic sex of the recipients, whose cells are thought to be dominant in the gonads of chimeras. However, among XX/XY (recipient/donor) chimeras, we obtained three males that differentiated into the donor's sex. Genotyping of their progeny and of strain-specific DNA fragments in their testes showed that, although two of them produced progeny from only XX spermatogenic cells, their testes all contained XY cells. That is, in the two XX/XY chimeras, germ cells consisted of XX cells but testicular somatic cells contained both XX and XY cells, suggesting that the XY somatic cells induced sex reversal of the XX germ cells and the XX somatic cells. The histological examination of developing gonads of XX/XY chimera fry showed that XY donor cells affect the early sex differentiation of germ cells. These results suggest that XY somatic cells start to differentiate into male cells depending on their sex chromosome composition, and that, in the environment produced by XY somatic cells in the medaka, germ cells differentiate into male cells regardless of their sex chromosome composition.     

Overexpression of Aromatase Alone is Sufficient for Ovarian Development in Genetically Male Chicken Embryos

Estrogens play a key role in sexual differentiation of both the gonads and external traits in birds. The production of estrogen occurs via a well-characterised steroidogenic pathway, which is a multi-step process involving several enzymes, including cytochrome P450 aromatase. In chicken embryos, the aromatase gene (CYP19A1) is expressed female-specifically from the time of gonadal sex differentiation. To further explore the role of aromatase in sex determination, we ectopically delivered this enzyme using the retroviral vector RCASBP in ovo. Aromatase overexpression in male chicken embryos induced gonadal sex-reversal characterised by an enlargement of the left gonad and development of ovarian structures such as a thickened outer cortex and medulla with lacunae. In addition, the expression of key male gonad developmental genes (DMRT1, SOX9 and Anti-Müllerian hormone (AMH)) was suppressed, and the distribution of germ cells in sex-reversed males followed the female pattern. The detection of SCP3 protein in late stage sex-reversed male embryonic gonads indicated that these genetically male germ cells had entered meiosis, a process that normally only occurs in female embryonic germ cells. This work shows for the first time that the addition of aromatase into a developing male embryo is sufficient to direct ovarian development, suggesting that male gonads have the complete capacity to develop as ovaries if provided with aromatase.     

Uncovering gene regulatory networks during mouse fetal germ cell development

The commitment of germ cells to either oogenesis or spermatogenesis occurs during fetal gonad development: germ cells enter meiosis or mitotic arrest, depending on whether they reside within an ovary or a testis, respectively. Despite the critical importance of this step for sexual reproduction, gene networks underlying germ cell development have remained only partially understood. Taking advantage of the W(v) mouse model, in which gonads lack germ cells, we conducted a microarray study to identify genes expressed in fetal germ cells. In addition to distinguishing genes expressed by germ cells from those expressed by somatic cells within the developing gonads, we were able to highlight specific groups of genes expressed only in female or male germ cells. Our results provide an important resource for deciphering the molecular pathways driving proper germ cell development and sex determination and will improve our understanding of the etiology of human germ cell tumors that arise from dysregulation of germ cell differentiation.     

FGF9 promotes survival of germ cells in the fetal testis

In addition to its role in somatic cell development in the testis, our data have revealed a role for Fgf9 in XY germ cell survival. In Fgf9-null mice, germ cells in the XY gonad decline in numbers after 11.5 days post coitum (dpc), while germ cell numbers in XX gonads are unaffected. We present evidence that germ cells resident in the XY gonad become dependent on FGF9 signaling between 10.5 dpc and 11.5 dpc, and that FGF9 directly promotes XY gonocyte survival after 11.5 dpc, independently from Sertoli cell differentiation. Furthermore, XY Fgf9-null gonads undergo true male-to-female sex reversal as they initiate but fail to maintain the male pathway and subsequently express markers of ovarian differentiation (Fst and Bmp2). By 14.5 dpc, these gonads contain germ cells that enter meiosis synchronously with ovarian gonocytes. FGF9 is necessary for 11.5 dpc XY gonocyte survival and is the earliest reported factor with a sex-specific role in regulating germ cell survival.     

A method to obtain avian germ-line chimaeras using isolated primordial germ cells.

Primordial germ cells (PGCs), collected from the blood of 2-day-old chick embryos, were concentrated by Ficoll density centrifugation. The blood contained 0.048% PGCs and the concentrated fraction contained 3.9% PGCs in blood cells. The PGCs were picked up with a fine glass pipette, and one hundred were then injected into the terminal sinuses of 2-day-old Japanese quail embryos (24 somites); bubbles were then inserted to prevent haemorrhage. The embryos were further incubated at 38 degrees C for 24 h, and then fixed. Serial sections were stained with the periodic acid-Schiff reagent (PAS) to demonstrate chicken PGCs and with Feulgen stain to identify quail cells. On the basis of the differences in staining properties, 63.6 +/- 5.3 chick PGCs were detected in the quail embryo in the area where the gonads develop. Furthermore, 39.3 +/- 4.5 chick PGCs were incorporated into the quail germinal epithelium within 24 h of the injection. A similar percentage of the host (quail) PGCs had also migrated to the germinal epithelium at the same stage of development. This technique for obtaining germ-line chimaeras will facilitate research on avian germ-line differentiation.     

Problems of sex determination in birds exemplified by <Emphasis Type="Italic">Gallus gallus domesticus</Emphasis>

The current views of sex determination in birds are considered mostly with the example of Gallus gallus domesticus, the species best studied in this respect. Data on the appearance of primordial germ cells, their migration to the primordial gonads, the role of hormonal factors in the regulation of sex differentiation, the sex chromosomes, putative genetic mechanisms of sex determination, and a possible contribution of dosage compensation are described. The review discusses the two best-grounded hypotheses on the roles of the Z and W chromosomes in sex determination.     

Sex determination and sexual differentiation in the avian model

The sex of birds is determined by the inheritance of sex chromosomes (ZZ male and ZW female). Genes carried on one or both of these sex chromosomes control sexual differentiation during embryonic life, producing testes in males (ZZ) and ovaries in females (ZW). This minireview summarizes our current understanding of avian sex determination and gonadal development. Most recently, it has been shown that sex is cell autonomous in birds. Evidence from gynandromorphic chickens (male on one side, female on the other) points to the likelihood that sex is determined directly in each cell of the body, independently of, or in addition to, hormonal signalling. Hence, sex-determining genes may operate not only in the gonads, to produce testes or ovaries, but also throughout cells of the body. In the chicken, as in other birds, the gonads develop into ovaries or testes during embryonic life, a process that must be triggered by sex-determining genes. This process involves the Z-linked DMRT1 gene. If DMRT1 gene activity is experimentally reduced, the gonads of male embryos (ZZ) are feminized, with ovarian-type structure, downregulation of male markers and activation of female markers. DMRT1 is currently the best candidate gene thought to regulate gonadal sex differentiation. However, if sex is cell autonomous, DMRT1 cannot be the master regulator, as its expression is confined to the urogenital system. Female development in the avian model appears to be shared with mammals; both the FOXL2 and RSPO1/WNT4 pathways are implicated in ovarian differentiation.