A role for Msx genes in mammalian embryonic diapause

Mammalian embryonic diapause is a reproductive phenomenon defined by the reversible arrest in blastocyst development and metabolic activity within the uterus which synchronously becomes quiescent to implantation. This natural strategy, evident in over 130 species across eight orders, can temporally uncouple conception from delivery until conditions are favorable for the survival of the mother and newborn. While the maternal endocrine milieu has been shown to be important for this process, the local molecular mechanisms by which the uterus and embryo achieve quiescence, maintain blastocyst survival and then resumes blastocyst activation with subsequent implantation in response to endocrine cues remains unclear. Here we review the first evidence that the proximal molecular control of embryonic diapause is conserved in three unrelated mammalian species which employ different endocrine programs to initiate diapause. In particular, uterine expression of muscle segment homeobox (Msx) genes Msx1 or Msx2 persists during diapause, followed by downregulation with blastocyst reactivation and implantation. Mice (Mus musculus) with conditional inactivation of Msx1 and Msx2 in the uterus fail to achieve diapause and reactivation. Remarkably, the mink (Neovison vison) and tammar wallaby (Macropus eugenii) share this pattern of MSX1 or MSX2 expression as in mice during delay - it persists during diapause and is rapidly downregulated upon implantation. Therefore, these findings were the first to provide evidence that there are common conserved molecular regulators in the uterus of unrelated mammals during embryonic diapause.

A dual role for SHH during phallus development in a marsupial

The mammalian phallus arises from identical primordia in both sexes and is patterned in part by the key morphogen Sonic hedgehog (SHH). We have investigated SHH and other morphogens during phallus development in the tammar wallaby. In this marsupial, testis differentiation and androgen production occurs just after birth, but it takes a further 50-60 days before the phallus becomes sexually dimorphic. One day before birth, SHH was expressed in both sexes in the urethral epithelium. In males, there was a marked upregulation of SHH, GLI2, and AR at day 50 postpartum, a time when testicular androgen production falls. SHH, GLI2, and AR were downregulated in female pouch young treated with androstanediol from days 24-50, but not when treatments were begun at day 29, suggesting an early window of androgen sensitivity. SHH, GLI2, and AR expression in the phallus of males castrated at day 23 did not differ from controls, but there was an increase in SHH and GLI2 and a decrease in FGF8 and BMP4 expression when the animals were castrated at day 29. These results suggest that the early patterning by SHH is androgen-independent followed by an androgen-dependent window of sensitivity and a sharp rise in SHH expression after androgen withdrawal at day 50.

Functional Analysis of the Cooled Rat Testis

Direct cooling of the testis results in the depletion of most germ cells in vivo. Germ cell-depleted testes are now commonly used to investigate spermatogenic regeneration and can serve as recipients for germ cell transplantation. The present study explored the effects of cooling rat testes on the depletion of endogenous germ cells, spermatogenic regeneration, and Sertoli cell function. Adult rat testes were cooled with iced Ringer's solution for 60 minutes, which results in the initiation of apoptotic germ cell loss within 8 hours. Pachytene spermatocytes at stages XII-I were the cells most sensitive to cooling. In 46%-67% of seminiferous tubule cross-sections, only Sertoli cells remained in the cooled testes 3-10 weeks after treatment. Germ cell loss was accompanied by a significant decrease in circulating inhibin B and an increase in follicle-stimulating hormone concentrations, which indicated a change in Sertoli cell function. Quantitative analysis of mRNA expression associated with apoptotic signals showed no significant uniform changes among the cooled testes, although some individuals had a distinct up-regulation of FAS mRNA at 24 hours. Attempts to use the cooled testes as recipient testes for mouse-to-rat germ cell transplantation were undertaken, but none of the mouse germ cells transplanted into the testes 15-34 days after cooling appeared to have undergone spermatogenesis 64-92 days after transplantation. These data suggest that modifications to Sertoli cell function resulting from testicular cooling create an environment that is unable to support spermatogenesis by donor germ cells.

Development of the penile urethra in the tammar wallaby

Hypospadias is increasingly common, and requires surgery to repair, but its aetiology is poorly understood. The marsupial tammar wallaby provides a unique opportunity to study hypospadias because penile differentiation occurs postnatally. Androgens are responsible for penile development in the tammar, but the majority of differentiation, in particular formation and closure of the urethral groove forming the penile urethra in males, occurs when there is no measurable sex difference in the concentrations of testosterone or dihydrotestosterone in either the gonads or the circulation [corrected]. Phalluses were examined morphologically from the sexually indifferent period (when androgens are high) to well after the time that the phallus becomes sexually dimorphic. We show that penile development and critical changes in the positioning of the urethra occur in the male phallus begin during an early window of time when androgens are high. Remodelling of the urethra in the male occurs between days 20-60. The critical period of time for the establishment urethral closure occurs during the earliest phases of penile development. This study suggests that there is an early window of time before day 60 when androgen imprinting must occur for normal penile development and closure of the urethral groove.

Fibroblast growth factor-9 in marsupial testicular development

FGF9 is a member of the fibroblast growth factor (FGF) family and is critical for early testicular development and germ cell survival in the mouse. Fgf9 reinforces the testis determinant Sox9 and antagonizes Wnt4, an ovarian factor. To determine whether FGF9 has a conserved role in the mammalian gonad, we examined its expression in the gonads of a marsupial, the tammar wallaby Macropus eugenii, and compared it to WNT4 expression. Marsupial FGF9 is highly conserved with orthologues from eutherian mammals, including humans. FGF9 protein was detected in both the testis and ovary before sexual differentiation, but it subsequently became sexually dimorphic during the period of testicular differentiation. The protein was specifically enriched in the seminiferous cords of the developing testis in the Sertoli and germ cells. FGF9 mRNA expression was upregulated in the tammar testis at the time of seminiferous cord formation and downregulated in the developing ovary in an opposite profile to that of marsupial WNT4. These observations suggest that FGF9 promotes male fate in the early gonad of marsupials through an antagonistic relationship with WNT4 as it does in eutherian mammals.

170. THE ROLE OF MEGALIN IN PROSTATE DEVELOPMENT OF THE MOUSE

Prostatic development is dependent on androgens; but the precise mechanism by which androgens mediate their effect is still unclear. Megalin, a cell membrane transporter, may shuttle sex steroids into cells to regulate androgen-responsive genes responsible for prostatic bud induction in the urogenital sinus (UGS). In megalin knockout mice, testicular descent fails and the vagina fails to open in females, both of which are dependent on sex steroid signalling (Hammes et al. 2005) . In this megalin-mediated pathway, SHBG-bound sex steroids bind to megalin, which is internalised. The SHBG-sex steroid complex is released, and the sex steroid is released from SHBG where it can bind to the androgen receptor to regulate androgen responsive genes. Receptor-Associated Protein (RAP) is a molecular chaperone protein that protects newly synthesised megalin from binding to potential ligands in the cytoplasm prior to insertion into the cell membrane. We hypothesised that megalin may shuttle SHBG-bound androgens across the cell membrane. This study characterised the expression and evaluated a possible role for megalin in the development of the mouse prostate. Megalin, SHBG and RAP transcripts were detected in the developing male and female UGS of the mouse from day E14.5 to day E18.5 (when prostatic buds start to form) and in the adult prostate. Megalin, SHBG and RAP protein were localised in the urogenital epithelium. To assess the role of megalin in prostatic development, UGS tissues were incubated with androgens in the presence and absence of RAP. Incubating UGS tissues with RAP did NOT inhibit prostatic bud initiation. Furthermore, in the UGS of megalin knockout mice, prostatic bud formation appeared to be identical to those of wild-type littermates. These results demonstrate that megalin is not involved in prostatic bud initiation. However, the ubiquitous expression of megalin suggests that its role is redundant in the prostate. (1) Hammes A et al. (2005) Role of endocytosis in cellular uptake of sex steroids. Cell 122(5), 751–62.

162. FRIEND OR FOE? THE ROLES OF PAF AND p53 DURING EMBRYONIC DIAPAUSE

In the tammar wallaby, Macropus eugenii, the blastocyst normally remains in embryonic diapause for 11 months without cell division or apoptosis occurring. Progesterone regulates reactivation by inducing active secretion from the endometrium, but the molecular cross-talk between the endometrium and blastocyst is unknown. This process may involve the phospholipid paf. Paf is an embryotrophin that acts as a trophic/survival factor in the early embryo, partly by inactivating (via the PI3K/Akt pathway) the expression of p53, a cell cycle arrest factor (1,2). In vitro, paf production from the tammar endometrium increases after diapause (3). This study examined the expression of the paf receptor (pafr) and p53 in the tammar endometrium and embryo at entry into, during and reactivation from diapause. Both pafr and p53 mRNA were expressed in the endometrium at all stages. However there was no quantitative change in pafr expression. In the endometrium, pafr protein is present on the membrane of the glandular epithelium at all stages examined, but p53 was not expressed in the endometrial nuclei at any stage and hence does not appear to be active. Both pafr and p53 mRNA were also expressed in the embryo from the early cleavage stages, during diapause and in the reactivated blastocyst. Pafr protein was present in the embryo both before and after diapause, but levels were greatly reduced during diapause, indicating it may be necessary for active growth. Unexpectedly, the expression of p53 in the embryo does not appear to depend on the presence or absence of pafr. p53 was expressed in the nuclei of the cleavage stage embryonic cells before diapause, but not during or after diapause. These results suggest that paf and pafr may participate in the molecular control of embryonic diapause in the tammar independent of p53. (1) Jin XL et al. (2009) Biology of Reproduction 80: 286–294.(2) O’Neill C (2005) Human Reproduction Update 11(3): 215–228.(3) Kojima T et al. (1993) Reproduction Fertility Development 5: 15–25.

054. TROPHOBLAST, PLACENTA AND EARLY EMBRYO: HOW THE MARSUPIAL DEVELOPS

In marsupials, the blastocyst forms as a single cell layer of cells. The marsupial blastocyst has no inner cell mass, so the 80–100 cell tammar embryo remains in diapause as a unilaminar blastocyst. All marsupials have a unilaminar stage, but what is unusual is that in the tammar the total cessation of cell division and cell metabolism lasts for 11 months each year. Marsupials are placental mammals. The yolk sac forms the definitive placenta up to birth. Only very few marsupials, such as the bandicoot, have a chorio-allantoic placenta, which supplements the placental functions of the yolk sac. However, the understanding how the unilaminar layer of trophoblast cells of the diapausing blastocyst become specified into placental and embryonic tissues has been an ongoing puzzle. To identify genes that do become differentially expressed in tammar development, we targeted the stage of the earliest appearance of the embryonic disc, at which the remainder of the blastocyst is then defined as trophoblast, as well as early cleavage stages. Intriguingly, we found no evidence for early differential expression of the canonical pluripotency genes POU5F1, SOX2 and NANOG, or of CDX2. By contrast, we found overt differential expression of GATA3, the closely related gene GATA2, and FGF4. This expression profile suggests that in the tammar, mechanisms regulating trophoblast- and pluriblast-specific expression of POU5F1, SOX2, NANOG and CDX2 are temporally secondary to those regulating GATA2 & -3 and FGF4 expression. Together, our results may signify the evolution of alternative mechanisms of early lineage specification in marsupials, or alternatively reveal a general hierarchy of signalling mechanisms that are masked in the relatively rapid and ‘compressed’ development of mice. The results of our ongoing study have important implications for understanding not only marsupial stem cells but the early development of all therian mammals.

140. GENES CONTROLLING PHALLUS DEVELOPMENT

Abnormalities of the limb and genital urinary tract are amongst the most prevalent congenital birth defects. The phallus and limb are both appendages controlled by similar patterning mechanisms during the early stages of differentiation. However, the phallus later undergoes an androgen dependent masculinisation phase whilst the limb does not. Marsupials deliver altricial young that complete their development after birth so are ideal models to investigate appendage development. In the tammar, development of the phallus occurs after birth during a period when the testicular androgen is low while the young is in the pouch, stages that normally occur in utero in mice. Exposure to androgens during development, but before differentiation of the phallus can induce sex reversal of the female phallus and hypospadias.1 However, the genes controlling development of the phallus and how they interact with the changing androgen environment have not been well studied as yet in any mammal. We are investigating the expression of several key genes, namely SHH, FGF8, BMP4 and DLX5, using RT-PCR, immunohistochemistry and in situ hybridization throughout the differentiation of the phallus and after treatment with androgens. Endogenous application of the potent androgen androstanediol to the phallus resulted in the downregulation of SHH, FGF8, BMP4 and DLX5. These genes are crucial for the correct development of both limb and phallus. However, the limb does not have an androgen dependant phase and it is not sexually dimorphic at these stages. SHH protein was localised in the epithelium of the phallus and in the urethral groove. The expression of the genes patterning the limb and phallus in the tammar therefore appear to be broadly conserved with those of the mouse. However, this is the first identification of androgen-regulated gene expression in the developing mammalian phallus. (1) Shaw G, Renfree M, Short R, Experimental manipulation of sexual differentiation in wallaby pouch young treated with exogenous steroids. Development, 1988. 104(4): 689.

137. GENOMIC IMPRINTING IN THE MARSUPIAL MAMMARY GLAND

Genomic imprinting is an epigenetic mechanism that differentially regulates the expression of certain genes, resulting in expression from only one parental allele. In mammals, genomic imprinting occurs in the placenta of both eutherians and marsupials, and plays an important role in regulating nutrition and growth of the developing fetus. The mammary gland also provides a critical source of nutrition for the neonate in all mammals, but there are few imprinting studies of this organ. Marsupials deliver tiny, altricial young that complete development during an extended lactation. INS (insulin) is paternally expressed in the eutherian and marsupial yolk sac and curiously is the only gene that is solely imprinted in this organ (1, 2). Insulin regulates carbohydrate metabolism, protein synthesis and cell growth. Insulin, (plus cortisol and prolactin) is required for the onset of lactation and the synthesis of milk (3). We characterised INS expression and examined its imprint status in the mammary gland of the tammar wallaby. INS mRNA is expressed in the mammary gland of the tammar from birth and throughout of lactation with highest expression at the initiation of lactation (Phase 1-2a) and around Phase 3 of lactation. Direct sequencing of 7 individuals at various stages of lactation confirmed that INS is imprinted in the mammary gland. Surprisingly, INS may also be imprinted in several other organs in the adult and juvenile wallaby. Preliminary bisulfite sequencing suggests there is a differentially methylated region located upstream of INS which may help to regulate INS expression. This is the first study to identify INS imprinting outside the yolk sac. As INS is critical for lactation, this is also the first indication that genomic imprinting may regulate lactation, suggesting that imprinting in the mammary gland may be as critical for post-natal survival as placental imprinting is for pre-natal development. (1) Deltour LX, et al. (1995). Tissue- and developmental stage-specific imprinting of the mouse proinsulin gene, Ins2. Dev Biol 168(2): 686–688.(2) Ager EI, et al. (2007). Insulin is imprinted in the placenta of the marsupial, Macropus eugenii. Dev Biol 309: 317–328.(3) Bolander FF, et al. (1981). Insulin is essential for accumulation of casein mRNA in mouse mammary epithelial cells. Proc Natl Acad Sci USA 78(9): 5682–5684.

Early expression of the androgen receptor in the Sertoli cells of a marsupial coincides with downregulation of anti-Müllerian hormone at the time of urogenital virilization

Anti-Müllerian hormone (AMH), responsible for the regression of Müllerian ducts, is strongly expressed by eutherian fetal and postnatal Sertoli cells. Both AMH and testosterone levels are high during the period of fetal reproductive tract virilization which occurs largely in utero in eutherian mammals. Taking advantage of the fact that differentiation of the urogenital tract occurs after birth in marsupials, we studied the ontogeny and regulation of AMH in the tammar wallaby testis and related it to the expression of the androgen receptor in Sertoli cells. Testicular AMH expression was high between days 10-30 post partum, then fell to basal levels by day 60 and remained low until day 90, the oldest age examined. AMH expression was repressed by treatment of male pouch young with the potent androgen androstanediol. Thus, in the tammar, AMH expression decreases in response to androgen at the time of initial urogenital masculinization, in contrast to the situation in humans in which AMH is repressed by testosterone only at the time of puberty. The difference might be explained by the timing of androgen receptor expression which appears in tammar Sertoli cells at around day 40 of pouch life but only at a later developmental stage in eutherians.

164. THE IMPRINT STATUS AND EXPRESSION OF INS IN THE TAMMAR WALLABY, MACROPUS EUGENII

Genomic imprinting is an epigenetic mechanism that differentially regulates the expression of certain genes, resulting in expression from only one parental allele. It is presumed to have first evolved after the divergence of therian mammals from the monotremes. One imprinted gene, INS is maternally imprinted (paternally expressed) in the eutherian and marsupial yolk sac1,2. INS encodes the precursor to the hormone insulin, which regulates carbohydrate metabolism and has a role in cell growth and, by regulating amino acid and fatty acid transporters, protein synthesis. In rats, mice and several other mammals insulin, in addition to cortisol and prolactin, is an absolute requirement for the onset of lactation and the synthesis of milk3. As imprinting plays an important role in regulating nutrition and growth the role of imprinted genes in the placenta has been the focus for imprinting research. Since the mammary gland provides a critical source of nutrition for the neonate in all mammals it is possible that genomic imprinting may have developed and been maintained in this organ. Given that marsupials deliver tiny, altricial young, it is in the relatively long and complex lactation phase where the mother has most control of the young's growth. Therefore, there may be greater selection for genomic imprinting in the marsupial mammary gland than in the eutherian mammary gland. This study examined the expression and the imprint status of INS in the mammary gland and neonatal tissues of the tammar wallaby, Macropus eugenii. INS expression was detected using PCR and direct sequencing provides evidence of INS imprinting in the mammary gland. This is the first study to identify imprinting in the mammary gland of a marsupial and the first to identify INS imprinting outside of the yolk sac.

174. THE EPIDERMAL GROWTH FACTOR (EGF) FAMILY IN THE ENDOMETRIUM AND BLASTOCYST OF THE TAMMAR WALLABY, MACROPUS EUGENII DURING EMBRYONIC DIAPAUSE

Embryonic diapause, a suspension of cell division and growth at the blastocyst stage, is widespread amongst mammals, but is especially common in the kangaroos and wallabies. In the tammar, Macropus eugenii, the sequence of endocrine events leading to embryonic diapause and reactivation are well defined[1]. The blastocyst can remain in diapause for up to 11 months without cell division, measurable metabolism or apoptosis occurring [2]. The ovarian hormones, especially progesterone, exert their effects on the blastocyst by alterations in the endometrial secretions [3], but the molecular cross-talk between the endometrium and blastocyst is unknown. There is increasing evidence for the involvement of leukaemia inhibitory factor (LIF)but the epidermal growth factor (EGF) family of growth factors are also likely to be involved.This study examined the expression of EGF and HB-EGF as well as their receptors, ERBB1 and ERBB4, in the tammar endometrium and blastocyst at entry into, and reactivation from, diapause. The genes for these factors were highly conserved in the tammar with orthologues in human and mouse. Quantitative RT-PCR of all four factors in the endometrium showed that expression changed with stage. Although expression levels of both receptors did not change between diapause and reactivation, both HB-EGF and EGF levels increased at reactivation from diapause and levels of HB-EGF decreased at entry into diapause. All factors were immunopositive in the endometrium. Studies underway will determine whether the cellular location and quantity of these factors change with entry into or exit from diapause, and define the molecular interactions occurring between the blastocyst and endometrium. These results are consistent with a role for the EGF family of growth factors in the control of embryonic diapause in tammars.

140. THE DEVELOPMENT OF THE PHALLUS IN A MARSUPIAL

The phallus, the limbs and the tail are all considered appendages in the developing mammal. In mice, several key genes including FGF8, BMP4, SHH, DLX5 and DLX6 are known to control the precise pattering of the limb and phallus in the fetus (reviewed in Yamada et al. 2006). The signalling cascade in both appendages begins with SHH interacting with FGF8. In humans, disruptions to these gene pathways result in malformations of both limbs and phallus because these appendages share conserved elements in patterning and development (Yamada et al. 2003). However, this is a poorly researched area so additional models are needed to provide a greater perspective into mammalian embryonic patterning especially of the external genitalia. In marsupials, since most sexual differentiation occurs after birth, the developing phallus and limbs are accessible at stages that occur in utero in humans and other eutherian mammals. We have used the tammar as an alternative model to understand the differentiation of the phallus and limb. FGF8, SHH and megalin mRNA and protein are all expressedin the limb and phallus from the early embryo until post-natal stages. SHH and megalin were co-localised in the urethral epithelium of the tammar phallus. This is the first study to detect megalin in the developing mammalian phallus. SHH is a critical gene in patterning the appendages, and megalin is a transport protein that ferries steroids into the cell where they can bind to their cognate receptor. It has a high affinity for the potent androgen androstanediol, an androgen critical for virilisation of the tammar phallus (Leihy et al. 2004). Further examination is underway to confirm whether the expression of the genes patterning the phallus in the mouse are conserved in the marsupial and whether megalin plays any role in the patterning of the phallus, possibly mediated by SHH.

181. HEPATOCYTE-NUCLEAR FACTOR 3-ALPHA (HNF-3α) EXPRESSION IN THE DEVELOPING PROSTATE OF THE TAMMAR WALLABY: A MARKER OF PROSTATE DIFFERENTIATION

The prostate is the source of about 30% of the seminal fluid. The prostate develops from the urogenital sinus involving epithelial-mesenchymal interactions, and is dependent on androgen secretion for its differentiation. Most studies on prostatic development have focused on the mouse but the tammar may be an alternative model for some aspects of prostatic development due to its structural similarity to the human. The tammar prostate is a cone-shaped secretory gland which consists of a central zone, transition zone and peripheral zone, as in humans. In contrast, the mouse prostate is a multi-lobular organ. Although much is known of the hormonal control of prostatic development in the tammar1,2,3, little is known about the specific markers of its differentiation. HNF-3α is a transcription factor that is expressed in the urogenital epithelium of the prostate in the mouse and human. This study characterised HNF-3α in the developing prostate of the tammar. The full length sequence of the gene was obtained in silico and confirmed by cloning. Tammar HNF-3α is highly conserved, sharing 82% nucleotide identity with the human and 80% nucleotide identity with mouse. We used RT-PCR to examine the temporal expression of HNF-3α, and found that it is expressed throughout prostate development in the male from immediately after birth to day 70, the latest stage examined. It is also expressed in the developing female urogenital sinus during a similar time period. HNF-3α protein has a spatial expression similar to that of the mouse, and it is localised to the nucleus of the urogenital epithelial cells. These results indicate that prostatic differentiation is conserved between the tammar (marsupial) and mouse (eutherian). Characterisation of HNF-3α in the tammar will also provide a useful tool in assessing prostatic differentiation in our ongoing prostatic organ culture experiments.

264. Primordial germ cell specification in a marsupial, the tammar wallaby

Primordial germ cells (PGCs) are the precursors of the gametes. In the mouse, PGCs are specified within the proximal epiblast in response to signals from the extraembryonic membranes during early gastrulation. Epiblast cells competent to form PGCs express Ifitm3. A subset of these cells then express Blimp1, a marker of PGC precursors. Once lineage-restricted, PGCs express Stella. Germ cells entering the gonads express VASA protein, which is a component of the germ plasm in animals in which germ cells are specified by the inheritance of maternal determinatives. Almost all of the research on mammalian PGC specification has used the mouse as a model and it is tacitly assumed that findings in the mouse will apply to mammals in general. We are using the tammar wallaby as a marsupial model for PGC specification. Eutherians and marsupials diverged 125–148 million years ago, so comparisons between the two will provide insights into the evolution of the control of mammalian PGC specification. There are IFITM clusters in both the human (chromosome 11) and mouse (chromosome 7). In the mouse, IFITM1, 2 and 3 are expressed in PGCs, whereas IFITM4 and 5 are not (1). Only one IFITM member, IFITM5, is annotated in the opossum Ensemble database. We have cloned one tammar IFITM member and identified at least one other putative member in the tammar trace archive database. We have also cloned tammar BLIMP1 and VASA, both of which show high sequence conservation with other mammals. RT–PCR profiles for both genes during tammar gastrulation are similar to those for the mouse. In contrast, no marsupial STELLA orthologueue has been identified in either the opossum or tammar genomes. These findings suggest that some but not all of the signals and mechanisms involved in eutherian PGC specification are also applicable to marsupials. (1) Lange UC, Saitou M, Western P, Barton SC and Surani MA (2003) BMC Dev. Biol. Epub 2003 Mar 19

230. Megalin, RAP and Nkx3.1 expression in the developing reproductive tract of a marsupial, the tammar wallaby

Androgens induce the differentiation of the urogenital sinus (UGS) to form a prostate. An early marker of this response is upregulation of the transcription factor Nkx3.1 in the urogenital epithelium in the precursors of prostatic buds. In tammars, prostate differentiation begins ~3 weeks after birth and after the time the testis starts to secrete androgens, and 2 weeks after androgen stimulated Wolffian duct differentiation. The reason for this delay in prostate differentiation is unexplained. Androgen receptors are present in the UGS, and the potent androgen, androstanediol, induces prostatic development in females. Whilst androgens may diffuse into cells by across the cell membrane, there is increasing evidence that steroids are also internalised actively via the cell-surface transport molecule Megalin. We are exploring the possibility that the delay may be related to the establishment of a Megalin-mediated pathway. Megalin is a cell surface receptor expressed on epithelia and mediates the endocytosis of a wide range of ligands, including SHBG-bound sex steroids. Megalin action is regulated by Receptor Associated Protein (RAP), which acts as an antagonist to Megalin action. This study cloned partial sequences of Megalin, RAP and Nkx3.1 and examined their expression in the developing urogenital sinus of the tammar wallaby using RT–PCR. The cellular distribution of Megalin protein in the developing UGS was examined using immunohistochemistry. Megalin, RAP and Nkx3.1 in the tammar were all highly conserved with eutherian orthologueues. Megalin and Nkx3.1 transcripts were detected in the liver, kidney, ovary, testis and developing urogenital sinus of male and female tammars. In the developing UGS of the tammar, there was strong staining for Megalin protein in the urogenital epithelium with some diffuse staining in the surrounding mesenchyme. Together, these results suggest that Megalin could be a key gene in the mediation of androgen action in prostatic development in the tammar wallaby.

259. Pluripotency genes in a marsupial, the tammar wallaby

Markers of pluripotency and early differentiation in the early embryo have been extensively characterised in eutherian species, most notably the mouse. By comparison, mechanisms controlling pluripotency and early lineage specification have received surprisingly little attention in marsupials, which represent the second major infraclass of mammals. Early marsupial embryogenesis exhibits overt morphological differences to that of eutherians, however the underlying developmental mechanisms may be conserved. In order to characterise early marsupial development at the molecular level, we have identified, cloned and analysed expression of orthologueues of several eutherian genes encoding transcription factors and signalling molecules involved in regulating pluripotency and early lineage specification. These genes include POU5F1 (OCT4), SOX2, NANOG, FGF4, FGFR2, CDX2, EOMES, TEAD4, GATA6 and KITL and are all expressed at early stages of development in the tammar. In addition, we have identified and cloned tammar POU2, which has orthologueues in non-mammalian vertebrates. POU2 is a paralogue of POU5F1 – a master regulator of pluripotency in eutherians. Genomic analysis indicates that POU5F1 arose via gene duplication of POU2 before the monotreme-therian divergence. Both genes have persisted in marsupials and monotremes, while POU2 was lost early during eutherian evolution. Similar expression profiles of tammar POU5F1 and POU2 in early embryos and gonadal tissues suggest possible overlapping roles in the maintenance of pluripotency.

440. A-kinase anchoring protein 4 in the marsupial

A-Kinase Anchor Protein 4 (AKAP4) is an X-linked member of the AKAP family of scaffold proteins that anchor cAMP-dependent protein kinases and play an essential role in fibrous sheath assembly during spermatogenesis and flagellar function in spermatozoa. Marsupial spermatozoa differ in structural organisation from those of eutherian mammals but data on the molecular control of their structure and function are limited. We therefore cloned and characterised the AKAP4 gene in a marsupial, the tammar wallaby (Macropus eugenii). The gene structure, sequence and predicted protein of AKAP4 were highly conserved with that of eutherian orthologueues and it mapped to the marsupial X-chromosome. There was no AKAP4 expression detected in the developing young and in the adult, expression was limited to the testis with a major transcript of 2.9kb identified by northern blotting. AKAP4 mRNA was detected by in situ hybridisation in the cytoplasm of round and elongated spermatids in the adult testis while its protein was found in the sperm tail from principal piece of the flagellum. This is consistent with its expression in other mammals. Thus this gene appears to have a conserved role in spermatogenesis for at least the last 166 million years of mammalian evolution.

245. Aristaless-related homeobox gene is involved in early development and spermatogenesis in mammals

The aristaless homeobox gene, ARX, belongs to a large family of homeodomain transcription factors with essential roles in forebrain, pancreas, muscle tissues and testes development in human and mouse. Mutation of ARX in humans results in mental retardation with or without ambiguous genitalia. We used comparative analyses to examine the evolutionary conservation of the mammalian ARX gene. We characterised ARX in a marsupial, the tammar wallaby, to determine if this gene is highly conserved in the homeodomain, aristaless domain, octapeptide motif and polyalanine tracts of all mammals. We further investigated the mRNA distribution in the developing head of tammar with in situ hybridisation, and found that it is expressed in forebrain and olfactory bulb as expected. Besides these regions, very strong expression was detected in the epithelium of the tongue and nasal pits. In the gonads, there is very strong staining in the interstitial cells and some of the germ cells in the developing ovary; strong staining was also seen in the cytoplasm of Sertoli cells and some of the germ cells, weak staining was also detected in the interstitium of the testis, possibly within the vessel endothelial cells and interstitial fibroblast-like cells. In addition, we investigated mRNA distribution in adult testes based on a very strong signal observed with northern blotting. Interestingly, mRNA expression was restricted to the round spermatids, and was not seen before or after this stage. In order to confirm this new role for ARX in the adult testis, we further investigated mRNA distribution of Arx in adult mouse testis, and found the same expression pattern, which implies a conserved function for ARX in spermatogenesis and may explain why humans with ARX mutations are infertile. This is the first report that ARX gene is involved in spermatogenesis in addition to its conserved roles in early mammalian development.

208. Absence of GH-R exon 3 in marsupials and monotremes argues for a eutherian specific origin and fetal specific purpose of this domain

Growth hormone receptor (GH-R) plays a critical role in the control of growth and metabolism in all vertebrates. GH-R consists of 9 coding exons (2–10) in all eutherian mammals, while the chicken only has 8 coding exons, and does not have an orthologous region to eutherian exon 3. To further understand the evolutionary origins of exon 3 of the GH-R we have cloned the full-length GH-R sequence in a marsupial, the tammar wallaby to determine whether exon 3 was present or absent in marsupial liver cDNA. There was no evidence for the presence of an exon 3 containing mRNA in sequence of tammar pouch young and adult livers. We next examined the genomes of the platypus (a monotreme mammal) and the grey short-tailed opossum (another marsupial). Like the tammar, the GH-R gene of neither species contained an exon 3. GH receptor can obviously function in the absence of this exon, raising speculation about the function of this domain, if any, in eutherians. A comparison of exon 3 protein sequences within 16 species of eutherian mammals showed that there was ~75% homology in the domain despite only 3 residues being identical (Leu12, Gln13 and Pro17). Interestingly, we detected greater evolutionary divergence in exon 3 sequences from species that have variants of GH or prolactin (PRL) in their placentas. These data show that exon 3 was inserted into the GH-R after the divergence of marsupial and eutherian lineages at least 130 million years ago.

239. Expression of PAF-R and p53 in the endometrium during entry into and reactivation from diapause in the tammar wallaby

Embryonic diapause is widespread amongst mammals, but is especially common in the kangaroos and wallabies. In the tammar, Macropus eugenii, the sequence of endocrine events leading to embryonic diapause and reactivation are well defined and the blastocyst can remain in diapause for up to 11 months without cell division or apoptosis occurring (Renfree and Shaw 2000). The ovarian hormones exert their effects on the blastocyst by alterations in the endometrial secretions, but the molecular cross-talk between the endometrium and blastocyst is unknown. One possible regulator of diapause is the phospholipid PAF, an embryotrophin that acts as a trophic/survival factor for the early embryo (O'Neill 2005) partly by inactivating the expression of p53, a cell cycle inhibitor, via the PI3-K pathway. PAF is released from the tammar endometrium around the time of reactivation from diapause (Kojima et al. 1993). This study examined the expression of PAF-R and p53 in the tammar endometrium at entry into, and reactivation from, diapause. PAF-R and p53 were highly conserved with orthologueues in human and mouse. PAF-R and p53 expression was assessed by RT–PCR and both genes were expressed in the endometrium at all stages examined. Quantitative PCR (QPCR) studies performed for PAF-R in the endometrium show that levels of PAF-R vary depending on the stage examined and appear to be increasing at entry into diapause and decreasing at exit from diapause. Immunohistochemical (IHC) studies are in progress to determine the cellular location of PAF-R in the endometrium and confirm the QPCR results. QPCR and IHC studies are in progress to determine if there is any change in levels of expression or cellular location of p53 between the stages examined and how this relates to PAF-R availability. These results suggest that the control of diapause in the tammar involves interactions between multiple factors. (1) Renfree MB, Shaw G (2000) Diapause. Annu Rev Physiol 62, 353–375 (2) O'Neill C (2005) The role of Paf in embryo physiology. Human Reproduction Update 11, 215–228 (3) Kojima T et. al. (1993) Production and secretion of progesterone in vitro and presence of PAF in early pregnancy of the marsupial, Macropus eugenii. Reproduction Fertility Development 5, 15–25.

Placental Function in Two Distantly Related Marsupials

The biochemical composition of uterine and fetal fluids during pregnancy of the grey short-tailed opossum was compared with new and published data on the tammar wallaby. In the grey short-tailed opossum, there are three main phases of embryonic nourishment. During the first phase, the embryo obtains nutrients from uterine secretion transferred into the yolk sac. The amount of uterine secretion declines during the second phase up to the time of shell coat rupture. As a result, the protein concentration in yolk sac fluid also declines. During phase three, which begins with shell coat rupture, nutrients are predominantly available from the maternal blood. In the grey short-tailed opossum that lacks a vesicular, fluid-filled allantois, waste products such as urea are apparently stored in the yolk sac and from there pass into the maternal circulation across the invasive yolk sac placenta. In contrast, in the tammar wallaby, the main source of nutrients available to the late term fetus is glandular secretion that is complemented by substances from the maternal circulation via the chorio-vitelline placenta, and waste products are stored in the large, fluid-filled allantois.

Changes in semen quality and morphology of the reproductive tract of the male tammar wallaby parallel seasonal breeding activity in the female

Changes in semen quality and morphology of the male reproductive tract were studied throughout the year in the highly promiscuous tammar wallaby. Body size, semen quality and gross morphology of the reproductive organs were assessed in adult males each month from January to November. The mean weight of males was similar in most periods sampled, but males were slightly heavier in the minor (P < 0.05) than the non-breeding season. Since body weight was correlated with weights of the testes, epididymides and accessory sex glands, organ weights were adjusted for body weight in subsequent analyses. In the major breeding season (late January/early February), when most females go through a brief, highly synchronized oestrus, the testes, prostate, Cowper's glands, crus penis and urethral bulb were heaviest, volume and coagulation of ejaculates were greatest, and sperm motility had increased. Semen samples collected by electroejaculation at this time contained low numbers of spermatozoa, possibly as a result of dilution and entrapment by the seminal coagulum or depletion of epididymal stores during intense multiple mating activity. In the non-breeding season (late May-July), when mating does not normally occur in the wild, there was a significant decrease in the relative weight of nearly all male reproductive organs and a decline in most semen parameters. In the minor breeding season (September-November), when pubertal females undergo their first oestrus and mating, the weights of testes, epididymides and most accessory sex glands had significantly increased similar to those of males in the major breeding season. The total number and motility of ejaculated spermatozoa were highest during this period, but the volume and coagulation of ejaculates and weight of the prostate had only increased to levels that were intermediate between the major and non-breeding seasons. Ejaculate volume was strongly correlated with prostate weight, and % motile spermatozoa was strongly correlated with epididymis weight. Semen quality thus varied seasonally with changes in androgen-dependent reproductive organs in the male tammar wallaby and appeared to be influenced by the seasonal timing of oestrus in females. Semen quality may also improve in response to an increase in the number of available oestrous females.

Long-term effects of deslorelin implants on reproduction in the female tammar wallaby (Macropus eugenii)

The contraceptive and endocrine effects of long-term treatment with implants containing the GnRH agonist deslorelin were investigated in female tammar wallabies (Macropus eugenii). Fertility was successfully inhibited for 515 ± 87 days after treatment with a 5 mg deslorelin implant (n= 7), while control animals gave birth to their first young 159 ± 47 days after placebo implant administration (n= 8). The duration of contraception was highly variable, ranging from 344 to 761 days. The strict reproductive seasonality in the tammar wallaby was maintained once the implant had expired. This inhibition of reproduction was associated with a significant reduction in basal LH concentrations and a cessation of oestrous cycles, as evidenced by low progesterone concentrations. There was evidence to suggest that some aspect of either blastocyst survival, luteal reactivation, pregnancy or birth may be affected by deslorelin treatment in some animals. These results show that long-term inhibition of fertility in the female tammar wallaby is possible using slow-release deslorelin implants. The effects of deslorelin treatment were fully reversible and there was no evidence of negative side effects. Slow-release GnRH agonist implants may represent a practicable method for reproductive management of captive and semi-wild populations of marsupials.

Effects of a Gonadotropin-Releasing Hormone Agonist Implant on Reproduction in a Male Marsupial, Macropus eugenii1

This study evaluated the potential of slow-release GnRH agonist (deslorelin) implants to inhibit reproductive function in the male tammar wallaby. The specific aim was to measure the effects of graded dosages of deslorelin on testes size and plasma LH and testosterone concentrations. Adult male tammar wallabies were assigned to four groups (n = 6 per group) and received the following treatment: control, placebo implant; low dose, 5 mg deslorelin; medium dose, 10 mg; high dose, 20 mg. All dosages of deslorelin induced acute increases (P < 0.001) in plasma LH and testosterone concentrations within 2 h, with concentrations remaining elevated during the first 24 h but returning to pretreatment levels by Day 7. Thereafter, there was no evidence of a treatment-induced decline in plasma testosterone concentrations. There was no detectable difference in basal LH concentrations between treated and control animals, nor was there a significant change in testes width or length (P > 0.05). These results suggest that the male tammar wallaby is resistant to the contraceptive effects of chronic GnRH agonist treatment. Despite the maintenance of testosterone secretion, the majority of male tammars (10 of 17) failed to respond to a GnRH challenge with a release of LH between Days 186 and 197 of treatment. The failure of animals to respond to exogenous GnRH suggests a direct effect of deslorelin on the pituitary, resulting in a level of desensitization that was sufficient to inhibit a LH surge but insufficient to inhibit basal LH secretion. The variation between animals is believed to result from earlier recovery of some individuals, in particular those that received a lower dose, or individual resistance to the desensitization process.

Expression of DMRT1 in the mammalian ovary and testis--from marsupials to mice

Doublesex and mab3 related transcript (DMRT1) was identified as a candidate gene for human 9p24.3 associated sex reversal. DMRT1 orthologues have highly conserved roles in sexual differentiation from flies and worms to humans. A DMRT1 orthologue was isolated from a marsupial, the tammar wallaby Macropus eugenii. The wallaby gene is highly conserved with other vertebrate DMRT1 genes, especially within the P/S and DM domains. It is expressed in the differentiating testis from the late fetus, during pouch life and in the adult. As in eutherian mammals, DMRT1 protein was localized in the germ cells and the Sertoli cells of the testis, but in addition it was detected in the Leydig cells, peri-tubular myoid cells and within the acrosome of the sperm heads. DMRT1 protein was also detected in the fetal and adult ovary pre-granulosa, granulosa and germ cells. Similarly, we also detected DMRT1 in the granulosa cells of all developing follicles in the adult mouse ovary. This is the first report of DMRT1 expression in the adult mammalian ovary, and suggests a wider role for this gene in mammals, in both the testis and ovarian function.

Long-term fertility control in the kangaroo and the wallaby using levonorgestrel implants

Non-lethal management techniques are needed for overabundant captive and wild populations of macropodid marsupials for which lethal techniques are considered inappropriate and may be hazardous. The tammar wallaby, Macropus eugenii, was used as a model species to investigate the effect of s.c. levonorgestrel implants on reproduction during breeding and non-breeding seasons. Implants were tested on captive and wild populations of eastern grey kangaroos, Macropus giganteus. In both species, levonorgestrel successfully stopped reproduction by inhibiting oestrus. However, levonorgestrel did not affect the reactivation and subsequent development of blastocysts in diapause that had been conceived before treatment and it did not impair lactation, as young were reared to weaning in both species. The contraceptive effects of the implant were reversible, as removal of the implants from tammar wallabies was followed by a rapid return of fertility. Levonorgestrel implants had no apparent adverse effects on body condition in either species, although in the wild kangaroos a small increase in body condition did occur. Levonorgestrel implants are long-acting and so far have provided 48 months of contraception in the tammar wallaby and 27 months of contraception in the kangaroo, although the implants should provide contraception for more than 5 years in the kangaroo. Thus, levonorgestrel implants provide a safe, highly effective and long-term method of fertility control for macropodid marsupials and should be applicable for the management of overabundant captive and selected wild populations.

Effect of an anti-androgen on testicular descent and inguinal closure in a marsupial, the tammar wallaby (Macropus eugenii)

Androgens are essential for testicular descent in eutherian mammals, but little is known about its hormonal control in marsupials. This study reports the effects of daily treatment with the anti-androgen flutamide (10 mg kg(-1)) from day 9 to day 75 after birth on the descent of the testis and inguinal closure in tammar wallabies. By day 75 after birth, the testes of control males had descended and the prostate gland was well developed. The testes of all flutamide-treated males had passed through the inguinal canal and were situated in the base of the scrotum. Three of the nine flutamide-treated males had unilateral inguinal hernias. The size of the inguinal canal, regardless of whether a hernia was present, was significantly wider than that of control males. Development of the prostate gland was significantly inhibited. By day 75 after birth, the phallus was significantly longer in control males than in females, whereas the phallus of flutamide-treated males was similar to that of control females. In flutamide-treated males, the lumbar 1 dorsal root ganglia was feminized and significantly fewer cell bodies expressed calcitonin gene- related peptide. As the anti-androgen treatment resulted in a reduction in the number of calcitonin gene-related peptide-positive cell bodies in the dorsal root ganglion supplying the genitofemoral nerve, the process of inguinal closure in tammar wallabies may be mediated by calcitonin gene-related peptide via the genitofemoral nerve, as indicated in humans. Flutamide treatment inhibited development of the prostate gland and phallus, which are both androgen-dependent structures, but it did not affect the normal descent of the testis, indicating that testicular descent can proceed when the action of androgens is blocked.

The influence of estrogen on the developing male marsupial

The genes and hormones involved in gonadal differentiation are highly conserved between eutherians and marsupials, although the timing of the developmental events differs. In marsupials, the testis develops seminiferous cords two days after birth, and the ovaries are not distinguishable until around eight days after birth. Differentiation of the internal genitalia is controlled in marsupials, as in eutherians, by testicular testosterone and Müllerian inhibiting substance, but differentiation of the scrotum in males and mammary primordia in females is hormone-independent. Since the young are easily accessible in the pouch, it is possible to administer gonadal hormones during the period of sexual differentiation. In both Australian and South American marsupials, estradiol treatment of neonatal males can induce male-to-female gonadal sex reversal. The testicular transformations range from partial suppression of seminiferous tubule development to the development of a morphologically normal ovary depending on the stage that treatment starts. The sex-reversed testes have a clearly defined cortex and medulla, and there are significantly fewer germ cells. The germ cells are surrounded by follicle-like cells and are in the early stages of meiosis, as is normal for XX germ cells in ovaries. In normal males, germ cells only enter meiosis at the onset of puberty. As in eutherians, estrogen treatment of neonatal male marsupials prevents regression of the Müllerian ducts, which are hypertrophic. Neonatal estradiol exposure also causes hypertrophy of the prostate and urogenital sinus. Estradiol treatment also inhibits transabdominal testicular descent and many animals develop inguinal hernias. The ability of estradiol to cause testis-to-ovary sex reversal in marsupials provides a new way of studying the interactions between genes and hormones in testicular differentiation.

Effects of oestrogen treatment on testicular descent, inguinal closure and prostatic development in a male marsupial, Macropus eugenii

This study reports the effect of oestrogen treatment on the development of the genital ducts, prostate gland, testicular descent and inguinal canal closure in male tammar wallaby young treated with oestrogen over four time spans during the first 25 days of pouch life (days 0-10, 10-15, 15-25 and 0-25) and sampled at day 50. In control males, the Müllerian ducts had regressed and the Wolffian ducts had developed into the vas deferens and epididymis. The prostate gland had formed epithelial buds extending from the ventral, lateral and posterior walls of the urethra. The testes were in the neck of the scrotum and the gubernaculum and processus vaginalis were present at the base of the scrotum. In most males treated with oestradiol from day 0 to day 25, the testes had failed to descend by day 50. The gubernaculae were long and thin. The retained Müllerian ducts formed a lateral vaginal expansion like that of normal day 50 females. The Wolffian ducts of the males treated on days 0-25 were regressed, but were present in males in the other three treatment groups. The prostate glands were hyperplastic and epithelial budding was highly invasive. Some treated males from the day 10-25 and 0-25 groups had inguinal hernias. These results demonstrate that oestrogen treatment has profound effects on the development of the internal genitalia of a male marsupial, preventing inguinal closure and interfering with testicular descent. Therefore, the tammar wallaby may provide a useful experimental model animal in which to investigate the hormonal control of testicular migration and closure of the inguinal canal.

Fetal control of parturition in marsupials

Among marsupials, the control of birth is best understood in the tammar wallaby. The young is tiny relative to the mother and is highly altricial. Adult female tammar wallabies weigh 5 kg, whereas the neonate weighs about 400 mg. However, despite this small size, there is clear evidence that the fetus provides the signal that sets the timing of birth through several mechanisms. A fetal signal activates a nitric oxide-guanylate cyclase system in the myometrium that may maintain myometrial inactivity, and this is down-regulated at term. There is also up-regulation of prostaglandin (PG) production in the gravid endometrium during the last two days of gestation that parallels increased placental PG synthesis, and a pregnancy-specific up-regulation of oxytocin receptors in the gravid myometrium that increases the responsiveness of the gravid uterus to mesotocin. These changes facilitate parturition, but an acute fetus-derived signal appears to trigger parturition. The fetal signal is probably related to glucocorticoid production. The fetal adrenal matures and is able to synthesize cortisol by Day 22 of the 26-day gestation. The fetal adrenals double in size between Day 24 and term, and their cortisol content increases over 10-fold. The pituitary of the neonate contains presumptive corticotrophs, and the adrenals increase cortisol production in response to adrenocorticotrophin. Prostaglandin E2, which is produced by the placenta, is also a potent stimulant of fetal adrenal cortisol synthesis. Treatment of tammars in late gestation with the cortisol agonist, dexamethasone, triggers birth around 23 h later. There is thus a strong case that fetal adrenal cortisol plays a key role in the preparation for birth and the timing of it. Further studies are in progress to more clearly define the mechanisms behind these actions of cortisol.

Sex down under: the differentiation of sexual dimorphisms during marsupial development

Marsupials have many characteristic features that make them ideal models to study the control of sexual differentiation and development. They are distinguished from eutherian mammals in their mode of reproduction and their greater dependence on the teat and mammary gland than on the placenta for development. They give birth to a highly altricial young which completes its development while firmly attached to a teat, usually within the confines of a pouch. At birth, the marsupial neonate has a well-developed digestive, respiratory and circulatory system, but retains its fetal excretory system with a fully functional mesonephric kidney and undifferentiated gonads and genitalia.

Germ cells, gonads and sex reversal in marsupials

The formation of the testis or ovary is a critical step in development. Alterations in gonadal development during fetal or postnatal life can lead to intersexuality or infertility. Several model systems have been particularly useful in studying gonadal differentiation, the eutherian mammal and amphibia, fish, and birds. However, marsupials provide a unique opportunity to investigate gonadal development and the interactions of genes and hormones in gonadal differentiation and germ cell development in all mammals. On the one hand the genetic mechanisms appear to be identical to those in eutherian mammals, including the testis-determining SRY gene. On the other hand, marsupials retain in part the plasticity of the amphibian gonad to hormonal manipulation. It is possible to induce female to male and also male to female gonadal sex reversal in marsupials by hormonal manipulation, and oestradiol can induce male germ cells to enter meiosis at the time the oogonia do. In addition, in marsupials the development of the scrotum and mammary glands are independent of testicular androgens and instead are controlled by a gene or genes on the X-chromosome. Thus marsupials provide a number of opportunities for manipulating the sexual differentiation of the gonads that are not possible in eutherian mammals and so provide a unique perspective for understanding the common mechanisms controlling sexual development.

Sex determining genes and sexual differentiation in a marsupial

The role of genes in the differentiation of the testis and ovary has been extensively studied in the human and the mouse. Despite over a decade of investigations, the precise roles of genes and their interactions in the pathway of sex determination are still unclear. We have chosen to take a comparative look at sex determination and differentiation to gain insights into the evolution and the conserved functions of these genes. To achieve this, we have examined a wide variety of eutherian sex determining genes in a marsupial, the tammar wallaby, to determine which genes have a conserved and fundamental mammalian sex determining role. These investigations have provided many unique insights. Here, we review the recent molecular and endocrine investigations into sexual development in marsupials, and highlight how these studies have shed light on the roles of genes and hormones in mammalian sex determination and differentiation.

Characterization of steroidogenic factor 1 during sexual differentiation in a marsupial

In eutherian mammals, such as mice and humans, steroidogenic factor 1 (SF1) plays important roles in the development of the gonad and in its steroidogenic activity. Marsupial and eutherian mammals have been evolving independently for at least 100 million years and so we were interested in comparing SF1 of a marsupial with that of eutherians. To this end, we have cloned SF1 from an Australian marsupial, the tammar wallaby. Although the amino acid sequence of SF1 is highly conserved among vertebrate species, tammar SF1 appears to have diverged less from the ancestral SF1 than have eutherian SF1 proteins. Tammar SF1 is expressed by both ovaries and testes on the day of birth, just prior to the onset of testicular differentiation, until at least 8 days after birth by which time the ovary also has begun to sexually differentiate. SF1 transcripts are localized predominantly to the pre-granulosa and Sertoli cells of the ovary and testis, respectively. In the testis SF1 transcripts are also present in the interstitial cells, although at a lower level than that which is observed in the Sertoli cells. SF1 is also transcribed in adult testis and ovary. In the adult ovary SF1 is expressed in the interstitial gland, and in the granulosa cells and theca interna of small to medium-sized antral follicles, but is not expressed in large antral follicles. Thus, although the structure of tammar SF1 is divergent from that of eutherians, its expression profile is similar, supporting a conserved role in gonadal development and steroidogenesis.

Estrogen-induced gonadal sex reversal in the tammar wallaby

Estrogens have a feminizing effect on gonadal differentiation in fish, amphibians, reptiles, and birds. However, the role of estrogen during gonadal differentiation in mammals is less clear. We investigated the effect of estrogen on gonadal differentiation of male tammar wallabies. Male pouch young were treated orally with estradiol benzoate or oil from the day of birth, before seminiferous cords develop, to Day 25 postpartum and were killed at Day 50 postpartum. In all estrogen-treated neonates, a decrease in gonadal volume, volume of the seminiferous cords, thickness of the tunica albuginea, and number of germ cells was found. The stage of treatment affected the magnitude of the response. Two of three male young born prematurely after 25 days of gestation and treated subsequently with estradiol had ovary-like gonads, with well-developed cortical and medullary regions and primordial follicle formation. Furthermore, at Day 50 postpartum, many (21%) of the germ cells in these sex-reversed ovaries were in the leptotene and zygotene stages of meiosis, similar to female germ cells at the same stage of development. In the other males born on Day 26 of gestation or later, estradiol treatment from the day of birth caused development of dysgenetic testes, with abnormal Sertoli cells, atrophy of the seminiferous tubules and tunica albuginea, and absence of meiotic germ cells. In this marsupial, therefore, estradiol can induce either partial or complete transformation of the male gonads into an ovary with meiotic germ cells. These results confirm that estrogen can inhibit early testicular development, and that testis determination occurs during a narrow window of time.

Virilization of the urogenital sinus of the tammar wallaby is not unique to 5alpha-androstane-3alpha,17beta-diol

The androgen 5alpha-androstane-3alpha,17beta-diol (5alpha-adiol) is synthesized in testes and secreted into plasma of male tammar wallaby pouch young and appears to virilize the urogenital sinus. To provide insight into its mechanism of action, a dose response study showed that administration of 1 microg 5alpha-adiol monoenanthate per g body wt. per week for 3 weeks to 24-day-old female pouch young induced prostate bud formation equivalent to that of males of the same age. Administration of this same dose of the enanthates of testosterone, dihydrotestosterone, and 5alpha-adiol to female pouch young caused equivalent virilization of the urogenital sinus. The fact that 5alpha-adiol does not exert a unique effect, together with our earlier findings in this species that 5alpha-adiol and testosterone are converted to dihydrotestosterone in the urogenital sinus and that virilization of the urogenital sinus is prevented by the androgen receptor antagonist flutamide, suggest that 5alpha-adiol is a circulating precursor for dihydrotestosterone formation in this tissue.

Differential regulation of contractility and nitric oxide sensitivity in gravid and nongravid myometrium during late pregnancy in a marsupial

Marsupials have two anatomically separate uteri; and in macropodids (kangaroos and wallabies), there is a single ovulation from alternate ovaries in each cycle. During late pregnancy, the two uteri are differentially regulated by local hormonal influences from the corpus luteum, the fetus, and placenta on one side and by the developing Graafian follicle on the other. In this study, we report striking differences in contractile behavior of nongravid and gravid myometrium from the tammar wallaby (Macropus eugenii) in late pregnancy and immediately post partum. Nongravid myometrium, from the uterus ipsilateral to a Graafian follicle, was spontaneously active but unresponsive to the oxytocic peptide mesotocin and the smooth muscle relaxant nitric oxide. Myometrium from the contralateral, gravid uterus, which contained a conceptus and was associated with an active corpus luteum, was not spontaneously active. Gravid myometrium became increasingly sensitive to mesotocin stimulation as pregnancy progressed, and nitric oxide induced marked relaxation at all stages examined, by a guanylyl-cyclase mediated pathway. These results provide further evidence that the two uteri of marsupials are under differential control, suggesting that local endocrine and paracrine influences, derived from the ovaries, the fetus, and placenta, can regulate concurrent but distinct physiological responses in the reproductive tracts of these mammals.

Contraceptive effects of levonorgestrel implants in a marsupial

The effect of subcutaneous levonorgestrel implants on reproduction in female tammar wallabies was investigated during the breeding and non-breeding season. Female tammars were given either a control or a levonorgestrel implant and their pouch young were removed to terminate embryonic diapause. Both the control and the levonorgestrel-implant animals treated during the months of May and June gave birth, demonstrating that levonorgestrel does not prevent the reactivation of the diapausing blastocyst or its subsequent development when given at these times. However, none of the levonorgestrel-treated animals mated post partum, whereas all of the control females that gave birth had a post partum oestrus and mated. Control animals gave birth again when the neonate was removed, and continued to breed normally during the following 36 months of the investigation. None of the levonorgestrel-treated animals gave birth again or mated during the next 36 months. Animals given control implants during December did not reactivate or give birth until the normal start of the breeding season in late January. Animals treated with levonorgestrel implants during December did not reactivate with the control animals at the beginning of the breeding season and did not give birth during the next 36 months. There were no effects of levonorgestrel treatment on early lactation. Levonorgestrel implants were removed from six females and four of these animals resumed reproductive activity, confirming that the contraceptive effect of the implants is reversible. Levonorgestrel implants therefore provide a highly effective, reversible and long-term method of contraception for tammar wallabies. This contraceptive system appears to offer a method of population control for the management of overabundant captive and selected wild populations of macropodid marsupials.

The human sex-reversing ATRX gene has a homologue on the marsupial Y chromosome, ATRY: implications for the evolution of mammalian sex determination

Mutations in the ATRX gene on the human X chromosome cause X-linked alpha-thalassemia and mental retardation. XY patients with deletions or mutations in this gene display varying degrees of sex reversal, implicating ATRX in the development of the human testis. To explore further the role of ATRX in mammalian sex differentiation, the homologous gene was cloned and characterized in a marsupial. Surprisingly, active homologues of ATRX were detected on the marsupial Y as well as the X chromosome. The Y-borne copy (ATRY) displays testis-specific expression. This, as well as the sex reversal of ATRX patients, suggests that ATRY is involved in testis development in marsupials and may represent an ancestral testis-determining mechanism that predated the evolution of SRY as the primary mammalian male sex-determining gene. There is no evidence for a Y-borne ATRX homologue in mouse or human, implying that this gene has been lost in eutherians and its role supplanted by the evolution of SRY from SOX3 as the dominant determiner of male differentiation.

Prostate formation in a marsupial is mediated by the testicular androgen 5 alpha-androstane-3 alpha,17 beta-diol

Development of the male urogenital tract in mammals is mediated by testicular androgens. It has been tacitly assumed that testosterone acts through its intracellular metabolite dihydrotestosterone (DHT) to mediate this process, but levels of these androgens are not sexually dimorphic in plasma at the time of prostate development. Here we show that the 3 alpha-reduced derivative of DHT, 5 alpha-androstane-3 alpha,17 beta-diol (5 alpha-adiol), is formed in testes of tammar wallaby pouch young and is higher in male than in female plasma in this species during early sexual differentiation. Administration of 5 alpha-adiol caused formation of prostatic buds in female wallaby pouch young, and in tissue minces of urogenital sinus and urogenital tubercle radioactive 5 alpha-adiol was converted to DHT, suggesting that circulating 5 alpha-adiol acts through DHT in target tissues. We conclude that circulating 5 alpha-adiol is a key hormone in male development.

Diapause

Embryonic diapause, or delayed implantation as it is sometimes known, is said to occur when the conceptus enters a state of suspended animation at the blastocyst stage of development. Blastocysts may either cease cell division so that their size and cell numbers remain constant, or undergo a period of very slow growth with minimal cell division and expansion. Diapause has independently evolved on many occasions. There are almost 100 mammals in seven different mammalian orders that undergo diapause. In some groups, such as rodents, kangaroos, and mustelids, it is widespread, whereas others such as the Artiodactyla have only a single representative (the roe deer). In each family the characteristics of diapause differ, and the specific controls vary widely from lactational to seasonal, from estrogen to progesterone, or from photoperiod to nutritional. Prolactin is a key hormone controlling the endocrine milieu of diapause in many species, but paradoxically it may act either to stimulate or inhibit growth and activity of the corpus luteum. Whatever the species-specific mechanisms, the ecological result of diapause is one of synchronization: It effectively lengthens the active gestation period, which allows mating to occur and young to be born at times of the year optimal for that species.

Absence of SOX3 in the developing marsupial gonad is not consistent with a conserved role in mammalian sex determination

Expression of Sox3 has been detected in the testes of humans and of developing and adult mice at the same time as Sox9 and Sry. The co-expression of these three related Sox genes in the mouse indifferent gonadal ridge led to the hypothesis that these three genes, encoding transcription factors with similar DNA target binding sites, may interact with each other in initiating testis differentiation. The location of SOX3 on the marsupial Dunnart X chromosome also makes it a candidate for the marsupial X-linked gene responsible for the SRY- and hormone-independent initiation of scrotum or mammary gland development. Here we show that although marsupial SOX3 is highly conserved at the genetic level and appears to have a conserved role in CNS development, its expression during sexual differentiation differs from that of mice and humans. SOX3 expression is absent from the developing marsupial genital ridge and from the scrotal and mammary primordia during the critical time of differentiation and throughout the time that SRY is expressed. The absence of expression in the developing gonad strongly suggests that SOX3 does not have a conserved role in mammalian sexual determination or differentiation.

Progesterone and oestrogen receptors in the female genital tract throughout pregnancy in tammar wallabies

The tammar, Macropus eugenii, is a monovular macropodid marsupial which has a post-partum oestrus and an 11 month embryonic diapause. Progesterone and oestradiol cytosol receptors were measured by Scatchard analyses and single point analysis in the lateral vagina, endometrium and myometrium of the gravid and contralateral non-gravid uterus throughout pregnancy, immediately after parturition and during seasonal reproductive quiescence. In endometrial tissues, both progesterone and oestradiol receptors doubled in concentration in both gravid and non-gravid uteri between day 0 and day 5 of pregnancy, coinciding with previously described peak values in peripheral plasma progesterone and oestrogen. Receptor concentrations in endometrial tissue during seasonal quiescence were not significantly different from those immediately after reactivation. After day 12 of pregnancy, downregulation of both progesterone and oestradiol cytosolic receptors occurred concomitant with the increase in progesterone in the peripheral plasma. However, there was a unilateral increase in oestradiol receptor concentrations in endometrium obtained from the non-gravid uterus between day 25 of the 26.5 day gestation and immediately after parturition. Myometrial receptor concentrations mirrored those of the endometrium but were lower. Concentrations of progesterone receptor in the lateral vaginae were at the lower limit of detection, while the oestradiol cytosol receptor concentrations were even lower in this tissue. Thus, the steroid receptor concentrations provide another example of local unilateral endocrine responses in the reproductive tract of the tammar. These results also indicate that the downregulation of progesterone and oestradiol receptors that occurs in both uteri in mid- and late-pregnancy is selectively and locally reversed before parturition in the non-gravid endometrium in response to the local effects of follicular oestradiol from the ipsilateral ovary.

Progesterone and oestrogen receptors in the female genital tract throughout pregnancy in tammar wallabies

The tammar, Macropus eugenii, is a monovular macropodid marsupial which has a post-partum oestrus and an 11 month embryonic diapause. Progesterone and oestradiol cytosol receptors were measured by Scatchard analyses and single point analysis in the lateral vagina, endometrium and myometrium of the gravid and contralateral non-gravid uterus throughout pregnancy, immediately after parturition and during seasonal reproductive quiescence. In endometrial tissues, both progesterone and oestradiol receptors doubled in concentration in both gravid and non-gravid uteri between day 0 and day 5 of pregnancy, coinciding with previously described peak values in peripheral plasma progesterone and oestrogen. Receptor concentrations in endometrial tissue during seasonal quiescence were not significantly different from those immediately after reactivation. After day 12 of pregnancy, downregulation of both progesterone and oestradiol cytosolic receptors occurred concomitant with the increase in progesterone in the peripheral plasma. However, there was a unilateral increase in oestradiol receptor concentrations in endometrium obtained from the non-gravid uterus between day 25 of the 26.5 day gestation and immediately after parturition. Myometrial receptor concentrations mirrored those of the endometrium but were lower. Concentrations of progesterone receptor in the lateral vaginae were at the lower limit of detection, while the oestradiol cytosol receptor concentrations were even lower in this tissue. Thus, the steroid receptor concentrations provide another example of local unilateral endocrine responses in the reproductive tract of the tammar. These results also indicate that the downregulation of progesterone and oestradiol receptors that occurs in both uteri in mid- and late-pregnancy is selectively and locally reversed before parturition in the non-gravid endometrium in response to the local effects of follicular oestradiol from the ipsilateral ovary.

Maternal recognition of pregnancy in marsupials

Pregnancy in kangaroos and wallabies (macropodid marsupials) induces multiple unilateral responses in the reproductive system that override those related to proximity to the single corpus luteum on one ovary or to the follicle on the contralateral ovary. This situation is in contrast to most other non-macropodid marsupials, in which the responses are dependent on the corpus luteum. There is now good evidence that these unilateral responses in macropodids are controlled by the feto-placental unit acting locally to stimulate the endometrium and myometrium. Pregnancy also influences the duration of the oestrous cycle and maternal behaviour. The stimuli responsible for these effects probably include paracrine, endocrine and mechanical stimuli resulting from uterine stretch. Taken together, these unilateral responses demonstrate that there is a refined maternal recognition of pregnancy in at least the macropodid marsupials.