Impact of Some Ions Administration on Sex Ratio and Ovarian Structures in Rabbits.

<b>Background and Objective:</b> The sex pre-selection for offspring before conception is desirable demand especially for the breeding program of farm animals. This study aimed to evaluate the preconception treatment of monovalent and divalent ions on the primary sex ratio, ovarian structures and serum minerals levels in New Zealand white rabbit does. <b>Materials and Methods:</b> Nine New Zealand white rabbits doe<i> </i>(5.4±0.61 months of age and 2.4±0.35 kg of body weight) were used. Rabbits in the 1^st group were given drinking water only (control). While the 2^nd and 3^rd groups were given 1% of (calcium and magnesium) and (sodium and potassium) in daily drinking water, respectively for 15 days before mating. The embryos of each group were individually collected after three days of mating for primary sex detection using SRY (Sex Determining Region Y) Polymerase Chain Reaction (PCR) assay. Mineral analyses for all studied animals were weekly detected in serum before and after mating. <b>Results:</b> The primary sex ratio for embryos of rabbits does receive (Na+K) produced more males (69.7%) while (Ca+Mg) administrated rabbits does produce more females (72.2%). The mineral treatment leads to a significant increase in the number of corpus luteum, total embryos, follicles bleeding and a significant decline in the count of large follicles. Also, there was no significant change in serum Na and Ca levels in the treated groups compared to the control. <b>Conclusion:</b> The preconception administration of Ca+Mg could produce more females while Na+K could produce more males without adverse side effects on serum minerals concentration.

Abcc8 (Sulfonylurea Receptor-1) Impact on Brain Atrophy after Traumatic Brain Injury Varies by Sex.

Females have been understudied in pre-clinical and clinical traumatic brain injury (TBI), despite distinct biology and worse clinical outcomes versus males. Sulfonylurea receptor 1 (SUR1) inhibition has shown promising results in predominantly male TBI. A phase II trial is ongoing. We investigated whether SUR1 inhibition effects on contusional TBI differ by sex given that this may inform clinical trial design and/or interpretation. We studied the moderating effects of sex on post-injury brain tissue loss in 142 male and female ATP-binding cassette transporter subfamily C member 8 (Abcc8) wild-type, heterozygote, and knockout mice (12-15 weeks). Monkey fibroblast-like cells and mouse brain endothelium-derived cells were used for in vitro studies. Mice were injured with controlled cortical impact and euthanized 21 days post-injury to assess contusion, brain, and hemisphere volumes (vs. genotype- and sex-matched naïves). Abcc8 knockout mice had smaller contusion volumes (p = 0.012) and larger normalized contralateral (right) hemisphere volumes (nRHV; p = 0.03) after injury versus wild type. This was moderated by sex: Contusions were smaller (p = 0.020), nRHV was higher (p = 0.001), and there was less global atrophy (p = 0.003) in male, but not female, knockout versus wild-type mice after TBI. Less atrophy occurred in males for each copy of Abcc8 lost (p = 0.023-0.002, all outcomes). In vitro, sex-determining region Y (SRY) stimulated Abcc8 promoter activity and increased Abcc8 expression. Loss of Abcc8 strongly protected against post-traumatic cerebral atrophy in male, but not female, mice. This may partly be mediated by SRY on the Y-chromosome. Sex differences may have important implications for ongoing and future trials of SUR1 blockade.

Sex-determining region Y (SRY) attributes to gender differences in RANKL expression and incidence of osteoporosis.

Receptor activator of nuclear factor κB ligand (RANKL) plays a crucial role in bone metabolism. RANKL gene misregulation has been implicated in several bone and cancer diseases. Here, we aimed to identify novel transcription regulators of RANKL expression. We discovered that transcription factors, sex-determining region Y (SRY) and c-Myb, regulate RANKL expression. We demonstrated that c-Myb increases and male-specific SRY decreases RANKL expression through direct binding to its 5'-proximal promoter. These results are corroborated by the gene expression in human bone samples. In osteoporotic men, expression of RANKL is 17-fold higher, which correlates with the drastically reduced expression (200-fold) of Sry, suggesting that in osteoporotic men, the upregulation of RANKL is caused by a decrease of Sry. In healthy men, the expression of RANKL is 20% higher than that in healthy women. Our data suggest that gender differences in RANKL expression and bone quality could be due to the sex-specific transcription factor SRY.

Structural and functional conservation of fungal MatA and human SRY sex-determining proteins.

Sex determination in animals and fungi is regulated by specific sex-determining genes. The Aspergillus nidulans mating type gene matA and the human SRY (Sex-Determining Region Y) encode proteins containing a single HMG (high-mobility group) domain. Analysis of the amino-acid sequence of MatA and SRY transcription factors revealed significant structural similarity. The human SRY protein is able to functionally replace MatA and drives the sexual cycle in the fungus A. nidulans. Functional studies indicate that SRY drives early fruiting body development, and hybrid MatA protein carrying the SRY HMG box is fully capable of driving both early and late stages of sexual development, including gametogenesis. Our data suggest that SRY and MatA are both structurally and functionally related and conserved in regulating sexual processes. The fundamental mechanisms driving evolution of the genetic pathways underlying sex determination, sex chromosomes and sexual reproduction in eukaryotes appear similar.

Genetic of gonadal determination.

Fetal sexual differentiation results from complex subsequent intracellular signaling and hormonal events that interact together in a definite timing. This process contributes to the setting of gonad determination, internal and external genitalia resulting in a female or male phenotype. Here, we review our current knowledge of gonadal determination drawing on insights from knock-out and transgenic mouse models and analysis of patients with disorders of sex development (DSD).

Switching on sex: transcriptional regulation of the testis-determining gene Sry.

Mammalian sex determination hinges on the development of ovaries or testes, with testis fate being triggered by the expression of the transcription factor sex-determining region Y (Sry). Reduced or delayed Sry expression impairs testis development, highlighting the importance of its accurate spatiotemporal regulation and implying a potential role for SRY dysregulation in human intersex disorders. Several epigenetic modifiers, transcription factors and kinases are implicated in regulating Sry transcription, but it remains unclear whether or how this farrago of factors acts co-ordinately. Here we review our current understanding of Sry regulation and provide a model that assembles all known regulators into three modules, each converging on a single transcription factor that binds to the Sry promoter. We also discuss potential future avenues for discovering the cis-elements and trans-factors required for Sry regulation.

Two Y genes can replace the entire Y chromosome for assisted reproduction in the mouse.

The Y chromosome is thought to be important for male reproduction. We have previously shown that, with the use of assisted reproduction, live offspring can be obtained from mice lacking the entire Y chromosome long arm. Here, we demonstrate that live mouse progeny can also be generated by using germ cells from males with the Y chromosome contribution limited to only two genes, the testis determinant factor Sry and the spermatogonial proliferation factor Eif2s3y. Sry is believed to function primarily in sex determination during fetal life. Eif2s3y may be the only Y chromosome gene required to drive mouse spermatogenesis, allowing formation of haploid germ cells that are functional in assisted reproduction. Our findings are relevant, but not directly translatable, to human male infertility cases.

Evidence for avian cell autonomous sex identity (CASI) and implications for the sex-determination process?

For the majority of animals, males and females are obviously different in terms of appearance, behaviour and physiology, and until recently, these differences were considered to be the result of hormone actions. However, there is now considerable evidence that the development of some sexually dimorphic structures/behaviours is a function of properties inherent to male and female cells (hormone independent). The relative contribution of hormones and cellular identity to the development of the phenotype is not clear and is likely to vary from species to species. The study of gynandromorph birds and chimeric embryos has greatly assisted efforts to distinguish between the effects of hormones and inherent cellular factors on phenotype. It is now clear that in birds, male/female differences are not primarily the result of hormone action and that male and female somatic cells possess a cell autonomous sex identity (CASI). Here, we review evidence for CASI in birds and discuss the implications for the process of sex determination.

Functional analysis of the SRY-KRAB interaction in mouse sex determination.

BACKGROUND INFORMATION: SRY (sex-determining region Y), the master regulator of male development in mammals, has been studied extensively for more than 17 years, but how the SRY protein triggers the chain of events leading to testis development remains unclear. SRY probably requires a partner protein to elicit its molecular function. KRAB-O, a novel protein containing a KRAB (Krüppel-associated box) domain only, was suggested recently as a candidate SRY partner. In order to investigate the possible role of KRAB-O in sex determination, we studied its expression and conducted functional assays of the SRY-KRAB interaction. RESULTS: More than 100 KRAB genes were found to be expressed in mouse developing gonads, including 19 transcripts encoded by the KRAB-O cluster that were found to be expressed in somatic cells at 11.5 dpc (days post-coitum). Loss-of-function analysis in Sry-expressing cultured cells, using shRNA (small hairpin RNA) constructs directed against KRAB-O and its homologous genes, resulted in a reduced ability to up-regulate Sox9 [SRY-related HMG (high-mobility group)-box 9]; however, KRAB-knockdown mice exhibited normal testis development. CONCLUSIONS: Reduced Sox9 expression in KRAB-knockdown cells supports a role for KRAB-O and perhaps other KRAB genes in mediating SRY function. Overlapping expression and potential redundancy between members of the large KRAB-O gene cluster may mask any loss-of-function in vivo, presenting clear challenges for further functional analysis.

Boys, girls and shuttling of SRY and SOX9.

In the mammalian embryo, SRY and SOX9 are key Sertoli cell proteins that drive the development of the bipotential gonad into a testes rather than an ovary, leading ultimately to the male phenotype. Clinical SRY and SOX9 mutations causing disorders of sex development (DSD) highlight defective protein-protein interactions between SRY or SOX9, and carrier proteins required for nuclear import (importin-b and calmodulin) and nuclear export (CRM-1). The fine balance between import and export determines the levels of transcriptionally active SRY and SOX9 in the nucleus. Recently, post-translational modifications of SRY and SOX9 have been identified which affect nuclear transport. It is therefore timely that the consequences of sex-reversal mutation upon nuclear transport be reviewed. SRY and SOX9 mutations in DSD have uncovered regulatory sites for sumoylation, ubiquitination, acetylation and phosphorylation, many of which are essential for their transport and sex determining functions.

Full-length SRY protein is essential for DNA binding.

SRY directs testicular development. It has been suggested that the only high-mobility group (HMG) box of the SRY is important for the function of this protein; however, other studies have suggested that the N- and C-terminal regions are also involved in this process. Herein, we analysed and compared in vitro the DNA-binding activity of the full-length SRY and three mutants (HMG box alone, N-terminal less and C-terminal less SRY proteins). DNA-binding capability was analysed by mobility shift assays, optical density and dissociation constant by using pure non-fusion SRY proteins. The structure of the full-length SRY was carried out using a protein molecular model. The HMG box SRY alone and C-terminal less SRY proteins had a statistically diminished DNA binding in comparison with the full-length SRY. In contrast, the affinity for DNA of the N-terminal less SRY was relatively similar to the full-length SRY. Likewise, three-dimensional structure of the full-length SRY suggested that some residues of the C-terminal region of the SRY interact with DNA. We demonstrate the importance that full-length SRY has, particularly the C-terminal region of the protein, in DNA binding in vitro. Likewise, the affinity of the HMG box alone is clearly reduced when compared with the full-length SRY.

Nuclear import properties of the sex-determining factor SRY.

The sex-determining factor SRY plays an important role in male sexual development, diverting primordial gonads from the ovarian pathway toward male differentiation to form testes. SRY is a DNA-binding protein and gains access to the nucleus through two independently acting nuclear localization signals (NLSs) that flank the high mobility group (HMG) DNA-binding domain. We have reconstituted the nuclear import of SRY using an in vitro nuclear transport assay, showing that nuclear import of SRY can occur in the absence of additional exogenous cytosolic factors, with a significant reduction in nuclear transport in the presence of antibodies to the nuclear transport protein importin (Imp) beta1 but not Impalpha. We have also shown using in vitro binding assays that the C-terminal NLS of SRY binds directly to Impbeta1. Finally, we have shown that SRY can target green fluorescent protein to the nucleus in a mammalian transfected cell line; importantly, mutations known to result in sex reversal that map to either NLS impair nuclear accumulation implying that SRY nuclear import is critical to its function.

The transcription factor SOX17 is involved in the transcriptional control of the uteroglobin gene in rabbit endometrium.

The transcription of the uteroglobin gene (ug) is induced by progesterone in the rabbit endometrium, primarily through the binding of the progesterone receptor to the distal region of the ug promoter. However, other transcription factors participate in the progesterone action. The proximal ug promoter contains several putative consensus sequences for the binding of various progesterone-dependent endometrial nuclear factors (Perez Martinez et al. [1996] Arch Biochem Biophys 333: 12-18), suggesting that several transcription factors might be implicated in the hormonal induction of ug. We report here that one of these progesterone-dependent factors specifically binds to the sequence CACAATG (-183/-177) of the rabbit ug promoter. This sequence (hereafter called element G') is very similar to the consensus sequence for binding of the SOX family of transcription factors. Mutation of the element G' reduced transcription from the ug promoter in transient expression experiments. The endometrial factor was purified and analyzed by nano-liquid chromatography and ion trap coupled mass spectrometry yielding two partial amino acid sequences corresponding to a region of SOX17 that is highly conserved inter-species. This identification was confirmed by immunological techniques using a specific anti-SOX17 antibody. In agreement with the above findings, overexpression of SOX17 in transfected endometrial cells increased transcription from the ug promoter. SOX17 gradually accumulated in the nucleus in vivo concomitant with the induction of ug expression by progesterone in the endometrium. Thus, these findings implicate, for the first time, SOX17 in the transcriptional control of rabbit ug.

The poly(ADP-ribose) polymerase 1 interacts with Sry and modulates its biological functions.

Sry encodes a putative transcription factor that switches on testis differentiation during embryogenesis. Currently, the mechanism(s) by which Sry mediates such developmental process is still uncertain. To understand its gene regulation mechanism, we have utilized an in vitro affinity chromatography and proteomic strategy to identify and characterize Sry binding proteins from the mouse testis potentially involved in the formation of an Sry transcriptional complex(es). Our study has consistently identified the poly(ADP-ribose) polymerase 1 (PARP-1) as an Sry interactive protein. PARP-1 is expressed in mouse fetal gonads at the time of sex determination and co-localized with Sry in the nuclei of pre-Sertoli cells. PARP-1 could be co-immunoprecipitated with Sry in cultured cells. The interactive domains have been mapped to the HMG box of Sry and the zinc fingers of the PARP-1 protein, respectively. The Sry-PARP-1 interaction is evolutionarily conserved and it interferes with the ability of Sry in binding to its consensus sequence. In the presence of its substrate, PARP-1 poly(ADP-ribosyl)ates Sry and minimizes severely its DNA-binding activities. PARP-1 represses Sry-mediated transactivation of a reporter gene in cultured cells. Hence, PARP-1 could modulate the regulatory function(s) of Sry on its target genes in this developmental pathway.

The road to maleness: from testis to Wolffian duct.

The establishment of the male internal reproductive system involves two crucial events: the formation of the testis and the maintenance and differentiation of the Wolffian duct. Testis formation, particularly the specification of Sertoli cell and Leydig cell lineages, is controlled strictly by genetic components initiated by the testis-determining gene SRY (sex-determining region of the Y chromosome). Conversely, Wolffian duct differentiation is not directly mediated via the composition of the sex chromosome or SRY; instead, it relies on androgens derived from the Leydig cells. Leydig cells do not express SRY, indicating that a crosstalk must be present between the SRY-positive Sertoli and Leydig cells to ensure normal androgen production. Recent advancement of genetic and genomic approaches has unveiled the molecular pathways for differentiation of Sertoli cells and Leydig cells as well as development of the Wolffian duct.

Down-regulation of endogenous Wt1 expression by Sry transgene in the murine embryonic mesonephros-derived M15 cell line.

Wt1 is one of numerous candidate genes comprising the hypothetical chain of gene expression essential for male sex differentiation of the bipotential indifferent gonads during embryogenesis. However, the evidence in the literature is ambivalent regarding the position of Wt1 relative to Sry in this scheme; Wt1 might act either upstream or downstream of Sry. In the present study, the effects of Sry expression upon Wt1 were investigated using M15 cells (XX karyotype), which are derived from murine embryonic mesonephros and express endogenous Wt1. In 3 stably-transformed Sry-expressing M15 cell lines, we showed that the expression levels of the mRNAs coding for all 4 isoforms of the WT1 proteins were down-regulated. Similarly, Wnt 4 expression was down-regulated in these cell lines. Silencing of Sry in the transformed cell lines using ribozymes or short hairpin RNAs (shRNAs) resulted in elevated levels of Wt1 and Wnt4 expression. These results strongly indicate that Wt1 might be under the control of Sry during gonadal differentiation in the mouse. In electrophoretic mobility shift assays (EMSA), we demonstrated that the 3.7 kb 5'-upstream DNA stretch of Wt1 containing potential Sry binding sites was capable of forming molecular complexes with nuclear protein(s) from Sry expressing cells but not with those from control non-Sry expressing cells. In summary, our present results support the notion that Wt1 is located downstream of Sry and down-regulated by the sex determining gene. Although the precise biological meaning of the present findings have yet to be clarified, it is possible that Wt1 plays a dual role during gonadal differentiation, i. e., turning on Sry expression on one hand, and being down-regulated by its product, Sry, on the other, possibly forming a type of negative feed-back mechanism. Further work is needed to substantiate this view.

KRAB: a partner for SRY action on chromatin.

The sex determining region Y (SRY/Sry) gene is necessary and sufficient for testis determination and differentiation in mammals. SRY/Sry encodes a putative transcription factor with a high mobility group (HMG) DNA-binding domain. The spatiotemporal regulation of Sry expression suggests that a brief action of SRY in a limited number of progenitor cells (pre-Sertoli cells) before the onset of default ovarian differentiation is sufficient to switch on testicular differentiation. Recent identification and characterization of the Krüppel-associated box only (KRAB-O) protein as an SRY-interacting protein have provided experimental evidence supporting an interesting model for SRY function. In this model, SRY recruits the KRAB-KAP1 (KRAB-associating protein 1) complex as a chromatin modulator, which provides a molecular mechanism of SRY as a transcription factor. Moreover, the sufficiency of a brief action of SRY for testis differentiation can be partly explained by the heritability of KRAB-mediated chromatin remodeling. Although it is currently uncertain whether KRAB-O is the only KRAB protein with which SRY interacts, we hypothesize that KRAB-O or yet-to-be identified KRAB-containing proteins might play various roles in sex determination and gonadal differentiation.