A regulatory cascade hypothesis for mammalian sex determination: SRY represses a negative regulator of male development.

McElreavey, Ken; Vilain, Éric; Abbas, Nacer; Herskowitz, Ira; Fellous, Marc

doi:10.1073/pnas.90.8.3368

Cited by 338 publications

(183 citation statements)

References 39 publications

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“…One such measure could be the function of SRY as an "anti-ovary" gene to antagonize Wnt/β-catenin signaling allowing normal testis differentiation in the XY gonad. A similar but more general hypothesis was put forward by McElreavey et al (McElreavey et al, 1993), who suggested that SRY may repress a negative regulator, termed "Z" of male development. Our data identifies a repressive "anti-ovary" function of SRY: the inhibition of the female-specific Wnt/β-catenin signaling pathway, where the Wnt/β-catenin signaling pathway is the negative regulator "Z" (Figure 7).…”

Section: Is Wnt/β-catenin the Proposed "Z" Factor?mentioning

confidence: 76%

“…This observation also indicates that RSPO1 may have two complementary functions, a "pro-ovary" function in initiating female gonadal development and an "anti-testis" function in inhibiting the male gonadal development pathway (Chassot et al, 2008). Several years ago, the analysis of a number of XX male patients led McElreavey et al to propose that an unidentified female "Z" gene was involved in repressing male gonadal development and that SRY was actively involved in the repression of the "Z" gene in the XY gonad, allowing testis development to proceed (McElreavey et al, 1993). Therefore, it is possible that RSPO1 or downstream effectors of the RSPO1 signaling pathway could assume the function of the "Z" repressor gene (Bernard and Harley, 2007).…”

Section: Introductionmentioning

confidence: 96%

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Human SRY inhibits β-catenin-mediated transcription

Bernard

Sim

Knower

et al. 2008

The International Journal of Biochemistry & Cell Biology

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In most mammals, sex is determined by the presence or absence of the SRY gene. SRY encodes a DNA binding HMG-box transcription factor which, during embryogenesis, is the initial trigger of testis differentiation from the bipotential gonad, yet its precise mode of function remains unclear. In ovarian development, R-spondin1 and Wnt4 act through the Wnt/β-catenin signaling pathway to regulate TCF-dependent expression of unknown target genes and repress testis development. Conversely, SRY may be necessary to prevent the development of ovaries by inhibiting the action of ovarian-determining genes. We hypothesize that SRY prevents Wnt/β-catenin signaling, thereby inhibiting ovarian development. In HEK293T cells, SRY repressed β-catenin-mediated TCFdependent gene activation in the presence of a specific GSK3β inhibitor or an activated β-catenin mutant, suggesting that SRY inhibits Wnt signaling at the level of β-catenin. Three SRY mutant proteins with nuclear localization defects, encoded by XY male-to-female patients, failed to inhibit β-catenin; surprisingly four SRY sex reversed mutants with defective DNA binding activity showed near wild-type SRY inhibitory activity. Moreover the potent transactivator SRY-VP16 fusion protein also showed wild-type SRY inhibitory activity. Thus SRY inhibition of β-catenin involves neither DNA binding nor transactivation functions of SRY. β-catenin and SRY interact in-vitro and SRY expression triggered β-catenin localization into specific nuclear bodies in NT2/D1 and Hela cells. We conclude that SRY inhibits β-catenin-mediated Wnt signaling by a novel nuclear function of SRY that could be important in sex determination.

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Section: Is Wnt/β-catenin the Proposed "Z" Factor?mentioning

confidence: 76%

Section: Introductionmentioning

confidence: 96%

Human SRY inhibits β-catenin-mediated transcription

Bernard

Sim

Knower

et al. 2008

The International Journal of Biochemistry & Cell Biology

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“…Molecular genetics analyses have demonstrated that approximately 90 % of these patients carry a variable amount of Y material due to a Y-to-X interchange caused by an illegitimate recombination during paternal meiosis [13][14][15]. There was a report of an XX male caused by a translocation of an SRY gene fragment from the Y chromosome to an autosome [16].…”

Section: Results Of Pcr and Fishmentioning

confidence: 99%

Clinical, cytogenetic, and molecular analysis with 46,XX male sex reversal syndrome: case reports

Gao

Chen

Huang

et al. 2013

J Assist Reprod Genet

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Purpose To investigate the clinical characteristics of different categories of sex-reversed 46,XX individuals and their relationships with chromosomal karyotype and the SRY gene. Methods Chromosome karyotyping for peripheral blood culture and multi-PCR and FISH were performed. Results Endocrinological data showed that their endocrine hormone levels were similar to that observed for Klinefelter syndrome, with higher FSH and LH levels and lower T levels. Chromosome karyotyping for peripheral blood culture revealed 46, XX complement for 11 males. Molecular studies showed that there were locus deletions at SY84, SY86, SY127, SY134, SY254 and SY255 in AZF on chromosome Y in 9 cases, with the SRY gene present at the terminus of the X chromosome short arm. In one case, besides 6 locus deletions in AZF, there was also SRY gene deletion. In another case, there were locus deletions only at SY254 and SY255, with SY84, SY86, SY127 SY134 loci and SRY present. Conclusions The majority (10/11) of 46,XX males were SRY positive, with the SRY gene translocated into the terminus of the X chromosome short arm. These patients were caused mainly by an X/Y chromosomal inter-change during paternal meiosis, leading to the differentiation of primary gonads into testes. Only a single patient (1/11) was SRY-negative, in which there might be some unknown downstream genes involved in sex determination.

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“…Absence of Z would lead to SOX9 expression, testis development, and XX sex reversal. [14] We will come back to this idea below (Fig. 1).…”

Section: Introductionmentioning

confidence: 99%

FOXL2 versus SOX9: A lifelong “battle of the sexes”

Veitia

2010

BioEssays

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Testis determination in most mammals is regulated by a genetic hierarchy initiated by the SRY gene. Early ovarian development has long been thought of as a default pathway switched on passively by the absence of SRY. Recent studies challenge this view and show that the ovary constantly represses male-specific genes, from embryonic stages to adulthood. Notably, the absence of the crucial ovarian transcription factor FOXL2 (alone or in combination with other factors) induces a derepression of male-specific genes during development, postnatally and, even more interestingly, during adulthood. Strikingly, in the adult, targeted ablation of Foxl2 leads to a molecular transdifferentiation of the supporting cells of the ovary, which acquire cytological and transcriptomic characteristics of the supporting cells of the testes. These studies bring many answers to the field of gonadal determination, differentiation and maintenance, but also open many questions. Keywords:.F OXL2; ovary determination; ovarian maintenance IntroductionGonadal sex determination is a process that implies a unique decision to make a testis or an ovary out of a bipotential primordium. In most mammals, sex determination is equated with testis determination, whereas ovarian determination has been considered a default process. That is, absence of the testisdetermining factor would automatically lead to the development of an ovary (in appropriate conditions). Recent articles challenge this view and show that in the ovary active mechanisms are required to maintain the differentiated state. [1,2] The bipotential gonad is made up of four presumptive cell lineages: germ cells (which have an extraembryonic origin) and three types of somatic cells. The somatic component involves the supporting cell precursors, which will give rise to Sertoli cells in the male or granulosa cells in the female, the steroidogenic precursors, which differentiate into Leydig cells (male) and theca cells (female), and finally the connective tissue cells yielding other important structures. [3] From a genetic perspective, the SRY gene is pivotal in switching on the testis-determining cascade.[4] Indeed, murine Sry transcripts appear in the presumptive Sertoli cells from 10.5 days postcoitum and for about 2 days, at the right moment for testis determination. [5] In other mammals, including man, SRY is expressed from the period of testis determination until adulthood [6]). It seems now that the main task of Sry/SRY is to directly activate the gene Sox9, which also encodes a transcription factor. Recently a gonad-specific enhancer that mediates testis Sox9 expression, called TESCO, has been identified. [7] Indeed, Sry along with the steroidogenic factor 1 (Sf1) binds to multiple elements within the TESCO. Moreover, mutation, co-transfection, and sex-reversal studies suggest the existence of a positive feedback circuit. First, Sf1 and Sry cooperatively up-regulate Sox9 transcription. Then, Sox9 and Sf1 recognize the enhancer to maintain the expression of the former in the absence of Sr...

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A regulatory cascade hypothesis for mammalian sex determination: SRY represses a negative regulator of male development.

Cited by 338 publications

References 39 publications

Human SRY inhibits β-catenin-mediated transcription

Human SRY inhibits β-catenin-mediated transcription

Clinical, cytogenetic, and molecular analysis with 46,XX male sex reversal syndrome: case reports

FOXL2 versus SOX9: A lifelong “battle of the sexes”

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