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Puzzling out the genetics of mammalian sex determination

Mammals possess an XX/XY chromosomal system for sex determination. The presence of SRY, a master-regulatory gene on the Y chromosome, is necessary to induce the undifferentiated, bipotential gonadal primordium (the embryonic genital ridge) to develop as a testis. In the absence of SRY, it develops a...

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Bibliographic Details
Published in:Trends in genetics 1996-05, Vol.12 (5), p.164-166
Main Authors: Jiménez, Rafael, Sánchez, Antonio, Burgos, Miguel, Díaz de la Guardia, Rafael
Format: Article
Language:English
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Summary:Mammals possess an XX/XY chromosomal system for sex determination. The presence of SRY, a master-regulatory gene on the Y chromosome, is necessary to induce the undifferentiated, bipotential gonadal primordium (the embryonic genital ridge) to develop as a testis. In the absence of SRY, it develops as an ovary. Once the gonads differentiate, their male- or female-specific endocrine function is responsible for the rest of the events involved in the phenotypic sexual differentiation process. Accordingly, in mammals, sex determination can be equated with testis determination. SRY is the only gene currently known to be involved in the process of sex determination. A number of cloned genes probably participate in gonadal development: the Muellerian inhibiting substance gene (MIS; also called the antimuellerian hormone gene, AMH), the SRY-related gene, SOX9, the mouse gene encoding steroidogenic factor (SF1), FtzF1, the X-linked gene, DAX1, and the Wilm's tumor suppressor gene, WT1. Whereas MIS and SOX9 are probably involved in the male pathway, the moment and site of action of the rest of these genes in the sex-differentiation process is unclear. FtzF1 and WT1 might be involved in the formation of the bipotential gonad, thus acting before SRY. The female pathway remains almost completely unknown. An X-linked, dosage-sensitive gene (DSS), which might be identical to DAX1, causes male-to-female sex reversal when duplicated, and has been proposed to be a member of the female pathway, but the findings on this point are inconclusive. Therefore, mammalian sex-determination is, in fact, an unsolved genetic puzzle from which a number of pieces are probably still missing.
ISSN:0168-9525
DOI:10.1016/0168-9525(96)30022-X