The Xist gene has been proposed as a candidate for the X inactivation centre, the master regulatory switch locus that controls X chromosome inactivation. So far this hypothesis has been supported solely by indirect evidence. Here we describe gene targeting of Xist, and provide evidence for its absolute requirement in the process of X chromosome inactivation.
X-chromosome inactivation in mammals is a regulatory phenomenon whereby one of the two X chromosomes in female cells is genetically inactivated, resulting in dosage compensation for X-linked genes between males and females. In both man and mouse, X-chromosome inactivation is thought to proceed from a single cis-acting switch region or inactivation centre (XIC/Xic). In the human, XIC has been mapped to band Xq13 (ref. 6) and in the mouse to band XD (ref. 7), and comparative mapping has shown that the XIC regions in the two species are syntenic. The recently described human XIST gene maps to the XIC region and seems to be expressed only from the inactive X chromosome. We report here that the mouse Xist gene maps to the Xic region of the mouse X chromosome and, using an interspecific Mus spretus/Mus musculus domesticus F1 hybrid mouse carrying the T(X;16)16H translocation, show that Xist is exclusively expressed from the inactive X chromosome. Conservation between man and mouse of chromosomal position and unique expression exclusively from the inactive X chromosome lends support to the hypothesis that XIST and its mouse homologue are involved in X-chromosome inactivation.
The Y chromosome gene Sry encodes a transcription factor required to initiate testis development. The related autosomal gene Sox9 is up-regulated shortly after the onset of Sry transcription and is thought essential for the differentiation of Sertoli cells. The lineage that gives rise to Sertoli cells has its origins within the coelomic epithelium (CE) of the genital ridge, but from cells also able to give rise to an interstitial cell type. It was not known at what point SRY acts in the derivation of this lineage or how the two genes interact. To investigate the identity of the cells expressing Sry, we designed two transgenes driven by the Sry promoter: one gives expression of a stable reporter, human placental alkaline phosphatase (hPLAP), while the second gives expression of a functional Myc-epitope tagged SRY protein (SRYMYC). Taking advantage of lasting hPLAP activity after transcription of the reporter gene has ceased, we could show that SryhPLAP was expressed exclusively in all cells fated to become Sertoli cells. SRYMYC-single-positive cells were first observed in the gonad and not in the CE. Subsequently, they became SRYMYC/SOX9-double-positive, but only for a few hours before turning into SOX9-single-positive cells. After the coelomic epithelial cells migrate into the gonad, there is first a decision to become interstitial or supporting cells, and then the transient expression of SRY in the latter determines their fate as Sertoli cells by up-regulating Sox9.
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