Disruption of imprinted X inactivation by parent-of-origin effects at Tsix

In marsupials and in extraembryonic tissues of placental mammals, X inactivation is imprinted to occur on the paternal chromosome. Here, we find that imprinting is controlled by the antisense Xist gene, Tsix. Tsix is maternally expressed and mice carrying a Tsix deletion show normal paternal but impaired maternal transmission. Maternal inheritance occurs infrequently, with surviving progeny showing intrauterine growth retardation and reduced fertility. Transmission ratio distortion results from disrupted imprinting and postimplantation loss of mutant embryos. In contrast to effects in embryonic stem cells, deleting Tsix causes ectopic X inactivation in early male embryos and inactivation of both X chromosomes in female embryos, indicating that X chromosome counting cannot override Tsix imprinting. These results highlight differences between imprinted and random X inactivation but show that Tsix regulates both. We propose that an imprinting center lies within Tsix.     

Targeted mutagenesis of Tsix leads to nonrandom X inactivation.

During X inactivation, mammalian female cells make the selection of one active and one inactive X chromosome. X chromosome choice occurs randomly and results in Xist upregulation on the inactive X. We have hypothesized that the antisense gene, Tsix, controls Xist expression. Here, we create a targeted deletion of Tsix in female and male mouse cells. Despite a deficiency of Tsix RNA, X chromosome counting remains intact: female cells still inactivate one X, while male cells block X inactivation. However, heterozygous female cells show skewed Xist expression and primary nonrandom inactivation of the mutant X. The ability of the mutant X to block Xist accumulation is compromised. We conclude that Tsix regulates Xist in cis and determines X chromosome choice without affecting silencing. Therefore, counting, choice, and silencing are genetically separable. Contrasting effects in XX and XY cells argue that negative and positive factors are involved in choosing active and inactive Xs.     

Effect of TSIX disruption on XIST expression in male ES cells

XIST and its antisense partner, TSIX, encode non-coding RNAs and play key roles in X chromosome inactivation. Targeted disruption of TSIX causes ectopic expression of XIST in the extraembryonic tissues upon maternal transmission, which subsequently results in embryonic lethality due to inactivation of both X chromosomes in females and a single X chromosome in males. TSIX, therefore, plays a crucial role in maintaining the silenced state of XIST in CIS and regulates the imprinted X inactivation in the extraembryonic tissues. In this study, we examined the effect of TSIX disruption on XIST expression in the embryonic lineage using embryonic stem (ES) cells as a model system. Upon differentiation, XIST is ectopically activated in a subset of the nuclei of male ES cells harboring the TSIX-deficient X chromosome. Such ectopic expression, however, eventually ceased during prolonged culture. It is likely that surveillance by the X chromosome counting mechanism somehow shuts off the ectopic expression of XIST before inactivation of the X chromosome.     

X inactivation: Tsix and Xist as yin and yang

A new study shows that expression of Tsix, an antisense Xist gene, can be controlled by imprinting, and that high Tsix activity during X inactivation can protect the future active X chromosome from silencing by Xist. Tsix and Xist seem to have a yin and yang relationship, with opposite effects on X inactivation.