Dosage compensation

About: Dosage compensation is a research topic. Over the lifetime, 1920 publications have been published within this topic receiving 124589 citations.

Genetic compensation in a human genomic disorder.

Abstract: Cytogenetic studies of the parents of a girl with the DiGeorge (or velocardiofacial) syndrome, who carried a deletion at 22q11.2, revealed an unexpected rearrangement of both 22q11.2 regions in the unaffected father. He carried a 22q11.2 deletion on one copy of chromosome 22 and a reciprocal 22q11.2 duplication on the other copy of chromosome 22. Genetic compensation, which is consistent with the normal phenotype of the father, was shown through quantitative-expression analyses of genes located within the genetic region associated with the DiGeorge syndrome. This finding has implications for genetic counseling and represents a case of genetic compensation in a human genomic disorder.

Sex determination and gonadal sex differentiation in the chicken model.

Abstract: Our understanding of avian sex determination and gonadal development is derived primarily from the studies in the chicken. Analysis of gynandromorphic chickens and experimental chimeras indicate that sexual phenotype is at least partly cell autonomous in the chicken, with sexually dimorphic gene expression occurring in different tissue and different stages. Gonadal sex differentiation is just one of the many manifestations of sexual phenotype. As in other birds, the chicken has a ZZ male: ZW female sex chromosome system, in which the male is the homogametic sex. Most evidence favours a Z chromosome dosage mechanism underling chicken sex determination, with little evidence of a role for the W chromosome. Indeed, the W appears to harbour a small number of genes that are un-related to sexual development, but have been retained because they are dosage sensitive factors. As global Z dosage compensation is absent in birds, Z-linked genes may direct sexual development in different tissues (males having on average 1.5 to 2 times the expression level of females). In the embryonic gonads, the Z-linked DMRT1 gene plays a key role in testis development. Beyond the gonads, other combinations of Z-linked genes may govern sexual development, together with a role for sex steroid hormones. Gonadal DMRT1 is thought to activate other players in testis development, namely SOX9 and AMH, and the recently identified HEMGN gene. DMRT1 also represses ovarian pathway genes, such as FOXL2 and CYP19A1. A lower level of DMRT1 expression in the female gonads is compatible with activation of the ovarian pathway. Some outstanding questions include how the key testis and ovary genes, DMRT1 and FOXL2, are regulated. In addition, confirmation of the central role of these genes awaits genome editing approaches.

Chromosomal domains and escape from X inactivation: comparative X inactivation analysis in mouse and human

Abstract: In females, most genes on the inactive X Chromosome (Chr) are transcriptionally silenced. However, several dozen genes have been identified in human that escape inactivation and are expressed from both the active and inactive X Chrs. Many of the genes that escape inactivation in human are subject to inactivation in mouse, raising questions concerning the mechanisms that govern expression from the inactive X Chr in the two species. In human, the existence of a cluster of genes in Xp11.21-p11.22 that escape inactivation suggests that control of X inactivation occurs at the level of chromosomal domains. In this study, we have isolated, physically mapped, and determined the X inactivation status of a number of the orthologous mouse genes that correspond to this human "escape domain". In contrast to human, only the mouse Smcx gene has been found to escape inactivation in this region thus far, despite a highly conserved physical map between the two species. Sequence analysis and functional characterization of the mouse Smcx promoter did not reveal any obvious unique features that would explain the difference in the behavior of this gene on the inactive X compared with other nearby genes. Possible mechanisms responsible for the differing inactivation status between genes in the escape domain in human Xp11. 21-p11.22 and the corresponding mouse region are discussed.