[
J Genet,
2018]
Dosage compensation is a regulatory system designed to equalize the transcription output of the genes of the sex chromosomes that are present in different doses in the sexes (X or Z chromosome, depending on the animal species involved). Different mechanisms of dosage compensation have evolved in different animal groups. In Drosophila males, a complex (male-specific lethal) associates with the X chromosome and enhances the activity of most X-linked genes by increasing the rate of RNAPII elongation. In Caenorhabditis, a complex (dosage compensation complex) that contains a number of proteins involved in condensing chromosomes decreases the level of transcription of both X chromosomes in the XX hermaphrodite. In mammals, dosage compensation is achieved by the inactivation, early during development, of most X-linked genes on one of the two X chromosomes in females. The mechanism involves the synthesis of an RNA (Tsix) that protects one of the two Xs from inactivation, and of another RNA (Xist) that coats the other X chromosome and recruits histone and DNA modifying enzymes. This review will focus on the current progress in understanding the dosage compensation mechanisms in the three taxa where it has been best studied at the molecular level: flies, round worms and mammals.
[
Curr Opin Genet Dev,
1998]
Dosage compensation ensures that individuals with a single X chromosome have the same amount of most X-linked gene products as those with two. In Drosophila, this equalization is achieved by a two-fold enhancement of the level of transcription of the X in males (XY) relative to each X chromosome in females (XX). In Caenorhabditis, equalization of X-linked gene products between hermaphrodites (XX) and males (XO) is achieved by decreasing the activity of genes in the former. These two different solutions to the common problem of unequal dosage of X-linked genes in different sexes provide invaluable paradigms for the study of gene regulation at the level of chromatin remodeling.