CSIR LIFE SCIENCE PREPARATION: X-chromosome Inactivation & Dosage Compensation

Dosage Compensation

A phenomenon of neutralization of differences in sex-linked gene doses, i.e. males with one X-chromosome and females with two X-chromosomes have identical X-linked gene products
First report of this phenomenon → Muller (1931) while working with the w^a allele observed that there is a mechanism compensating for the difference in the dosage of X-linked gene between the sexes
This has been shown true for all X-linked genes with the exception of only a few alleles
Dosage compensation in Drosophila does not operate through female X-chromosome, i.e. inactivation of one female X-chromosome that is seen in mammals in not observed in case of Drosophila

interspecific hybrid experiment of Dobhzansky (1955) D. insularis xx D. tropicalis

The single (haploid) male X-chromosome was twice as wide as the single (haploid) femakes X-chromosome → the male X-chromosome appears puffy and diffuse, it apparently works twice as hard as the single female X-chromosome
Transcription autoradiographic experiements of Mukherjee and Beermann (1965) suggested that the rate of transcription of the haploid male X-chromosome is 43% faster than that on a single female X-chromosome
The puffy and diffuse appearance of the male X-chromosome is an accepted cytological marker of dosage compensation

The primary determinant of the dosage compensation pathway is the X:A ratio → changing the X:A ratio results in alteration of X-chromosome transcription
The X:A ratio operates through Sxl gene

X-chromosome transcription is altered in Sxl mutants
Loss-of-function in females → X-chromosome is bloated and shows increased transcription
Gain-of-function in males → X-chromosome is condensed and transcription is reduced

Dosage compensation is not achieved through the genes of the sex determination pathway

w^a/w^b; dsx/dsx and w^a/Y; dsx/dsx females and males are intersexual but show female and male levels of X-chromosomr transcription

The target of Sex lethal (sxl) is a set of five known dosage compensation genes:

male lethal phenotype
rate of transcription, only 65% of WT male X-chromosome
chromosome appears narrow
genetic interdependence → mutation in any one of the msls results in male lethality, i.e. they must be functioning cooperatively in a complex → shown to be true since they co-immunoprecipitate, complex termed as "Compensasome"

Dosage compensation in Drosophila involves a male specific histone acetylation (16Lys-H4)
Two non-coding RNAs (products of rox-1 and rox-2 genes) are also involved in dosage compensation in Drosophila

Regulation of Dosage Compensation in Drosophila

remodeling the chromatin of the male X-chromosome through the assembly of the multi-protein complex
ensuring that the complex is directed to the correct target, i.e. the male X-chromosome
ensuring sex-specific expression of this complex, i.e. the complex should be functional only in the male

Dosage Compensation Regulators and their Function

Broad Function of Gene Product	Gene	Type of Product
Transcriptional Regulation through chromatin remodeling	male-specific lethal-2 (msl-2)	RING finger protein which interacts with msl-1 and is expressed only in males
	male-specific lethal-1 (msl-1)	a novel acidic protein that interacts with msl-2 and msl-3
	male-specific lethal-3 (msl-3)	a protein with a chromodomain motif that interacts with msl-1
	maleless or male lethal (mle)	ATP-dependent helicase that interacts with rox
	males absent on the first (mof)	male-specific histone acetyltransferase
	JIL-1	a kinase which is possibly involved in nucleosomal modification
Targeting to X-chromosome	RNA on the X-1, 2 (rox-1 and rox-2)	an RNA transcript of an X-linked gene
Sex-specific expression	Sex lethal (Sxl)	an RNA-binding protein which negatively regulates msl-2

CSIR LIFE SCIENCE PREPARATION