Dosage compensation

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

Multiple and independent cessation of recombination between avian sex chromosomes.

Abstract: Birds are characterized by female heterogamety; females carry the Z and W sex chromosomes, while males have two copies of the Z chromosome. We suggest here that full differentiation of the Z and W sex chromosomes of birds did not take place until after the split of major contemporary lineages, in the late Cretaceous. The ATP synthase α-subunit gene is now present in one copy each on the nonrecombining part of the W chromosome ( ATP5A1W ) and on the Z chromosome ( ATP5A1Z ). This gene seems to have evolved on several independent occasions, in different lineages, from a state of free recombination into two sex-specific and nonrecombining variants. ATP5A1W and ATP5A1Z are thus more similar within orders, relative to what W (or Z) are between orders. Moreover, this cessation of recombination apparently took place at different times in different lineages (estimated at 13, 40, and 65 million years ago in Ciconiiformes, Galliformes, and Anseriformes, respectively). We argue that these observations are the result of recent and traceable steps in the process where sex chromosomes gradually cease to recombine and become differentiated. Our data demonstrate that this process, once initiated, may occur independently in parallel in sister lineages.

Complete dosage compensation and sex-biased gene expression in the moth Manduca sexta.

Abstract: Sex chromosome dosage compensation balances homogametic sex chromosome expression with autosomal expression in the heterogametic sex, leading to sex chromosome expression parity between the sexes. If compensation is incomplete, this can lead to expression imbalance and sex-biased gene expression. Recent work has uncovered an intriguing and variable pattern of dosage compensation across species that includes a lack of complete dosage compensation in ZW species compared with XY species. This has led to the hypothesis that ZW species do not require complete compensation or that complete compensation would negatively affect their fitness. To date, only one study, a study of the moth Bombyx mori, has discovered evidence for complete dosage compensation in a ZW species. We examined another moth species, Manduca sexta, using high-throughput sequencing to survey gene expression in the head tissue of males and females. We found dosage compensation to be complete in M. sexta with average expression between the Z chromosome in males and females being equal. When genes expressed at very low levels are removed by filtering, we found that average autosome expression was highly similar to average Z expression, suggesting that the majority of genes in M. sexta are completely dosage compensated. Further, this compensation was accompanied by sex-specific gene expression associated with important sexually dimorphic traits. We suggest that complete dosage compensation in ZW species might be more common than previously appreciated and linked to additional selective processes, such as sexual selection. More ZW and lepidopteran species should now be examined in a phylogenetic framework, to understand the evolution of dosage compensation.

Codon Usage Bias and Effective Population Sizes on the X Chromosome versus the Autosomes in Drosophila melanogaster

Abstract: Codon usage bias (CUB) in Drosophila is higher for X-linked genes than for autosomal genes. One possible explanation is that the higher effective recombination rate for genes on the X chromosome compared with the autosomes reduces their susceptibility to Hill-Robertson effects, and thus enhances the efficacy of selection on codon usage. The genome sequence of D. melanogaster was used to test this hypothesis. Contrary to expectation, it was found that, after correcting for the effective recombination rate, CUB remained higher on the X than on the autosomes. In contrast, an analysis of polymorphism data from a Rwandan population showed that mean nucleotide site diversity at 4-fold degenerate sites for genes on the X is approximately three-quarters of the autosomal value after correcting for the effective recombination rate, compared with approximate equality before correction. In addition, these data show that selection for preferred versus unpreferred synonymous variants is stronger on the X than the autosomes, which accounts for the higher CUB of genes on the X chromosome. This difference in the strength of selection does not appear to reflect the effects of dominance of mutations affecting codon usage, differences in gene expression levels between X and autosomes, or differences in mutational bias. Its cause therefore remains unexplained. The stronger selection on CUB on the X chromosome leads to a lower rate of synonymous site divergence compared with the autosomes; this will cause a stronger upward bias for X than A in estimates of the proportion of nonsynonymous mutations fixed by positive selection, for methods based on the McDonald-Kreitman test.

X-chromosome inactivation as a system of gene dosage compensation to regulate gene expression.

Abstract: Publisher Summary X-inactivation center is thought to play a critical role, and the evidence for this comes from mouse X-autosome translocations. In such translocations, inactivation spreads from the X- chromosome into the attached autosomal material and can be detected by variegation in the expression of the coat-color genes located in the autosomal segment. This chapter describes X-chromosome inactivation as a system of gene dosage compensation to regulate gene expression. The two most extensively studied systems of gene dosage compensation are those in Drosophila melanogast er and in mammals and these systems show considerable differences. The most striking feature of the mammalian system is that two homologous chromosomes, the two X chromosomes of females, behave differently within the same cell, whereas in Drosophila homologs within a cell behave similarly and the compensation is obtained by differential chromosome behavior in the two sexes. A further difference is seen when the X chromosome is broken by translocations; in Drosophila , the different segments seem to behave autonomously, whereas in mammals, the behavior of separated segments is controlled by the X-inactivation center.