Dosage compensation

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

Dosage compensation in Drosophila melanogaster : epigenetic fine-tuning of chromosome-wide transcription

Abstract: Dosage compensation is an epigenetic mechanism that normalizes gene expression from unequal copy numbers of sex chromosomes. Different organisms have evolved alternative molecular solutions to this task. In Drosophila melanogaster, transcription of the single male X chromosome is upregulated by twofold in a process orchestrated by the dosage compensation complex. Despite this conceptual simplicity, dosage compensation involves multiple coordinated steps to recognize and activate the entire X chromosome. We are only beginning to understand the intriguing interplay between multiple levels of local and long-range chromatin regulation required for the fine-tuned transcriptional activation of a heterogeneous gene population. This Review highlights the known facts and open questions of dosage compensation in D. melanogaster.

Modeling stochastic gene expression: Implications for haploinsufficiency

Abstract: There is increasing recognition that stochastic processes regulate highly predictable patterns of gene expression in developing organisms, but the implications of stochastic gene expression for understanding haploinsufficiency remain largely unexplored We have used simulations of stochastic gene expression to illustrate that gene copy number and expression deactivation rates are important variables in achieving predictable outcomes In gene expression systems with non-zero expression deactivation rates, diploid systems had a higher probability of uninterrupted gene expression than haploid systems and were more successful at maintaining gene product above a very low threshold Systems with relatively rapid expression deactivation rates (unstable gene expression) had more predictable responses to a gradient of inducer than systems with slow or zero expression deactivation rates (stable gene expression), and diploid systems were more predictable than haploid, with or without dosage compensation We suggest that null mutations of a single allele in a diploid organism could decrease the probability of gene expression and present the hypothesis that some haploinsufficiency syndromes might result from an increased susceptibility to stochastic delays of gene initiation or interruptions of gene expression

Modulation of ISWI function by site‐specific histone acetylation

Abstract: Mutations in Drosophila ISWI, a member of the SWI2/SNF2 family of chromatin remodeling ATPases, alter the global architecture of the male X chromosome. The transcription of genes on this chromosome is increased 2-fold relative to females due to dosage compensation, a process involving the acetylation of histone H4 at lysine 16 (H4K16). Here we show that blocking H4K16 acetylation suppresses the X chromosome defects resulting from loss of ISWI function in males. In contrast, the forced acetylation of H4K16 in ISWI mutant females causes X chromosome defects indistinguishable from those seen in ISWI mutant males. Increased expression of MOF, the histone acetyltransferase that acetylates H4K16, strongly enhances phenotypes resulting from the partial loss of ISWI function. Peptide competition assays revealed that H4K16 acetylation reduces the ability of ISWI to interact productively with its substrate. These findings suggest that H4K16 acetylation directly counteracts chromatin compaction mediated by the ISWI ATPase.

Demasculinization of X chromosomes in the Drosophila genus

Abstract: This issue includes a landmark collection of papers on the stalwart of the genetics lab, the Drosophila fruit fly. The centrepiece is the publication by the Drosophila 12 Genomes Consortium of the genomic sequence for ten Drosophila species. The paper compares the newly sequenced genomes (sechellia, simulans, yakuba, erecta, ananassae, persimilis, willistoni, mojavensis, virilis and grimshawi species), with the two previously known sequences for D. melanogaster and D. pseudoobscura. The resulting database of genetic variation will be invaluable for the study of the forces of evolutionary change. A second major collaboration has mined the dozen Drosophila genome sequences for conserved elements, and reports the relationship between conservation and function for many specific sequence motifs. A detailed regulatory network emerges, identifying protein-coding genes and exons, RNA genes, microRNAs and their targets. These papers are discussed in News and Views. Two further research papers use the new genomic data to study gene expression, first for genes with male-biased expression and those unique to each species and second, to track the evolution of gene dosage compensation on Drosophila sex chromosomes. Four new reviews focus on how the latest work on Drosophila is taking this genetically pliant lab model into exciting new fields. Pierre Leopold and Norbert Perrimon review advances in the study of endocrinology and homeostasis that are establishing Drosophila as a model for mammalian physiology. Drosophila has proved a powerful system in which to study the pathways controlling cell shape in growing tissue, as reported by Thomas Lecuit and Loic Le Goff. Leslie Vosshall reviews the remarkable work linking neural circuits and behaviour and John Lis reviews work on Drosophila that has rewritten the textbook view of gene transcription. The cover shows anaesthetized individuals of all twelve Drosophila species. The evolution of dosage compensation on Drosophila sex chromosomes is examined by using microarrays to determine relative gene expression of sex-linked genes in a number of fly species. How this expression changes over time is discussed, particularly in species with a neo-X chromosome, to determine why genes might have male-biased expression. X chromosomes evolve differently from autosomes, but general governing principles have not emerged1. For example, genes with male-biased expression are under-represented on the X chromosome of D. melanogaster2, but are randomly distributed in the genome of Anopheles gambiae3. In direct global profiling experiments using species-specific microarrays, we find a nearly identical paucity of genes with male-biased expression on D. melanogaster, D. simulans, D. yakuba, D. ananassae, D. virilis and D. mojavensis X chromosomes. We observe the same under-representation on the neo-X of D. pseudoobscura. It has been suggested that precocious meiotic silencing of the X chromosome accounts for reduced X chromosome male-biased expression in nematodes4, mammals5 and Drosophila6. We show that X chromosome genes with male-biased expression are under-represented in somatic cells and in mitotic male germ cells. These data are incompatible with simple X chromosome inactivation models. Using expression profiling and comparative sequence analysis, we show that selective gene extinction on the X chromosome, creation of new genes on autosomes and changed genomic location of existing genes contribute to the unusual X chromosome gene content.

Transcriptional analysis of nucleolar dominance in polyploid plants: Biased expression/silencing of progenitor rRNA genes is developmentally regulated in Brassica

Abstract: Nucleolar dominance is an epigenetic phenomenon that describes the formation of nucleoli around rRNA genes inherited from only one parent in the progeny of an interspecific hybrid. Despite numerous cytogenetic studies, little is known about nucleolar dominance at the level of rRNA gene expression in plants. We used S1 nuclease protection and primer extension assays to define nucleolar dominance at a molecular level in the plant genus Brassica. rRNA transcription start sites were mapped in three diploids and in three allotetraploids (amphidiploids) and one allohexaploid species derived from these diploid progenitors. rRNA transcripts of only one progenitor were detected in vegetative tissues of each polyploid. Dominance was independent of maternal effect, ploidy, or rRNA gene dosage. Natural and newly synthesized amphidiploids yielded the same results, arguing against substantial evolutionary effects. The hypothesis that nucleolar dominance in plants is correlated with physical characteristics of rRNA gene intergenic spacers is not supported in Brassica. Furthermore, in Brassica napus, rRNA genes silenced in vegetative tissues were found to be expressed in all floral organs, including sepals and petals, arguing against the hypothesis that passage through meiosis is needed to reactivate suppressed genes. Instead, the transition of inflorescence to floral meristem appears to be a developmental stage when silenced genes can be derepressed.