Many animal species use a chromosome-based mechanism of sex determination, which has led to the coordinate evolution of dosage-compensation systems. Dosage compensation not only corrects the imbalance in the number of X chromosomes between the sexes but also is hypothesized to correct dosage imbalance within cells that is due to monoallelic X-linked expression and biallelic autosomal expression, by upregulating X-linked genes twofold (termed ‘Ohno’s hypothesis’). Although this hypothesis is well supported by expression analyses of individual X-linked genes and by microarray-based transcriptome analyses, it was challenged by a recent study using RNA sequencing and proteomics. We obtained new, independent RNA-seq data, measured RNA polymerase distribution and reanalyzed published expression data in mammals, C. elegans and Drosophila. Our analyses, which take into account the skewed gene content of the X chromosome, support the hypothesis of upregulation of expressed X-linked genes to balance expression of the genome.
Introductory paragraphAmong organisms with chromosome-based mechanisms of sex determination, failure to equalize expression of X-linked genes between the sexes is typically lethal. In C. elegans, XX hermaphrodites halve transcription from each X chromosome to match the output of XO males 1 . Here, we mapped the binding location of the condensin homolog DPY-27 and the zinc finger protein SDC-3, two components of the C. elegans dosage compensation complex (DCC) 2,3 . Strong foci of DCC binding were observed on X, around which broader regions of localization were centered. Binding foci, but not adjacent regions of localization, were distinguished by clusters of a stereotypic 10-bp DNA sequence, suggesting a recruitment-andspreading mechanism for X recognition. In contrast to the Drosophila DCC, the C. elegans DCC was bound preferentially upstream of genes, suggesting modulation of transcriptional initiation and polymerase-coupled spreading. A mechanism for tuning DCC activity at specific loci was indicated by stronger DCC binding upstream of genes with high transcriptional activity. These data provide a basis for understanding how proteins involved in higher-order chromosome dynamics can regulate transcription at individual loci. Main TextTo compensate for differences in X-linked gene dosage between XY males and XX females, mammals inactivate most genes on one of the two female X chromosomes 4 . In contrast, C. elegans XX hermaphrodites dosage compensate by reducing transcription from each X chromosome by a factor of two to match the expression of XO males 1 . This mechanism is remarkable in that the subtle two-fold downregulation is imposed upon X-linked genes expressed over a large dynamic range 5,6 . The dosage compensation complex (DCC) required for C. elegans X-repression is composed of proteins encoded by the genes sdc-1, sdc-2, sdc-3, dpy-21, dpy-26, dpy-27, dpy-28, dpy-30 and mix-1 7 . DPY-26, DPY-27, DPY-28 and MIX-1 are homologous to members of the condensin complex, which is required for chromosome condensation and segregation in organisms ranging from bacteria to humans 8 . While the *Correspondence should be addressed to: Jason D. Lieb jlieb@bio.unc.edu (919) 843-3228. AUTHOR CONTRIBUTIONS This study was designed by SE and JDL. SE conducted the experiments. SE, PGG, CMW, and JDL conducted the data analysis. XZ and RDG designed, manufactured, and hybridized the DNA microarrays. SE and JDL wrote the paper. COMPETING INTERESTS STATEMENTThe authors declare that they have no competing financial interests. NIH Public Access NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author Manuscript molecular parallels to mitotic chromosome condensation broadly suggest a mechanism for reducing X-linked transcription 9,10 , the features of X that control DCC binding have proven more difficult to investigate. Four loci on X (rex-1-4) sufficient for DCC recruitment were identified recently by using confocal microscopy to detect DCC binding to multiple-copy extrachromosomal transgenic DNA 11,12 . Here, we take an ...
Studies of X chromosome evolution in various organisms have indicated that sex-biased genes are nonrandomly distributed between the X and autosomes. Here, to extend these studies to nematodes, we annotated and analyzed X chromosome gene content in four Caenorhabditis species and in Pristionchus pacificus. Our gene expression analyses comparing young adult male and female mRNAseq data indicate that, in general, nematode X chromosomes are enriched for genes with high female-biased expression and depleted of genes with high male-biased expression. Genes with low sex-biased expression do not show the same trend of X chromosome enrichment and depletion. Combined with the observation that highly sex-biased genes are primarily expressed in the gonad, differential distribution of sex-biased genes reflects differences in evolutionary pressures linked to tissue-specific regulation of X chromosome transcription. Our data also indicate that X dosage imbalance between males (XO) and females (XX) is influential in shaping both expression and gene content of the X chromosome. Predicted upregulation of the single male X to match autosomal transcription (Ohno's hypothesis) is supported by our observation that overall transcript levels from the X and autosomes are similar for highly expressed genes. However, comparison of differentially located one-to-one orthologs between C. elegans and P. pacificus indicates lower expression of X-linked orthologs, arguing against X upregulation. These contradicting observations may be reconciled if X upregulation is not a global mechanism but instead acts locally on a subset of tissues and X-linked genes that are dosage sensitive. IN an XY sex-determination system, male and female genomes are identical with the exception of the male-specific Y chromosome, which bears few genes (Charlesworth et al. 2005). This is particularly true when the Y chromosome is thought to be completely lost, as is the case for C. elegans and many other nematodes (Walton 1940). Because gene content is the same, phenotypic differences between males and females, termed "sexual dimorphisms," must be caused by differential gene expression between the two sexes (Connallon and Knowles 2005;Ellegren and Parsch 2007). Throughout the article, such differentially expressed genes are referred to as "sex biased." As males and females have different fitness optima, a trait that is beneficial to one sex can be harmful to the other (termed sexual antagonism) (Rice and Chippindale 2001;Arnqvist 2004;Connallon and Knowles 2005;Ellegren and Parsch 2007;Mank et al. 2008a;Rice 1984). The evolution of sex-biased gene expression is thought to mediate the effects of sexual antagonism and allow for achievement of sex-specific fitness. Previous studies have indicated that anywhere between 30 and 60% of metazoan genes may be sex biased Parisi et al. 2004;Reinke et al. 2004;Yang et al. 2006;Reinius et al. 2008;Small et al. 2009;Innocenti and Morrow 2010;Assis et al. 2012;Reinius et al. 2012;Thomas et al. 2012). Genes with sex-biased exp...
In Caenorhabditis elegans, the dosage compensation complex (DCC) specifically binds to and represses transcription from both X chromosomes in hermaphrodites. The DCC is composed of an X-specific condensin complex that interacts with several proteins. During embryogenesis, DCC starts localizing to the X chromosomes around the 40-cell stage, and is followed by X-enrichment of H4K20me1 between 100-cell to comma stage. Here, we analyzed dosage compensation of the X chromosome between sexes, and the roles of dpy-27 (condensin subunit), dpy-21 (non-condensin DCC member), set-1 (H4K20 monomethylase) and set-4 (H4K20 di-/tri-methylase) in X chromosome repression using mRNA-seq and ChIP-seq analyses across several developmental time points. We found that the DCC starts repressing the X chromosomes by the 40-cell stage, but X-linked transcript levels remain significantly higher in hermaphrodites compared to males through the comma stage of embryogenesis. Dpy-27 and dpy-21 are required for X chromosome repression throughout development, but particularly in early embryos dpy-27 and dpy-21 mutations produced distinct expression changes, suggesting a DCC independent role for dpy-21. We previously hypothesized that the DCC increases H4K20me1 by reducing set-4 activity on the X chromosomes. Accordingly, in the set-4 mutant, H4K20me1 increased more from the autosomes compared to the X, equalizing H4K20me1 level between X and autosomes. H4K20me1 increase on the autosomes led to a slight repression, resulting in a relative effect of X derepression. H4K20me1 depletion in the set-1 mutant showed greater X derepression compared to equalization of H4K20me1 levels between X and autosomes in the set-4 mutant, indicating that H4K20me1 level is important, but X to autosomal balance of H4K20me1 contributes only slightly to X-repression. Thus H4K20me1 by itself is not a downstream effector of the DCC. In summary, X chromosome dosage compensation starts in early embryos as the DCC localizes to the X, and is strengthened in later embryogenesis by H4K20me1.
In many organisms, it remains unclear how X chromosomes are specified for dosage compensation, since DNA sequence motifs shown to be important for dosage compensation complex (DCC) recruitment are themselves not X-specific. Here, we addressed this problem in C. elegans. We found that the DCC recruiter, SDC-2, is required to maintain open chromatin at a small number of primary DCC recruitment sites, whose sequence and genomic context are X-specific. Along the X, primary recruitment sites are interspersed with secondary sites, whose function is X-dependent. A secondary site can ectopically recruit the DCC when additional recruitment sites are inserted either in tandem or at a distance (>30 kb). Deletion of a recruitment site on the X results in reduced DCC binding across several megabases surrounded by topologically associating domain (TAD) boundaries. Our work elucidates that hierarchy and long-distance cooperativity between gene-regulatory elements target a single chromosome for regulation.DOI: http://dx.doi.org/10.7554/eLife.23645.001
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