Abstract
Higher order chromosome structure and nuclear architecture can have profound effects on gene regulation. We analyzed how compartmentalizing the genome by tethering heterochromatic regions to the nuclear lamina affects dosage compensation in the nematode C. elegans. In this organism, the dosage compensation complex (DCC) binds both X chromosomes of hermaphrodites to repress transcription two-fold, thus balancing gene expression between XX hermaphrodites and XO males. X chromosome structure is disrupted by mutations in DCC subunits. Using X chromosome paint fluorescence microscopy, we found that X chromosome structure and subnuclear localization are also disrupted when the mechanisms that anchor heterochromatin to the nuclear lamina are defective. Strikingly, the heterochromatic left end of the X chromosome is less affected than the gene-rich middle region, which lacks heterochromatic anchors. These changes in X chromosome structure and subnuclear localization are accompanied by small, but significant levels of derepression of X-linked genes as measured by RNA-seq, without any observable defects in DCC localization and DCC-mediated changes in histone modifications. We propose a model in which heterochromatic tethers on the left arm of the X cooperate with the DCC to compact and peripherally relocate the X chromosomes, contributing to gene repression.
Highlights
Expression of genes must be tightly regulated both spatially and temporarily to ensure normal development
We studied the effects of DNA compaction and nuclear localization on gene expression levels using regulation of the X chromosomes in the nematode Caenorhabditis elegans as a model
Our results suggest that regions of the left end of the X chromosome are anchored to the nuclear periphery by an additional mechanism that is independent of SET-25, CEC-4, and LEM-2, and loss of H3K9me3-lamina mediated anchoring mechanism is not sufficient to significantly relocate this region
Summary
Expression of genes must be tightly regulated both spatially and temporarily to ensure normal development. While our understanding of gene regulation at the level of transcription factor binding and modulation of chromatin structure is supported by an abundance of data, the contribution of the spatial organization of the nucleus to regulation of gene expression is not well understood. In the nematode C. elegans, dosage compensation downregulates expression of genes on the otherwise highly expressed X chromosomes of hermaphrodites, such that transcript levels from the two hermaphrodite X chromosomes are brought down to match transcript levels from the single X in males [1, 2]. A complex of proteins called the dosage compensation complex (DCC) binds the length of both hermaphrodite X chromosomes to regulate transcription. The DCC contains a subcomplex, condensin IDC, which is homologous to condensin complexes in all eukaryotes responsible for compaction and segregation of chromosomes in mitosis and meiosis [3,4,5]
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