Project description:The dosage compensation complex (DCC) of Drosophila identifies its X chromosomal binding sites with exquisite selectivity. The principles that assure this vital targeting are known from the D. melanogaster model: DCC-intrinsic specificity of DNA binding, cooperativity with the CLAMP protein, and non-coding roX2 RNA transcribed from the X chromosome. We found that in D. virilis, a species separated from melanogaster by 40 million years of evolution, all principles are active, but contribute differently to X-specificity. In melanogaster, the DCC subunit MSL2 evolved intrinsic DNA-binding selectivity for rare PionX sites, which mark the X chromosome. In virilis, PionX sites are abundant and not X-enriched. Accordingly, MSL2 lacks specific recognition. Here, roX2 RNA plays a more instructive role, counteracting a non-productive interaction of CLAMP and modulating DCC binding selectivity. Remarkably, roX2 triggers a low-diffusion chromatin binding mode characteristic of DCC. Evidently, X-specific regulation is achieved by divergent evolution of similar components.

Project description:The rules according to which transcription factors selectively bind only a small subset of genomic sites from a vast pool of similar sequences are not understood. One of the most challenging tasks in DNA recognition is posed by dosage compensation systems that require the unequivocal distinction between a sex chromosome and all autosomes. In Drosophila melanogaster the male-specific-lethal dosage compensation complex (MSL-DCC) doubles the transcription output of most genes on the X chromosome via chromatin modification, but the nature of this selectivity is not known. We now found that MSL2, the male-specific organizer of the DCC, uses two distinct DNA interaction surfaces to read out previously identified X chromosomal ‘high affinity sites’. Specificity is provided by the interaction of the CXC domain with a novel, X-specific motif defined by DNA sequence and shape features. By several criteria these ‘PionX sites’ are primary determinants of X chromosome identity.

Project description:The rules according to which transcription factors selectively bind only a small subset of genomic sites from a vast pool of similar sequences are not understood. One of the most challenging tasks in DNA recognition is posed by dosage compensation systems that require the unequivocal distinction between a sex chromosome and all autosomes. In Drosophila melanogaster the male-specific-lethal dosage compensation complex (MSL-DCC) doubles the transcription output of most genes on the X chromosome via chromatin modification, but the nature of this selectivity is not known. We now found that MSL2, the male-specific organizer of the DCC, uses two distinct DNA interaction surfaces to read out previously identified X chromosomal ‘high affinity sites’. Specificity is provided by the interaction of the CXC domain with a novel, X-specific motif defined by DNA sequence and shape features. By several criteria these ‘PionX sites’ are primary determinants of X chromosome identity.

Project description:The rules according to which transcription factors selectively bind only a small subset of genomic sites from a vast pool of similar sequences are not understood. One of the most challenging tasks in DNA recognition is posed by dosage compensation systems that require the unequivocal distinction between a sex chromosome and all autosomes. In Drosophila melanogaster the male-specific-lethal dosage compensation complex (MSL-DCC) doubles the transcription output of most genes on the X chromosome via chromatin modification, but the nature of this selectivity is not known. We now found that MSL2, the male-specific organizer of the DCC, uses two distinct DNA interaction surfaces to read out previously identified X chromosomal ‘high affinity sites’. Specificity is provided by the interaction of the CXC domain with a novel, X-specific motif defined by DNA sequence and shape features. By several criteria these ‘PionX sites’ are primary determinants of X chromosome identity.

Project description:The dosage compensation complex (DCC) of Drosophila identifies its X chromosomal binding sites with exquisite selectivity. The principles that assure this vital targeting are known from the D. melanogaster model: DCC-intrinsic specificity of DNA binding, cooperativity with the CLAMP protein, and non-coding roX2 RNA transcribed from the X chromosome. We found that in D. virilis, a species separated from melanogaster by 40 million years of evolution, all principles are active, but contribute differently to X-specificity. In melanogaster, the DCC subunit MSL2 evolved intrinsic DNA-binding selectivity for rare PionX sites, which mark the X chromosome. In virilis, PionX sites are abundant and not X-enriched. Accordingly, MSL2 lacks specific recognition. Here, roX2 RNA plays a more instructive role, counteracting a non-productive interaction of CLAMP and modulating DCC binding selectivity. Remarkably, roX2 triggers a low-diffusion chromatin binding mode characteristic of DCC. Evidently, X-specific regulation is achieved by divergent evolution of similar components.

Project description:In D. melanogaster males, X chromosome monosomy is compensated by chromosome-wide transcription activation. We found that complete dosage compensation during embryogenesis takes surprisingly long. Although the activating Dosage Compensation Complex (DCC) associates with the chromosome and acetylates histone H4 early, many genes are not compensated. Acetylation levels on gene bodies continue to increase for several hours after gastrulation in parallel with progressive compensation. Constitutive genes are compensated earlier than developmental genes. Remarkably, later compensation correlates with longer distances to DCC binding sites. This time-space relationship suggests that DCC action on target genes requires maturation of the active chromosome compartment.

Project description:In D. melanogaster males, X chromosome monosomy is compensated by chromosome-wide transcription activation. We found that complete dosage compensation during embryogenesis takes surprisingly long. Although the activating Dosage Compensation Complex (DCC) associates with the chromosome and acetylates histone H4 early, many genes are not compensated. Acetylation levels on gene bodies continue to increase for several hours after gastrulation in parallel with progressive compensation. Constitutive genes are compensated earlier than developmental genes. Remarkably, later compensation correlates with longer distances to DCC binding sites. This time-space relationship suggests that DCC action on target genes requires maturation of the active chromosome compartment.

Project description:Dosage compensation ensures that males and females, despite unequal number of X chromosomes, equalize for X linked gene expression. In Drosophila, it is achieved by a two-fold up-regulation of most of the genes present on the male X chromosome, and requires the association of the Dosage Compensation Complex (DCC) on the X chromosome. One of the main intriguing aspects of dosage compensation is how this complex is able to target specifically hundreds of sites only on the X chromosome in order to ensure dosage compensation. In order to better understand the targeting of the DCC and the dosage compensation mechanism, we have then decided to analyze the distribution of the DCC as well as the expression levels in male and female in a more complete and precise manner, using microarrays. In this experiment, we present the data used to analyse the distribution of the MSL-1 and MSL-3 protein (part of the DCC complex) on the X chromosome in WT embryos aged from 0H-14H, as well as the distribution of MSL-1 in embryos aged from 4-6H and in male III instar salivary glands. The DNA amplified from the specific immunoprecipitation (MSL-1 or MSL-3 IP) were labelled using Cy5-dCTP and hybridized against DNA amplified from a non specific immunoprecipitation (mock IP), labeled with Cy3 dye. In parralel we present the data used to analyse the expression profile of X-linked genes in WT male or female III instar larvae salivary glands. The cDNA amplified from the RNA extracted from the male or female salivary glands were labelled using Cy5-dUTP and hybridized against the reference sample, labelled with Cy3-dUTP (pool RNA from ON embryos, adultes, and salivary glands mixed at a ratio 1:1:1.and amplified as the RNA from salivary glands). We used for this study a cDNA array developed by the Genecore facility in EMBL, covering the DGC1 and DGC2 cDNA libraries from the Berkeley Drosophila Genome Project, which represents more than 70% of the coding Drosophila genome.

Project description:Mechanisms establishing higher-order chromosome structures and their roles in gene regulation are elusive. We analyzed chromosome architecture during nematode X-chromosome dosage compensation, which represses transcription via a dosage-compensation condensin complex (DCC) that binds hermaphrodite Xs and establishes megabase-size topologically associating domains (TADs). We show that DCC binding at high-occupancy sites (rex sites) defines eight TAD boundary locations. Single rex deletions disrupted boundaries, and single insertions created new boundaries, demonstrating one rex site is necessary and sufficient for DCC-dependent boundary formation. Deleting eight rex sites (8rexΔ) recapitulated TAD structure of DCC mutants, permitting analysis when chromosome-wide domain architecture was disrupted but most DCC binding remained. 8rexΔ animals exhibited no changes in X expression and lacked dosage-compensation mutant phenotypes. Hence, TAD boundaries are neither the cause nor consequence of gene repression during dosage compensation. Abrogating TAD structure did, however, reduce thermotolerance, accelerate aging, and shorten lifespan, implicating chromosome architecture in regulating stress responses and aging.

Project description:Mechanisms establishing higher-order chromosome structures and their roles in gene regulation are elusive. We analyzed chromosome architecture during nematode X-chromosome dosage compensation, which represses transcription via a dosage-compensation condensin complex (DCC) that binds hermaphrodite Xs and establishes megabase-size topologically associating domains (TADs). We show that DCC binding at high-occupancy sites (rex sites) defines eight TAD boundary locations. Single rex deletions disrupted boundaries, and single insertions created new boundaries, demonstrating one rex site is necessary and sufficient for DCC-dependent boundary formation. Deleting eight rex sites (8rexΔ) recapitulated TAD structure of DCC mutants, permitting analysis when chromosome-wide domain architecture was disrupted but most DCC binding remained. 8rexΔ animals exhibited no changes in X expression and lacked dosage-compensation mutant phenotypes. Hence, TAD boundaries are neither the cause nor consequence of gene repression during dosage compensation. Abrogating TAD structure did, however, reduce thermotolerance, accelerate aging, and shorten lifespan, implicating chromosome architecture in regulating stress responses and aging.