Rare risk variants associate with epigenetic dysregulation in migraine

Migraine has a heritability of up to 65%. Genome-wide association studies (GWAS) on migraine have identified 123 risk loci, explaining only 10.6% of migraine heritability. Thus, there is a considerable genetic component not identified with GWAS. Further, the causality of the identified risk loci remains inconclusive. Rare variants contribute to the risk of migraine but GWAS are often underpowered to detect these. Whole genome sequencing is reliable for analyzing rare variants but is not frequently used in large-scale. We assessed if rare variants in the migraine risk loci associated with migraine. We used a large cohort of whole genome sequenced migraine patients (1,040 individuals from 155 families). The findings were replicated in an independent case-control cohort (2,027 migraine patients, 1,650 controls). We found rare variants (minor allele frequency<0.1%) associated with migraine in a Polycomb Response Element in the ASTN2 locus. The association was independent of the GWAS lead risk variant in the locus. The findings place rare variants as risk factors for migraine. We propose a biological mechanism by which epigenetic regulation by Polycomb Response Elements plays a crucial role in migraine etiology.

Genomic organization of the autonomous regulatory domain of eyeless locus in Drosophila melanogaster

In Drosophila, expression of eyeless (ey) gene is restricted to the developing eyes and central nervous system. However, the flanking genes, myoglianin (myo), and bent (bt) have different temporal and spatial expression patterns as compared to the ey. How distinct regulation of ey is maintained is mostly unknown. Earlier, we have identified a boundary element intervening myo and ey genes (ME boundary) that prevents the crosstalk between the cis-regulatory elements of myo and ey genes. In the present study, we further searched for the cis-elements that define the domain of ey and maintain its expression pattern. We identify another boundary element between ey and bt, the EB boundary. The EB boundary separates the regulatory landscapes of ey and bt genes. The two boundaries, ME and EB, show a long-range interaction as well as interact with the nuclear architecture. This suggests functional autonomy of the ey locus and its insulation from differentially regulated flanking regions. We also identify a new Polycomb Response Element, the ey-PRE, within the ey domain. The expression state of the ey gene, once established during early development is likely to be maintained with the help of ey-PRE. Our study proposes a general regulatory mechanism by which a gene can be maintained in a functionally independent chromatin domain in gene-rich euchromatin.

Genomic organization of the autonomous regulatory domain of eyeless locus in Drosophila melanogaster

In Drosophila, expression of eyeless (ey) gene is restricted to the developing eyes and central nervous system. However, the flanking genes, myoglianin (myo), and bent (bt) have different temporal and spatial expression patterns as compared to the ey. How distinct regulation of ey is maintained is mostly unknown. Earlier, we have identified a boundary element intervening myo and ey genes (ME boundary) that prevents the crosstalk between the cis-regulatory elements of myo and ey genes. In the present study, we further searched for the cis-elements that define the domain of ey and maintain its expression pattern. We identify another boundary element between ey and bt, the EB boundary. The EB boundary separates the regulatory landscapes of ey and bt genes. The two boundaries, ME and EB, show a long-range interaction as well as interact with the nuclear architecture. This suggests functional autonomy of the ey locus and its insulation from differentially regulated flanking regions. We also identify a new Polycomb Response Element, the ey-PRE, within the ey domain. The expression state of the ey gene, once established during early development is likely to be maintained with the help of ey-PRE. Our study proposes a general regulatory mechanism by which a gene can be maintained in a functionally independent chromatin domain in gene-rich euchromatin.

Human PRE-PIK3C2B exhibits long-range intra- and inter-chromosomal interactions with genomic regions enriched in repressive marks

Human PRE-PIK3C2B is a dual nature polycomb response element that interacts with both polycomb as well as trithorax members. In the current study, using 4C-Seq (Capturing Circular Chromosomal Conformation-Sequencing), we identified long-range chromatin interactions associated with PRE-PIK3C2B and validated them with 3C-PCR. We identified both intra-as well as inter-chromosomal interactions, a large proportion of which were found to be closely distributed around transcriptional start sites (TSS). A significant number of interactions were also found to be associated with heterochromatic regions. Meta-analysis of ENCODE ChIP-Seq data identified an overall enrichment of YY1, CTCF as well as histone modification such as H3K4me3 and H3K27me marks in different cell lines. Almost 90% interactions were derived from either intronic or intergenic regions. among which large proportions of intronic interactors were either unique sequences or LINE/SINE derived. In case of intergenic interactions, majority of the interaction were associated with LINE/SINE repeats. We further found that genes proximal to the interactor sequences were co-expressed, they showed reduced expression. To the best of our knowledge this is one of the early demonstrations of long-range interaction of PRE sequences in human genome.

The bithorax complex iab-7 Polycomb Response Element has a novel role in the functioning of the Fab-7 chromatin boundary

Expression of the three Bithorax complex homeotic genes is orchestrated by nine parasegment-specific regulatory domains. Autonomy of each domain is conferred by boundary elements (insulators). Here, we have used an in situ replacement strategy to reanalyze the sequences required for the functioning of one of the best-characterized fly boundaries, Fab-7. It was initially identified by a deletion, Fab-71, that transformed parasegment (PS) 11 into a duplicate copy of PS12. Fab-71 deleted four nuclease hypersensitive sites, HS*, HS1, HS2, and HS3, located in between the iab-6 and iab-7 regulatory domains. Transgene and P-element excision experiments mapped the boundary to HS*+HS1+HS2, while HS3 was shown to be the iab-7 Polycomb response element (PRE). Recent replacement experiments showed that HS1 is both necessary and sufficient for boundary activity when HS3 is also presented in the replacement construct. Surprisingly, while HS1+HS3 combination has full boundary activity, we discovered that HS1 alone has only minimal function. Moreover, when combined with HS3, only the distal half of HS1, dHS1, is needed. A ∼1,000 kD multiprotein complex containing the GAF protein, called the LBC, binds to the dHS1 sequence and we show that mutations in dHS1 that disrupt LBC binding in nuclear extracts eliminate boundary activity and GAF binding in vivo. HS3 has binding sites for GAF and Pho proteins that are required for PRE silencing. In contrast, HS3 boundary activity only requires the GAF binding sites. LBC binding with HS3 in nuclear extracts, and GAF association in vivo depend upon the HS3 GAF sites, but not the Pho sites. Consistent with a role for the LBC in HS3 boundary activity, the boundary function of the dHS1+HS3mPho combination is lost when the flies are heterozygous for a mutation in the GAF gene. Taken together, these results reveal a novel function for the iab-7 PREs in chromosome architecture.Author SummaryPolycomb group proteins (PcG) are important epigenetic regulators of developmental genes in all higher eukaryotes. In Drosophila, these proteins are bound to specific regulatory DNA elements called Polycomb group Response Elements (PREs). PcG support proper patterns of homeotic gene expression throughout development. Drosophila PREs are made up of binding sites for a complex array of DNA binding proteins, including GAF and Pho. In the regulatory region of the bithorax complex (BX-C), the boundary/insulator elements organize the autonomous regulatory domains, and their active or repressed states are regulated by PREs. Here, we studied the domain organization of the Fab-7 boundary and the neighboring PRE, which separate the iab-6 and iab-7 domains involved in transcription of the Abd-B gene. It was previously thought that PRE recruits PcG proteins that inhibit activation of the iab-7 enhancers in the inappropriate domains. However, here we found that PRE contributes to boundary activity and in combination with a key 242 bp Fab-7 region (dHS1) can form a completely functional boundary. Late Boundary Complex (LBC) binds not only to dHS1 but also to PRE and is required for the boundary activity of both elements. At the same time, mutations of Pho binding sites strongly diminish recruiting of PcG but do not considerably affect boundary function, suggesting that these activities can be separated in PRE.

PTE, a novel module to target Polycomb Repressive Complex 1 to the Cyclin D2 oncogene

Polycomb Group proteins are essential epigenetic repressors. They form multiple protein complexes of which two kinds, PRC1 and PRC2, are indispensable for repression. Although much is known about their biochemical properties, how PRC1 and PRC2 are targeted to specific genes is poorly understood. Here we establish the Cyclin D2 (CCND2) oncogene as a simple model to address this question. We provide the evidence that coordinated recruitment of PRC1 and PRC2 complexes to CCND2 involves a combination of a specialized PRC1 targeting element (PTE) and an adjacent CpG-island, which together act as a human Polycomb Response Element. Chromatin immunoprecipitation analysis of CCND2 in different transcriptional states indicates that histone modifications produced by PRC1 and PRC2 are not sufficient to recruit either of the complexes. However, catalytic activity of PRC2 helps to anchor PRC1 at the PTE. Our analyses suggest that coordinated targeting of PRC1 and PRC2 complexes by juxtaposed AT-rich PTEs and CpG-islands may be a general feature of Polycomb repression in mammals.