Migraine is a debilitating neurological disorder affecting around 1 in 7 people worldwide, but its molecular mechanisms remain poorly understood. Some debate exists over whether migraine is a disease of vascular dysfunction or a result of neuronal dysfunction with secondary vascular changes. Genome-wide association (GWA) studies have thus far identified 13 independent loci associated with migraine. To identify new susceptibility loci, we performed the largest genetic study of migraine to date, comprising 59,674 cases and 316,078 controls from 22 GWA studies. We identified 44 independent single nucleotide polymorphisms (SNPs) significantly associated with migraine risk (P < 5 × 10−8) that map to 38 distinct genomic loci, including 28 loci not previously reported and the first locus identified on chromosome X. In subsequent computational analyses, the identified loci showed enrichment for genes expressed in vascular and smooth muscle tissues, consistent with a predominant theory of migraine that highlights vascular etiologies.
SUMMARY This report identifies human skeletal diseases associated with mutations in WNT1. In ten family members with dominantly inherited early-onset osteoporosis, a heterozygous missense variation c.652T>G (p.Cys218Gly) in WNT1 segregated with the disease, and a homozygous nonsense mutation (c.884C>A, p.Ser295*) was identified in two siblings with recessive osteogenesis imperfecta. In vitro, aberrant forms of WNT1 protein showed impaired capacity to induce canonical WNT signaling, their target genes, and mineralization. Wnt1 was clearly expressed in bone marrow, especially in B cell lineage and hematopoietic progenitors; lineage tracing identified expression in a subset of osteocytes, suggesting altered cross-talk of WNT signaling between hematopoietic and osteoblastic lineage cells in these diseases.
Migraine without aura is the most common form of migraine, characterized by recurrent disabling headache and associated autonomic symptoms. To identify common genetic variants for this migraine type, we analyzed genome-wide association data of 2,326 clinic-based German and Dutch patients and 4,580 population-matched controls. We selected SNPs from 12 loci with two or more SNPs with P-values < 1 × 10 −5 for follow-up in 2,508 patients and 2,652 controls. Two loci, i.e. 1q22 (MEF2D) and 3p24 (near TGFBR2) replicated convincingly (P = 4.9 × 10 −4 , P = 1.0 × 10 −4 , respectively). Meta-analysis of the discovery and replication data yielded two additional genome-wide significant (P < 5 × 10 −8 ) loci in PHACTR1 and ASTN2. In addition, SNPs in two previously reported migraine loci in or near TRPM8 and LRP1 significantly replicated. This study reveals the first susceptibility loci for migraine without aura, thereby expanding our knowledge of this debilitating neurological disorder. Main textMigraine is a disabling episodic neurovascular brain disorder affecting 12% of the general population [1][2][3][4] . Migraine attacks are typically characterized by severe throbbing unilateral headache and nausea, vomiting and photo-and phonophobia (migraine without aura; MO). In up to one third of patients attacks may be associated with neurological aura symptoms (migraine with aura; MA). Previous genome-wide association studies (GWAS) identified a migraine susceptibility locus on chromosome 8q22, close to MTDH, in the clinic-based International Headache Genetics Consortium (IHGC) MA study 5 and three other loci in or near PRDM16, LRP1, and TRPM8 in the population-based migraine Women's Genome Health Study (WGHS) 6 . For TRPM8 there was suggestive association (P < 1 × 10 −5 ) also in the clinic-based IHGC MA GWAS 5 . Here we report the first GWAS in MO, the most common form of migraine. We analyzed two large samples from headache centres in Germany and the Netherlands including 2,326 MO patients and 4,580 population-matched controls (Supplementary Note and Supplementary Fig. 1). A quantile-quantile plot of the joint analysis ( Supplementary Fig. 2) and an overall inflation factor ( 1000) of 1.03 were used as final quality control measures. The discovery dataset identified one genome-wide significant (P < 5 × 10 −8 ) locus on chromosome 1q22 as well as eleven additional loci containing multiple SNPs with suggestive association (P < 1 × 10 −5 ) (Supplementary Table 1). Eighteen SNPs from these 12 loci were taken forward to the replication stage in four Fig. 1 and Supplementary Table 1). Eight SNPs in six loci showed P-values < 0.05 in the replication study, and five of these SNPs also showed P-values < 5 × 10 −8 in the meta-analysis combining the discovery and replication cohorts (Table 1, Fig. 1 and Supplementary Fig. 3). Four loci (1q22, 3p24, 6p24, 9q33) replicated, although replication was less convincing for loci on 6p24 and 9q33 with replication P-values of 0.012 and 0.018, respectively, although P-values were < 5 × ...
Genome-wide association study of migraine implicates a common susceptibility variant on 8q22.1
Migraine is a common episodic neurological disorder, typically presenting with recurrent attacks of severe headache and autonomic dysfunction. Apart from rare monogenic subtypes, no genetic or molecular markers for migraine have been convincingly established. We identified the minor allele of rs1835740 on chromosome 8q22.1 to be associated with migraine (p=5.12 × 10−9, OR 1.23 [1.150-1.324]) in a genome-wide association study of 2,748 migraineurs from three European headache clinics and 10,747 population-matched controls. The association was replicated in 3,202 cases and 40,062 controls for an overall meta-analysis p-value of 1.60 × 10−11 (OR 1.18 [1.127 – 1.244]). rs1835740 is located between the astrocyte elevated gene 1 (MTDH/AEG-1) and plasma glutamate carboxypeptidase (PGCP). In an expression quantitative trait study in lymphoblastoid cell lines transcript levels of the MTDH/AEG-1 were found to have a significant correlation to rs1835740. Our data establish rs1835740 as the first genetic risk factor for migraine.
IntroductionHematopoietic stem cells (HSCs) have the unique ability to undergo self-renewal and to differentiate into cells belonging to multiple hematopoietic lineages. 1,2 These properties allow stem cells to maintain hematopoiesis throughout the life span of an organism. The knowledge of the behavior of HSCs is limited due to their rarity, difficulty of efficient isolation, and sensitivity to manipulation. 1,2 The self-renewal capacity of several classes of stem cells is thought to be controlled by external signals and intrinsic cellular processes. [1][2][3][4] Over the last 2 decades, a variety of external stimuli (cytokines, matrix proteins) that alter HSC self-renewal have been the subject of intense investigation. Although a number of such external signals that interact with specific receptors on HSC have been identified, the signaling mechanisms that govern HSC self-renewal have eluded investigation. Intrinsic cellular mechanisms that regulate stem cell self-renewal have been explored in a variety of model systems including germline stem cells (GSCs) in several lower species. Drosophila has been a particularly useful model for studying biologic processes that are conserved in higher developmental systems. [5][6][7][8][9][10][11][12] Therefore, in an attempt to define candidate genes that are responsible for human HSC self-renewal, we have explored the expression of genes in humans that have recently been demonstrated to play a role in Drosophila GSC self-renewal.The GSCs provide a continuous source of totipotent cells for the production of gametes needed for fertilization. 8 They are similar to HSCs in their ability to not only self-renew but also to remain capable of generating large numbers of differentiated daughter cells. 8,9 The intracellular mechanisms that serve as the determinants of asymmetric-segregating cell fates of GSCs depend not only on the basic cell cycle machinery but also on a family of recently identified genes, some of which are evolutionarily conserved. 7,9 A group of somatic cells in Drosophila, termed terminal filament cells, which lie distal and immediately adjacent to the GSCs, have been shown to regulate GSC division. 8,10,11 Laser ablation of the terminal filament increases the rate of oogenesis by 40%. 12 Loss of function mutations in a gene found in the terminal filament, termed piwi, leads to a failure of stem cell maintenance 7,10 ; piwi is expressed not only in the terminal filament but also in the germline. Loss of piwi function in the germline, however, is not known to affect GSC division. The protein encoded by piwi is extraordinarily well conserved along the evolutionary tree, being found in both Caenorhabditis elegans and primates. 7 Our laboratory has attempted to determine if such genes were present in primitive hematopoietic cells and if they might play a role in HSC development. We report here the presence of a human homologue of the piwi gene, termed hiwi, in a variety of primitive hematopoietic cells. The hiwi gene represents a candidate gene that may play a ro...
Genome-wide analysis of 102,084 migraine cases identifies 123 risk loci and subtype-specific risk alleles
Migraine affects over a billion individuals worldwide but its genetic underpinning remains largely unknown. Here, we performed a genome-wide association study of 102,084 migraine cases and 771,257 controls and identified 123 loci, of which 86 are previously unknown. These loci provide an opportunity to evaluate shared and distinct genetic components in the two main migraine subtypes: migraine with aura and migraine without aura. Stratification of the risk loci using 29,679 cases with subtype information indicated three risk variants that seem specific for migraine with aura (in HMOX2, CACNA1A and MPPED2), two that seem specific for migraine without aura (near SPINK2 and near FECH) and nine that increase susceptibility for migraine regardless of subtype. The new risk loci include genes encoding recent migraine-specific drug targets, namely calcitonin gene-related peptide (CALCA/CALCB) and serotonin 1F receptor (HTR1F). Overall, genomic annotations among migraine-associated variants were enriched in both vascular and central nervous system tissue/cell types, supporting unequivocally that neurovascular mechanisms underlie migraine pathophysiology.
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