Beyond SNP Heritability: Polygenicity and Discoverability of Phenotypes Estimated with a Univariate Gaussian Mixture Model

Holland, Dominic; Frei, Oleksandr; Desikan, Rahul S.; Fan, Chun-Chieh; Shadrin, Alexey; Smeland, Olav B.; Sundar, V. S.; Thompson, Paul M.; Andreassen, Ole A.; Dale, Anders M.

doi:10.1101/133132

Cited by 31 publications

(65 citation statements)

References 90 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Across the 9 traits, the estimated proportions of common causal SNPs in each population (the sum of the 293 numbers of population-specific and shared causal SNPs) are consistent with previously reported estimates 294 of polygenicity in single populations 7,8,55,75,76 . For example, we estimate that approximately 10% of common 295…”

supporting

confidence: 79%

Localizing components of shared transethnic genetic architecture of complex traits from GWAS summary data

Shi

Burch²,

Johnson

et al. 2019

Preprint

View full text Add to dashboard Cite

1Despite strong transethnic genetic correlations reported in the literature for many complex traits, the non-2 transferability of polygenic risk scores across populations suggests the presence of population-specific 3 components of genetic architecture. We propose an approach that models GWAS summary data for one 4 trait in two populations to estimate genome-wide proportions of population-specific/shared causal SNPs. 5In simulations across various genetic architectures, we show that our approach yields approximately 6 unbiased estimates with in-sample LD and slight upward-bias with out-of-sample LD. We analyze 9 7 complex traits in individuals of East Asian and European ancestry, restricting to common SNPs (MAF > 8 5%), and find that most common causal SNPs are shared by both populations. Using the genome-wide 9 estimates as priors in an empirical Bayes framework, we perform fine-mapping and observe that high-10posterior SNPs (for both the population-specific and shared causal configurations) have highly correlated 11 effects in East Asians and Europeans. In population-specific GWAS risk regions, we observe a 2.8x 12 enrichment of shared high-posterior SNPs, suggesting that population-specific GWAS risk regions harbor 13 shared causal SNPs that are undetected in the other GWAS due to differences in LD, allele frequencies, 14 and/or sample size. Finally, we report enrichments of shared high-posterior SNPs in 53 tissue-specific 15 functional categories and find evidence that SNP-heritability enrichments are driven largely by many low-16 effect common SNPs. 17 respect to the set of variants included in the GWAS and can contain variants with indirect nonzero effects 52 that are statistical rather than biological in nature (this is analogous to the definition of SNP-heritability, 53 which is also a function of a specific set of SNPs 11,54-56 ). Through extensive simulations, we show that our 54 method yields approximately unbiased estimates of the proportions of population-specific/shared causal 55 variants if in-sample LD is used and slightly upward-biased estimates if LD is estimated from an external 56 reference panel. We then show that using these estimates as priors to perform fine-mapping (Methods) 57 produces well-calibrated per-SNP posterior probabilities and enrichment test statistics. We note that the 58 definition of enrichment used here is related to, but conceptually distinct from, definitions of SNP-59 heritability enrichment 13,16 . Under our framework, an enrichment of causal SNPs greater than 1 indicates 60 that, compared to the genome-wide background, there are more causal SNPs in that region than expected 57,58 61 (Methods). In contrast, an enrichment of SNP-heritability greater than 1 indicates that the average per-SNP 62 effect size in the region is larger than the genome-wide average per-SNP effect size. 63We apply our approach to publicly available GWAS summary statistics for 9 complex traits and 64 diseases in individuals of East Asian (EAS) and European (EUR) ancestry (average NEAS = 94,621, N...

show abstract

supporting

confidence: 79%

Localizing components of shared transethnic genetic architecture of complex traits from GWAS summary data

Shi

Burch²,

Johnson

et al. 2019

Preprint

View full text Add to dashboard Cite

show abstract

“…93 Measuring the effect size differences at an individual locus for two different traits determines whether the maximum effect of a variant is higher in one trait than another. Recent studies [94][95][96] have asked a broader question: Are effect size distributions of common variants across the genome in general stronger for neuroimaging traits than they are for neuropsychiatric disorders? Effect size distributions can be estimated by clustering the effect sizes of linkage disequilibrium (LD)-independent SNPs across the genomes into one of two general categories: (i) susceptibility SNPs, which show some level of nonzero effect sizes (although do not necessarily survive genome-wide significance); and (ii) SNPs that have signals so low they cannot be distinguished from no effect.…”

Section: Effect Sizes Of Genetic Variants On Brain Structurementioning

confidence: 99%

“…Genetic variants impacting psychiatric disorders are amongst the most polygenic studied with an estimated 10 000-50 000 susceptibility SNPs, 94 indicating that many genetic variants, each of exceedingly small effect size, impact risk for these disorders. 94,95 In comparison, ulcerative colitis and asthma are estimated to have only 1000-2000 susceptibility SNPs. 94 Within the realm of imaging genetics, the degree of polygenicity of the putamen is over 30-fold less than that of schizophrenia, again indicating a higher effect size distribution of a brain structure trait as compared to a disorder.…”

Section: Effect Sizes Of Genetic Variants On Brain Structurementioning

confidence: 99%

Mapping causal pathways from genetics to neuropsychiatric disorders using genome‐wide imaging genetics: Current status and future directions

Stein

2019

Psychiatry Clin Neurosci

View full text Add to dashboard Cite

Imaging genetics aims to identify genetic variants associated with the structure and function of the human brain. Recently, collaborative consortia have been successful in this goal, identifying and replicating common genetic variants influencing gross human brain structure as measured through magnetic resonance imaging. In this review, we contextualize imaging genetic associations as one important link in understanding the causal chain from genetic variant to increased risk for neuropsychiatric disorders. We provide examples in other fields of how identifying genetic variant associations to disease and multiple phenotypes along the causal chain has revealed a mechanistic understanding of disease risk, with implications for how imaging genetics can be similarly applied. We discuss current findings in the imaging genetics research domain, including that common genetic variants can have a slightly larger effect on brain structure than on risk for disorders like schizophrenia, indicating a somewhat simpler genetic architecture. Also, gross brain structure measurements share a genetic basis with some, but not all, neuropsychiatric disorders, invalidating the previously held belief that they are broad endophenotypes, yet pinpointing brain regions likely involved in the pathology of specific disorders. Finally, we suggest that in order to build a more detailed mechanistic understanding of the effects of genetic variants on the brain, future directions in imaging genetics research will require observations of cellular and synaptic structure in specific brain regions beyond the resolution of magnetic resonance imaging. We expect that integrating genetic associations at biological levels from synapse to sulcus will reveal specific causal pathways impacting risk for neuropsychiatric disorders.

show abstract

“…For example, they are agnostic about the number of genetic variants influencing a 18 phenotype and their effect sizes [4]. Both of these quantities can vary and still result in the same 19heritability, which is proportional to their product [5,6]. 20Recently, we developed a model which allows the breakdown of SNP-heritability into the number of 21 variants influencing a given phenotype (non-null variants) and the distribution of their effect sizes using 22 summary statistics from GWAS and detailed population-specific linkage disequilibrium (LD) structure [5, 23 6].…”

mentioning

confidence: 99%

“…It was shown that, in the framework of the infinitesimal model, 0 2 has 14 the same mathematical meaning as the intercept term in the LDSC model [6]. The last unknown factor in 15 (5), , is modeled as a random variable with point-normal mixture distribution, where the variance is 16 allowed to differ between different variant annotation categories: 17…”

mentioning

confidence: 99%

Annotation-Informed Causal Mixture Modeling (AI-MiXeR) reveals phenotype-specific differences in polygenicity and effect size distribution across functional annotation categories

Frei

et al. 2019

Preprint

Self Cite

View full text Add to dashboard Cite

1Determining the contribution of functional genetic categories is fundamental to understanding the 2 genetic etiology of complex human traits and diseases. Here we present Annotation Informed MiXeR: a 3 likelihood-based method to estimate the number of variants influencing a phenotype and their effect 4 sizes across different functional annotation categories of the genome using summary statistics from 5 genome-wide association studies. Applying the model to 11 complex phenotypes suggests diverse 6 patterns of functional category-specific genetic architectures across human diseases and traits. 7 8 Keywords: genetic architecture, complex traits, functional genetic categories, polygenicity, variant effect 9 size 10 11 Background 12 The rapid technological advances of the last years have provided an enormous amount of genetic data 13 thereby promoting the development of statistical methods aimed to unravel the genetic architecture of 14 complex traits [1]. A key effort has been to estimate SNP-based heritability, either using individual-level 15 genotype data [2], or summary-level statistics from genome-wide association studies (GWAS) [3]. 16 However, heritability estimates provide a limited picture of the genetic architecture underlying complex 17 phenotypes. For example, they are agnostic about the number of genetic variants influencing a 18 phenotype and their effect sizes [4]. Both of these quantities can vary and still result in the same 19heritability, which is proportional to their product [5,6]. 20Recently, we developed a model which allows the breakdown of SNP-heritability into the number of 21 variants influencing a given phenotype (non-null variants) and the distribution of their effect sizes using 22 summary statistics from GWAS and detailed population-specific linkage disequilibrium (LD) structure [5, 23 6]. This model assumes a uniform distribution of non-null variants with the same expected effect size 24 throughout the genome. However, prior genetic studies suggest that non-null variants are differentially for the same phenotype may differ depending on a GWAS's sample size, as well as on the coverage of 2 the tested variants. The samples of the GWAS tested here vary by more than one order of magnitude in 3 size, from approximately 5×10 4 for BD and ADHD to more than 7×10 5 for EA and height. In all 4 simulations, we kept the sample size constant (N = 10 5 ) and varied only the heritability (ℎ 2 =0.1, 0.4, 0.7). 5Since these quantities contribute to the GWAS z-scores distribution only through their product (follows 6 from formula (5)), our simulation scenario with N=10 5 and ℎ 2 =0.7 is equivalent to a scenario with, for 7 example, N=7×10 5 and ℎ 2 =0.1. Other aspects of potential GWAS-related issues (e.g. coverage of tested 8 Declarations 1

show abstract

Beyond SNP Heritability: Polygenicity and Discoverability of Phenotypes Estimated with a Univariate Gaussian Mixture Model

Cited by 31 publications

References 90 publications

Localizing components of shared transethnic genetic architecture of complex traits from GWAS summary data

Localizing components of shared transethnic genetic architecture of complex traits from GWAS summary data

Mapping causal pathways from genetics to neuropsychiatric disorders using genome‐wide imaging genetics: Current status and future directions

Annotation-Informed Causal Mixture Modeling (AI-MiXeR) reveals phenotype-specific differences in polygenicity and effect size distribution across functional annotation categories

Contact Info

Product

Resources

About