Glastonbury Craig A, Viñuela Ana, Buil Alfonso, Halldorsson Gisli H, Thorleifsson Gudmar, Helgason Hannes, Thorsteinsdottir Unnur, Stefansson Kari, Dermitzakis Emmanouil T, Spector Tim D, Small Kerrin S
Department of Twin Research and Genetic Epidemiology, King's College London, London SE1 7EH, UK.
Department of Genetic Medicine and Development, University of Geneva Medical School, Geneva 1211, Switzerland.
Am J Hum Genet. 2016 Sep 1;99(3):567-579. doi: 10.1016/j.ajhg.2016.07.001.
Obesity is a global epidemic that is causally associated with a range of diseases, including type 2 diabetes and cardiovascular disease, at the population-level. However, there is marked heterogeneity in obesity-related outcomes among individuals. This might reflect genotype-dependent responses to adiposity. Given that adiposity, measured by BMI, is associated with widespread changes in gene expression and regulatory variants mediate the majority of known complex trait loci, we sought to identify gene-by-BMI (G × BMI) interactions on the regulation of gene expression in a multi-tissue RNA-sequencing (RNA-seq) dataset from the TwinsUK cohort (n = 856). At a false discovery rate of 5%, we identified 16 cis G × BMI interactions (top cis interaction: CHURC1, rs7143432, p = 2.0 × 10(-12)) and one variant regulating 53 genes in trans (top trans interaction: ZNF423, rs3851570, p = 8.2 × 10(-13)), all in adipose tissue. The interactions were adipose-specific and enriched for variants overlapping adipocyte enhancers, and regulated genes were enriched for metabolic and inflammatory processes. We replicated a subset of the interactions in an independent adipose RNA-seq dataset (deCODE genetics, n = 754). We also confirmed the interactions with an alternate measure of obesity, dual-energy X-ray absorptiometry (DXA)-derived visceral-fat-volume measurements, in a subset of TwinsUK individuals (n = 682). The identified G × BMI regulatory effects demonstrate the dynamic nature of gene regulation and reveal a functional mechanism underlying the heterogeneous response to obesity. Additionally, we have provided a web browser allowing interactive exploration of the dataset, including of association between expression, BMI, and G × BMI regulatory effects in four tissues.
肥胖是一种全球性的流行病,在人群层面上与一系列疾病存在因果关联,包括2型糖尿病和心血管疾病。然而,个体之间与肥胖相关的结果存在显著异质性。这可能反映了对肥胖的基因型依赖性反应。鉴于通过体重指数(BMI)衡量的肥胖与基因表达的广泛变化相关,且调控变异介导了大多数已知的复杂性状位点,我们试图在来自英国双胞胎队列(n = 856)的多组织RNA测序(RNA-seq)数据集中鉴定基因与BMI(G×BMI)对基因表达调控的相互作用。在错误发现率为5%的情况下,我们在脂肪组织中鉴定出16个顺式G×BMI相互作用(顶级顺式相互作用:CHURC1,rs7143432,p = 2.0×10⁻¹²)和一个反式调控53个基因的变异(顶级反式相互作用:ZNF423,rs3851570,p = 8.2×10⁻¹³)。这些相互作用具有脂肪组织特异性,且富集了与脂肪细胞增强子重叠的变异,受调控的基因在代谢和炎症过程中富集。我们在一个独立的脂肪RNA-seq数据集(deCODE遗传学,n = 754)中重复了部分相互作用。我们还在一部分英国双胞胎个体(n = 682)中,用另一种肥胖测量方法——双能X线吸收法(DXA)得出 visceral-fat-volume测量值,证实了这些相互作用。所鉴定的G×BMI调控效应证明了基因调控的动态性质,并揭示了对肥胖异质性反应的潜在功能机制。此外,我们提供了一个网络浏览器,允许交互式探索该数据集,包括四个组织中表达、BMI和G×BMI调控效应之间的关联。
