An Expanded Genome-Wide Association Study of Type 2 Diabetes in Europeans

Scott, Robert A.; Scott, Laura J.; Mägi, Reedik; Marullo, Letizia; Gaulton, Kyle J.; Kaakinen, Marika; Pervjakova, Natalia; Pers, Tune H.; Johnson, Andrew D.; Eicher, John D.; Jackson, Anne; Ferreira, Teresa; Lee, Yeji; Ma, Clement; Steinthórsdóttir, Valgerður; Þorleifsson, Guðmar; Qi, Lü; Zuydam, Natalie R. van; Mahajan, Anubha; Chen, Han; Almgren, Peter; Voight, Ben; Grallert, Harald; Müller‐Nurasyid, Martina; Ried, Janina S.; Rayner, Nigel W.; Robertson, Neil; Karssen, Lennart C.; Leeuwen, Elisabeth M. van; Willems, Sara M.; Fuchsberger, Christian; Kwan, Phoenix; Teslovich, Tanya M.; Chanda, Pritam; Li, Man; Lu, Yingchang; Dina, Christian; Thuillier, Dorothée; Yengo, Loïc; Jiang, Longda; Sparsø, Thomas; Kestler, Hans A.; Chheda, Himanshu; Eisele, Lewin; Gustafsson, Stefan; Frånberg, Mattias; Strawbridge, Rona J.; Benediktsson, Rafn; Hreiðarsson, Ástráður B.; Kong, Augustine; Sigurðsson, Gunnar; Kerrison, Nicola D.; Luan, Jian’an; Liang, Liming; Meitinger, Thomas; Roden, Michael; Thorand, Barbara; Esko, Tõnu; Mihailov, Evelin; Fox, Caroline S.; Liu, Ching‐Ti; Rybin, Denis; Isomaa, Bo; Lyssenko, Valeriya; Tuomi, Tiinamaija; Couper, David J.; Pankow, James S.; Grarup, Niels; Have, Christian Theil; Jørgensen, Marit E.; Jørgensen, Torben; Linneberg, Allan; Cornelis, Marilyn C.; Dam, Rob M. van; Hunter, David J.; Kraft, Peter; Sun, Qi; Edkins, Sarah; Owen, Katharine R.; Perry, John R. B.; Wood, Andrew R.; Zeggini, Eleftheria; Tajes-Fernandes, Juan; Abecasis, Gonçalo R.; Bonnycastle, Lori L.; Chines, Peter S.; Stringham, Heather M.; Koistinen, Heikki A.; Kinnunen, Leena; Sennblad, Bengt; Mühleisen, Thomas W.; Nöthen, Markus M.; Pechlivanis, Sonali; Baldassarre, Damiano; Gertow, Karl; Humphries, Steve E.; Tremoli, Elena; Klopp, Norman; Meyer, Julia; Steinbach, Gerald; Wennauer, Roman; Eriksson, Johan G.; Männistö, Satu; Peltonen, Leena; Tikkanen, Emmi; Charpentier, G.; Eury, Elodie; Lobbens, Stéphane; Gigante, Bruna; Leander, Karin; McLeod, Olga; Böttinger, Erwin P.; Gottesman, Omri; Ruderfer, Douglas M.; Blüher, Matthias; Kovacs, Peter; Tönjes, Anke; Maruthur, Nisa M.; Scapoli, Chiara; Erbel, Raimund; Jöckel, Karl‐Heinz; Moebus, Susanne; Fairé, Ulf dé; Hamsten, Anders; Stümvoll, Michael; Deloukas, Panos; Donnelly, Peter; Frayling, Timothy M.; Hattersley, Andrew T.; Ripatti, Samuli; Salomaa, Veikko; Pedersen, Nancy L.; Boehm, Bernhard O.; Bergman, Richard N.; Collins, Francis S.; Mohlke, Karen L.; Tuomilehto, Jaakko; Hansen, Torben; Pedersen, Oluf; Barroso, Inês; Lannfelt, Lars; Ingelsson, Erik; Lind, Lars; Lindgren, Cecilia M.; Cauchi, Stéphane; Froguel, Philippe; Loos, Ruth J.F.; Balkau, Beverley; Boeing, Heiner; Franks, Paul W.; Gurrea, Aurelio Barricarte; Palli, Domenico; Schouw, Yvonne T. van der; Altshuler, David; Groop, Leif; Langenberg, Claudia; Wareham, Nicholas J.; Sijbrands, Eric J.G.; Duijn, Cornelia M. van; Florez, José C.; Meigs, James B.; Boerwinkle, Eric; Gieger, Christian; Strauch, Konstantin; Metspalu, Andres; Morris, Andrew D.; Palmer, Colin N.A.; Hu, Frank B.; Þorsteinsdóttir, Unnur; Stefánsson, Kāri; Dupuis, Josée; Morris, Andrew P.; Boehnke, Michael; McCarthy, Mark I.; Prokopenko, Inga

doi:10.2337/db16-1253

Cited by 631 publications

(619 citation statements)

References 52 publications

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“…Credible intervals were defined by the boundaries of the 99% credible sets of variants [24] from DIAGRAM (96 loci) [25] and ENGAGE (16 loci) [26] consortium data, respectively (ESM Table 10). A subset of 15 loci was considered to influence type 2 diabetes via beta cell dysfunction; these loci included ones causing hyperglycaemia, reduced insulin processing and secretion, and reduced fasting proinsulin levels [27,28] (ESM Table 11, ESM Methods).…”

Section: Flow Cytometrymentioning

confidence: 99%

Patterns of differential gene expression in a cellular model of human islet development, and relationship to type 2 diabetes predisposition

et al. 2018

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Aims/hypothesis Most type 2 diabetes-associated genetic variants identified via genome-wide association studies (GWASs) appear to act via the pancreatic islet. Observed defects in insulin secretion could result from an impact of these variants on islet development and/or the function of mature islets. Most functional studies have focused on the latter, given limitations regarding access to human fetal islet tissue. Capitalising upon advances in in vitro differentiation, we characterised the transcriptomes of human induced pluripotent stem cell (iPSC) lines differentiated along the pancreatic endocrine lineage, and explored the contribution of altered islet development to the pathogenesis of type 2 diabetes. Methods We performed whole-transcriptome RNA sequencing of human iPSC lines from three independent donors, at baseline and at seven subsequent stages during in vitro islet differentiation. Differentially expressed genes (q < 0.01, log 2 fold change [FC] > 1) were assigned to the stages at which they were most markedly upregulated. We used these data to characterise upstream transcription factors directing different stages of development, and to explore the relationship between RNA expression profiles and genes mapping to type 2 diabetes GWAS signals.Results We identified 9409 differentially expressed genes across all stages, including many known markers of islet development. Integration of differential expression data with information on transcription factor motifs highlighted the potential contribution of REST to islet development. Over 70% of genes mapping within type 2 diabetes-associated credible intervals showed peak differential expression during islet development, and type 2 diabetes GWAS loci of largest effect (including TCF7L2; log 2 FC = 1.2; q = 8.5 × 10 −10 ) were notably enriched in genes differentially expressed at the posterior foregut stage (q = 0.002), as calculated by gene set enrichment analyses. In a complementary analysis of enrichment, genes differentially expressed in the final, beta-like cell stage of in vitro differentiation were significantly enriched (hypergeometric test, permuted p value <0.05) for genes within the credible intervals of type 2 diabetes GWAS loci. Conclusions/interpretation The present study characterises RNA expression profiles during human islet differentiation, identifies potential transcriptional regulators of the differentiation process, and suggests that the inherited predisposition to type 2 diabetes is partly mediated through modulation of islet development.Marta Perez-Alcantara and Christian Honoré contributed equally to this study.Electronic supplementary material The online version of this article (https://doi.org/10.1007/s00125-018-4612-4) contains peer-reviewed but unedited supplementary material, which is available to authorised users.

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Section: Flow Cytometrymentioning

confidence: 99%

Patterns of differential gene expression in a cellular model of human islet development, and relationship to type 2 diabetes predisposition

et al. 2018

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“…45 To date, well over 100 genetic loci have been identified in successive waves of GWAS metaanalyses as robustly associated with T2D and/or related traits. [46][47][48][49][50][51][52] Comprehensive sequencing studies that capture both common and rare variation suggest that most genetic variation influencing T2D appears to reside at common variant sites. 11 Although genetic risk variants at these loci have modest effects on disease predisposition (collectively accounting for 10-15% of overall disease risk), 11,50 the knowledge gained has paved the way to elucidate the molecular taxonomy of the disease and the potential identification of novel therapeutic approaches.…”

Section: Subclassification Of Type 2 Diabetesmentioning

confidence: 99%

Precision medicine in diabetes: an opportunity for clinical translation

Merino

Florez

2018

Annals of the New York Academy of Sciences

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Metabolic disorders present a public health challenge of staggering proportions. In diabetes, there is an urgent need to better understand disease heterogeneity, clinical trajectories, and related comorbidities. A pressing and timely question is whether we are ready for precision medicine in diabetes. Some biological insights that have emerged during the last decade have already been used to direct clinical decision making, especially in monogenic forms of diabetes. However, much work is necessary to integrate high-dimensional explorations into complex disease architectures, less penetrant biological alterations, and broader phenotypes, such as type 2 diabetes. In addition, for precision medicine to take hold in diabetes, reproducibility, interpretability, and actionability remain key guiding objectives. In this review, we examine how mounting data sets generated during the last decade to understand biological variability are now inspiring new venues to clarify diabetes nosology and ultimately translate findings into more effective prevention and treatment strategies.

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“…In contrast to candidate gene studies, GWAS offer an “hypothesis-free” approach and rapidly led to the discovery of dozens of new genetic loci associated with T2D [14••]. Including multi-ethnic populations in GWAS, meta-analyzing multiple GWAS to increase sample size, and performing imputation against reference sequences, all further expanded the number of loci to just over 100 [15•, 16, 17••, 18, 19]. The variants identified through GWAS thus far individually confer small increased risks of T2D (odds ratios generally less than 1.3) and, combined, they explain about an estimated 10–20% of the familial aggregation of the disease [15•, 17••, 20, 21].…”

Section: Genetic Discovery For T2d Riskmentioning

confidence: 99%

“…Increasing sample sizes of genetic association studies will likely enable discovery of hundreds of additional loci. While such additional loci are expected to have decreasing magnitudes of effect sizes [15•, 24••], in aggregate, they may still facilitate improved T2D risk prediction.…”

Section: Genetic Discovery For T2d Riskmentioning

confidence: 99%

A Decade of Genetic and Metabolomic Contributions to Type 2 Diabetes Risk Prediction

et al. 2017

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Purpose of Review The purpose of this review was to summarize and reflect on advances over the past decade in human genetic and metabolomic discovery with particular focus on their contributions to type 2 diabetes (T2D) risk prediction. Recent Findings In the past 10 years, a combination of advances in genotyping efficiency, metabolomic profiling, bio-informatics approaches, and international collaboration have moved T2D genetics and metabolomics from a state of frustration to an abundance of new knowledge. Summary Efforts to control and prevent T2D have failed to stop this global epidemic. New approaches are needed, and although neither genetic nor metabolomic profiling yet have a clear clinical role, the rapid pace of accumulating knowledge offers the possibility for “multi-omic” prediction to improve health.

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An Expanded Genome-Wide Association Study of Type 2 Diabetes in Europeans

Cited by 631 publications

References 52 publications

Patterns of differential gene expression in a cellular model of human islet development, and relationship to type 2 diabetes predisposition

Patterns of differential gene expression in a cellular model of human islet development, and relationship to type 2 diabetes predisposition

Precision medicine in diabetes: an opportunity for clinical translation

A Decade of Genetic and Metabolomic Contributions to Type 2 Diabetes Risk Prediction

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