Your search keyword '"Erdos, Michael"' showing total 17 results

1. Single-cell transcriptomic profiling of human pancreatic islets reveals genes responsive to glucose exposure over 24 h

Author

Grenko, Caleb M., Taylor, Henry J., Bonnycastle, Lori L., Xue, Dongxiang, Lee, Brian N., Weiss, Zoe, Yan, Tingfen, Swift, Amy J., Mansell, Erin C., Lee, Angela, Robertson, Catherine C., Narisu, Narisu, Erdos, Michael R., Chen, Shuibing, Collins, Francis S., and Taylor, D. Leland

Published

2024

2. Modeling islet enhancers using deep learning identifies candidate causal variants at loci associated with T2D and glycemic traits.

Author

Hudaiberdiev, Sanjarbek, Taylor, D. Leland, Wei Song, Narisu, Narisu, Bhuiyan, Redwan M., Taylor, Henry J., Xuming Tang, Tingfen Yan, Swift, Amy J., Bonnycastle, Lori L., Shuibing Chen, Stitzel, Michael L., Erdos, Michael R., Ovcharenko, Ivan, and Collins, Francis S.

Subjects

DEEP learning, PANCREATIC beta cells, ISLANDS, ISLANDS of Langerhans, TYPE 2 diabetes

Abstract

Genetic association studies have identified hundreds of independent signals associated with type 2 diabetes (T2D) and related traits. Despite these successes, the identification of specific causal variants underlying a genetic association signal remains challenging. In this study, we describe a deep learning (DL) method to analyze the impact of sequence variants on enhancers. Focusing on pancreatic islets, a T2D relevant tissue, we show that our model learns islet-specific transcription factor (TF) regulatory patterns and can be used to prioritize candidate causal variants. At 101 genetic signals associated with T2D and related glycemic traits where multiple variants occur in linkage disequilibrium, our method nominates a single causal variant for each association signal, including three variants previously shown to alter reporter activity in islet-relevant cell types. For another signal associated with blood glucose levels, we biochemically test all candidate causal variants from statistical fine-mapping using a pancreatic islet beta cell line and show biochemical evidence of allelic effects on TF binding for the model-prioritized variant. To aid in future research, we publicly distribute our model and islet enhancer perturbation scores across ~67 million genetic variants. We anticipate that DL methods like the one presented in this study will enhance the prioritization of candidate causal variants for functional studies. [ABSTRACT FROM AUTHOR]

Published

2023

3. A Transcription Start Site Map in Human Pancreatic Islets Reveals Functional Regulatory Signatures.

Author

Varshney, Arushi, Kyono, Yasuhiro, Elangovan, Venkateswaran Ramamoorthi, Wang, Collin, Erdos, Michael R., Narisu, Narisu, Albanus, Ricardo D'Oliveira, Orchard, Peter, Stitzel, Michael L., Collins, Francis S., Kitzman, Jacob O., and Parker, Stephen C.J.

Subjects

ISLANDS of Langerhans, GENOME-wide association studies, FALSE discovery rate, TYPE 2 diabetes, TRANSGENIC organisms, RESEARCH, SEQUENCE analysis, GENETICS, RESEARCH methodology, GENETIC polymorphisms, MEDICAL cooperation, EVALUATION research, COMPARATIVE studies, GENES, RESEARCH funding

Abstract

Identifying the tissue-specific molecular signatures of active regulatory elements is critical to understand gene regulatory mechanisms. Here, we identify transcription start sites (TSS) using cap analysis of gene expression (CAGE) across 57 human pancreatic islet samples. We identify 9,954 reproducible CAGE tag clusters (TCs), ∼20% of which are islet specific and occur mostly distal to known gene TSS. We integrated islet CAGE data with histone modification and chromatin accessibility profiles to identify epigenomic signatures of transcription initiation. Using a massively parallel reporter assay, we validated the transcriptional enhancer activity for 2,279 of 3,378 (∼68%) tested islet CAGE elements (5% false discovery rate). TCs within accessible enhancers show higher enrichment to overlap type 2 diabetes genome-wide association study (GWAS) signals than existing islet annotations, which emphasizes the utility of mapping CAGE profiles in disease-relevant tissue. This work provides a high-resolution map of transcriptional initiation in human pancreatic islets with utility for dissecting active enhancers at GWAS loci. [ABSTRACT FROM AUTHOR]

Published

2021

4. Single-cell ATAC-Seq in human pancreatic islets and deep learning upscaling of rare cells reveals cell-specific type 2 diabetes regulatory signatures.

Author

Rai, Vivek, Quang, Daniel X., Erdos, Michael R., Cusanovich, Darren A., Daza, Riza M., Narisu, Narisu, Zou, Luli S., Didion, John P., Guan, Yuanfang, Shendure, Jay, Parker, Stephen C.J., and Collins, Francis S.

Abstract

Type 2 diabetes (T2D) is a complex disease characterized by pancreatic islet dysfunction, insulin resistance, and disruption of blood glucose levels. Genome-wide association studies (GWAS) have identified > 400 independent signals that encode genetic predisposition. More than 90% of associated single-nucleotide polymorphisms (SNPs) localize to non-coding regions and are enriched in chromatin-defined islet enhancer elements, indicating a strong transcriptional regulatory component to disease susceptibility. Pancreatic islets are a mixture of cell types that express distinct hormonal programs, so each cell type may contribute differentially to the underlying regulatory processes that modulate T2D-associated transcriptional circuits. Existing chromatin profiling methods such as ATAC-seq and DNase-seq, applied to islets in bulk, produce aggregate profiles that mask important cellular and regulatory heterogeneity. We present genome-wide single-cell chromatin accessibility profiles in >1,600 cells derived from a human pancreatic islet sample using single-cell combinatorial indexing ATAC-seq (sci-ATAC-seq). We also developed a deep learning model based on U-Net architecture to accurately predict open chromatin peak calls in rare cell populations. We show that sci-ATAC-seq profiles allow us to deconvolve alpha, beta, and delta cell populations and identify cell-type-specific regulatory signatures underlying T2D. Particularly, T2D GWAS SNPs are significantly enriched in beta cell-specific and across cell-type shared islet open chromatin, but not in alpha or delta cell-specific open chromatin. We also demonstrate, using less abundant delta cells, that deep learning models can improve signal recovery and feature reconstruction of rarer cell populations. Finally, we use co-accessibility measures to nominate the cell-specific target genes at 104 non-coding T2D GWAS signals. Collectively, we identify the islet cell type of action across genetic signals of T2D predisposition and provide higher-resolution mechanistic insights into genetically encoded risk pathways. • Single cell chromatin accessibility profiles obtained for 1,456 human pancreatic islet cells. • Unique α, β, and δ cell chromatin accessibility signatures identified. • Deep learning approach accurately predicts chromatin accessibility in rare cells. • Nominate effector cell types, causal variants and target genes at diabetes GWAS loci. [ABSTRACT FROM AUTHOR]

Published

2020

5. Interactions between genetic variation and cellular environment in skeletal muscle gene expression.

Author

Taylor, D. Leland, Knowles, David A., Scott, Laura J., Ramirez, Andrea H., Casale, Francesco Paolo, Wolford, Brooke N., Guan, Li, Varshney, Arushi, Albanus, Ricardo D’Oliveira, Parker, Stephen C. J., Narisu, Narisu, Chines, Peter S., Erdos, Michael R., Welch, Ryan P., Kinnunen, Leena, Saramies, Jouko, Sundvall, Jouko, Lakka, Timo A., Laakso, Markku, and Tuomilehto, Jaakko

Subjects

HUMAN genetic variation, SKELETAL muscle, GENE expression, RNA sequencing, PHENOTYPES, GENETICS

Abstract

From whole organisms to individual cells, responses to environmental conditions are influenced by genetic makeup, where the effect of genetic variation on a trait depends on the environmental context. RNA-sequencing quantifies gene expression as a molecular trait, and is capable of capturing both genetic and environmental effects. In this study, we explore opportunities of using allele-specific expression (ASE) to discover cis-acting genotype-environment interactions (GxE)—genetic effects on gene expression that depend on an environmental condition. Treating 17 common, clinical traits as approximations of the cellular environment of 267 skeletal muscle biopsies, we identify 10 candidate environmental response expression quantitative trait loci (reQTLs) across 6 traits (12 unique gene-environment trait pairs; 10% FDR per trait) including sex, systolic blood pressure, and low-density lipoprotein cholesterol. Although using ASE is in principle a promising approach to detect GxE effects, replication of such signals can be challenging as validation requires harmonization of environmental traits across cohorts and a sufficient sampling of heterozygotes for a transcribed SNP. Comprehensive discovery and replication will require large human transcriptome datasets, or the integration of multiple transcribed SNPs, coupled with standardized clinical phenotyping. [ABSTRACT FROM AUTHOR]

Published

2018

6. A Type 2 Diabetes-Associated Functional Regulatory Variant in a Pancreatic Islet Enhancer at the Locus.

Author

Roman, Tamara S., Cannon, Maren E., Vadlamudi, Swarooparani, Buchkovich, Martin L., Wolford, Brooke N., Welch, Ryan P., Morken, Mario A., Kwon, Grace J., Varshney, Arushi, Kursawe, Romy, Ying Wu, Jackson, Anne U., Erdos, Michael R., Kuusisto, Johanna, Laakso, Markku, Scott, Laura J., Boehnke, Michael, Collins, Francis S., Parker, Stephen C. J., and Stitzel, Michael L.

Subjects

TYPE 2 diabetes, GLUCOSE analysis, ISLANDS of Langerhans, NUCLEAR proteins, CARRIER proteins, GENES, GENETICS, INSULIN, RESEARCH funding, SEQUENCE analysis

Abstract

Molecular mechanisms remain unknown for most type 2 diabetes genome-wide association study identified loci. Variants associated with type 2 diabetes and fasting glucose levels reside in introns of ADCY5, a gene that encodes adenylate cyclase 5. Adenylate cyclase 5 catalyzes the production of cyclic AMP, which is a second messenger molecule involved in cell signaling and pancreatic β-cell insulin secretion. We demonstrated that type 2 diabetes risk alleles are associated with decreased ADCY5 expression in human islets and examined candidate variants for regulatory function. rs11708067 overlaps a predicted enhancer region in pancreatic islets. The type 2 diabetes risk rs11708067-A allele showed fewer H3K27ac ChIP-seq reads in human islets, lower transcriptional activity in reporter assays in rodent β-cells (rat 832/13 and mouse MIN6), and increased nuclear protein binding compared with the rs11708067-G allele. Homozygous deletion of the orthologous enhancer region in 832/13 cells resulted in a 64% reduction in expression level of Adcy5, but not adjacent gene Sec22a, and a 39% reduction in insulin secretion. Together, these data suggest that rs11708067-A risk allele contributes to type 2 diabetes by disrupting an islet enhancer, which results in reduced ADCY5 expression and impaired insulin secretion. [ABSTRACT FROM AUTHOR]

Published

2017

7. Global Epigenomic Analysis of Primary Human Pancreatic Islets Provides Insights into Type 2 Diabetes Susceptibility Loci.

Author

Stitzel, Michael L., Sethupathy, Praveen, Pearson, Daniel S., Chines, Peter S., Song, Lingyun, Erdos, Michael R., Welch, Ryan, Parker, Stephen C.J., Boyle, Alan P., Scott, Laura J., Margulies, Elliott H., Boehnke, Michael, Furey, Terrence S., Crawford, Gregory E., and Collins, Francis S.

Subjects

EPIGENESIS, ISLANDS of Langerhans, TYPE 2 diabetes, DISEASE susceptibility, GENE expression, PATHOLOGICAL physiology, GENETIC code

Abstract

Summary: Identifying cis-regulatory elements is important to understanding how human pancreatic islets modulate gene expression in physiologic or pathophysiologic (e.g., diabetic) conditions. We conducted genome-wide analysis of DNase I hypersensitive sites, histone H3 lysine methylation modifications (K4me1, K4me3, K79me2), and CCCTC factor (CTCF) binding in human islets. This identified ∼18,000 putative promoters (several hundred unannotated and islet-active). Surprisingly, active promoter modifications were absent at genes encoding islet-specific hormones, suggesting a distinct regulatory mechanism. Of 34,039 distal (nonpromoter) regulatory elements, 47% are islet unique and 22% are CTCF bound. In the 18 type 2 diabetes (T2D)-associated loci, we identified 118 putative regulatory elements and confirmed enhancer activity for 12 of 33 tested. Among six regulatory elements harboring T2D-associated variants, two exhibit significant allele-specific differences in activity. These findings present a global snapshot of the human islet epigenome and should provide functional context for noncoding variants emerging from genetic studies of T2D and other islet disorders. [ABSTRACT FROM AUTHOR]

Published

2010

8. Variants in MTNR1B influence fasting glucose levels.

Author

Prokopenko, Inga, Langenberg, Claudia, Florez, Jose C., Saxena, Richa, Soranzo, Nicole, Thorleifsson, Gudmar, Loos, Ruth J. F., Manning, Alisa K., Jackson, Anne U., Aulchenko, Yurii, Potter, Simon C., Erdos, Michael R., Sanna, Serena, Hottenga, Jouke-Jan, Wheeler, Eleanor, Kaakinen, Marika, Lyssenko, Valeriya, Chen, Wei-Min, Ahmadi, Kourosh, and Beckmann, Jacques S.

Subjects

GLUCOSE, GENOMES, MELATONIN, HOMEOSTASIS, TYPE 2 diabetes, PANCREATIC beta cells, META-analysis

Abstract

To identify previously unknown genetic loci associated with fasting glucose concentrations, we examined the leading association signals in ten genome-wide association scans involving a total of 36,610 individuals of European descent. Variants in the gene encoding melatonin receptor 1B (MTNR1B) were consistently associated with fasting glucose across all ten studies. The strongest signal was observed at rs10830963, where each G allele (frequency 0.30 in HapMap CEU) was associated with an increase of 0.07 (95% CI = 0.06–0.08) mmol/l in fasting glucose levels (P = 3.2 × 10−50) and reduced beta-cell function as measured by homeostasis model assessment (HOMA-B, P = 1.1 × 10−15). The same allele was associated with an increased risk of type 2 diabetes (odds ratio = 1.09 (1.05–1.12), per G allele P = 3.3 × 10−7) in a meta-analysis of 13 case-control studies totaling 18,236 cases and 64,453 controls. Our analyses also confirm previous associations of fasting glucose with variants at the G6PC2 (rs560887, P = 1.1 × 10−57) and GCK (rs4607517, P = 1.0 × 10−25) loci. [ABSTRACT FROM AUTHOR]

Published

2009

9. Screening of 134 Single Nucleotide Polymorphisms (SNPs) Previously Associated With Type 2 Diabetes Replicates Association With 12 SNPs in Nine Genes.

Author

Willer, Cristen J., Bonnycastle, Lori L., Conneely, Karen N., Duren, William L., Jackson, Anne U., Scott, Laura J., Narisu, Narisu, Chines, Peter S., Skol, Andrew, Stringham, Heather M., Petrie, John, Erdos, Michael R., Swift, Amy J., Enloe, Sareena T., Sprau, Andrew G., Smith, Eboni, Tong, Maurine, Doheny, Kimberly F., Pugh, Elizabeth W., and Watanabe, Richard M.

Subjects

TYPE 2 diabetes, GENETIC polymorphisms, GLUCOSE, GENES, LITERATURE reviews

Abstract

More than 120 published reports have described associations between single nucleotide polymorphisms (SNPs) and type 2 diabetes. However, multiple studies of the same variant have often been discordant. From a literature search, we identified previously reported type 2 diabetes-associated SNPs. We initially genotyped 134 SNPs on 786 index case subjects from type 2 diabetes families and 617 control subjects with normal glucose tolerance from Finland and excluded from analysis 20 SNPs in strong linkage disequilibrium (r2 > 0.8) with another typed SNP. Of the 114 SNPs examined, we followed up the 20 most significant SNPs (P < 0.10) on an additional 384 case subjects and 366 control subjects from a population-based study in Finland. In the combined data, we replicated association (P < 0.05) for 12 SNPs: PPARG Pro12Ala and His447, KCNJ11 Glu23Lys and rs5210, TNF -857, SLC2A2 Ile110Thr, HNFIA/TCF1 rs2701175 and GEl17881_360, PCK1 -232, NEUROD1 Thr45Ala, IL6 -598, and ENPP1 Lys121Gln. The replication of 12 SNPs of 114 tested was significantly greater than expected by chance under the null hypothesis of no association (P = 0.012). We observed that SNPs from genes that had three or more previous reports of association were significantly more likely to be replicated in our sample (P -- 0.03), although we also replicated 4 of 58 SNPs from genes that had only one previous report of association. Diabetes 56:256-264, 2007 [ABSTRACT FROM AUTHOR]

Published

2007

10. Association of Transcription Factor 7-Like 2 (TCF7L2) Variants With Type 2 Diabetes in a Finnish Sample.

Author

Scott, Laura J., Bonnycastle, Lori L., Willer, Cristen J., Sprau, Andrew G., Jackson, Anne U., Narisu, Narisu, Duren, William L., Chines, Peter S., Stringham, Heather M., Erdos, Michael R., Valle, Timo T., Tuomilehto, Jaakko, Bergman, Richard N., Mohlke, Karen L., Collins, Francis S., and Boehnke, Michael

Subjects

TYPE 2 diabetes, DIABETES, GENETICS, ENDOCRINE diseases, TRANSCRIPTION factors

Abstract

Transcription factor 7-like 2 (TCF7L2) is part of the Wnt signaling pathway. Genetic variants within TCF7L2 on chromosome 10q were recently reported to be associated with type 2 diabetes in Icelandic, Danish, and American (U.S.) samples. We previously observed a modest logarithm of odds score of 0.61 on chromosome 10q, ∼1 Mb from TCF7L2, in the Finland-United States Investigation of NIDDM Genetics study. We tested the five associated TCF7L2 single nucleotide polymorphism (SNP) variants in a Finnish sample of 1,151 type 2 diabetic patients and 953 control subjects. We confirmed the association with the same risk allele (P value <0.05) for all five SNPs. Our strongest results were for rs12255372 (odds ratio [OR] 1.36 [95% CI 1.15-1.61], P = 0.00026) and rs7903146 (1.33 [1.14-1.56], P = 0.00042). Based on the CEU HapMap data, we selected and tested 12 additional SNPs to tag SNPs in linkage disequilibrium with rs12255372. None of these SNPs showed stronger evidence of association than rs12255372 or rs7903146 (OR ≤1.26, P ≥ 0.0054). Our results strengthen the evidence that one or more variants in TCF7L2 are associated with increased risk of type 2 diabetes. Diabetes 55:2649-2653, 2006 [ABSTRACT FROM AUTHOR]

Published

2006

11. Mitochondrial polymorphisms and susceptibility to type 2 diabetes-related traits in Finns.

Author

Mohlke, Karen L., Jackson, Anne U., Scott, Laura J., Peck, Erin C., Suh, Yong D., Chines, Peter S., Watanabe, Richard M., Buchanan, Thomas A., Conneely, Karen N., Erdos, Michael R., Narisu, Narisu, Enloe, Sareena, Valle, Timo T., Tuomilehto, Jaakko, Bergman, Richard N., Boehnke, Michael, and Collins, Francis S.

Subjects

TYPE 2 diabetes, DISEASE susceptibility, ADENOSINE triphosphate, GLUCOSE, GENETIC polymorphisms

Abstract

Mitochondria play an integral role in ATP production in cells and are involved in glucose metabolism and insulin secretion, suggesting that variants in the mitochondrial genome may contribute to diabetes susceptibility. In a study of Finnish families ascertained for type 2 diabetes mellitus (T2DM), we genotyped single nucleotide polymorphisms (SNPs) based on phylogenetic networks. These SNPs defined eight major haplogroups and subdivided groups H and U, which are common in Finns. We evaluated association with both diabetes disease status and up to 14 diabetes-related traits for 762 cases, 402 non-diabetic controls, and 465 offspring of genotyped females. Haplogroup J showed a trend toward association with T2DM affected status (OR 1.69, P=0.056) that became slightly more significant after excluding cases with affected fathers (OR 1.77, P=0.045). We also genotyped non-haplogroup-tagging SNPs previously reported to show evidence for association with diabetes or related traits. Our data support previous evidence for association of T16189C with reduced ponderal index at birth and also show evidence for association with reduced birthweight but not with diabetes status. Given the multiple tests performed and the significance levels obtained, this study suggests that mitochondrial genome variants may play at most a modest role in glucose metabolism in the Finnish population. Furthermore, our data do not support a reported maternal inheritance pattern of T2DM but instead show a strong effect of recall bias. [ABSTRACT FROM AUTHOR]

Published

2005

12. Genetic variation near the hepatocyte nuclear factor-4 alpha gene predicts susceptibility to type 2 diabetes.

Author

Silander, Kaisa, Mohlke, Karen L., Scott, Laura J., Peck, Erin C., Hollstein, Pablo, Skol, Andrew D., Jackson, Anne U., Deloukas, Panagiotis, Hunt, Sarah, Stavrides, George, Chines, Peter S., Erdos, Michael R., Narisu, Narisu, Conneely, Karen N., Li, Chun, Fingerlin, Tasha E., Dhanjal, Sharanjeet K., Valle, Timo T., Bergman, Richard N., and Tuomilehto, Jaakko

Subjects

TYPE 2 diabetes, ENDOCRINE diseases, DIABETES, GENETICS, LIVER cells

Abstract

The Finland-United States Investigation Of NIDDM Genetics (FUSION) study aims to identify genetic variants that predispose to type 2 diabetes by studying affected sibling pair families from Finland. Chromosome 20 showed our strongest initial evidence for linkage. It currently has a maximum logarithm of odds (LOD) score of 2.48 at 70 cM in a set of 495 families. In this study, we searched for diabetes susceptibility variant(s) at 20q13 by genotyping single nucleotide polymorphism (SNP) markers in case and control DNA pools. Of 291 SNPs successfully typed in a 7.5-Mb interval, the strongest association confirmed by individual genotyping was with SNP rs2144908, located 1.3 kb downstream of the primary β-cell promoter P2 of hepatocyte nuclear factor-4α (HNF4A). This SNP showed association with diabetes disease status (odds ratio [OR] 1.33, 95% CI 1.06-1.65, P = 0.011) and with several diabetes-related traits. Most of the evidence for linkage at 20q13 could be attributed to the families carrying the risk allele. We subsequently found nine additional associated SNPs spanning a 64-kb region, including the P2 and P1 promoters and exons 1-3. Our results and the independent observation of association of SNPs near the P2 promoter with diabetes in a separate study population of Ashkenazi Jewish origin suggests that variant(s) located near or within HNF4A increases susceptibility to type 2 diabetes. [ABSTRACT FROM AUTHOR]

Published

2004

13. The peroxisome proliferator-activated receptor-gamma2 Pro12A1a variant: association with type 2 diabetes and trait differences.

Author

Douglas, Julie A., Erdos, Michael R., Watanabe, Richard M., Braun, Andi, Johnston, Cristy L., Oeth, Paul, Mohlke, Karen L., Valle, Timo T., Ehnholm, Christian, Buchanan, Thomas A., Bergman, Richard N., Collins, Francis S., Boehnke, Michael, Douglas, J A, Erdos, M R, Watanabe, R M, Braun, A, Johnston, C L, Oeth, P, and Mohlke, K L

Subjects

*TYPE 2 diabetes, *NUCLEAR receptors (Biochemistry), *INSULIN

Abstract

Recent studies have identified a common proline-to-alanine substitution (Pro12Ala) in the peroxisome proliferator-activated receptor-gamma2 (PPAR-gamma2), a nuclear receptor that regulates adipocyte differentiation and possibly insulin sensitivity. The Pro12Ala variant has been associated in some studies with diabetes-related traits and/or protection against type 2 diabetes. We examined this variant in 935 Finnish subjects, including 522 subjects with type 2 diabetes, 193 nondiabetic spouses, and 220 elderly nondiabetic control subjects. The frequency of the Pro12Ala variant was significantly lower in diabetic subjects than in nondiabetic subjects (0.15 vs. 0.21; P = 0.001). We also compared diabetes-related traits between subjects with and without the Pro12Ala variant within subgroups. Among diabetic subjects, the variant was associated with greater weight gain after age 20 years (P = 0.023) and lower triglyceride levels (P = 0.033). Diastolic blood pressure was higher in grossly obese (BMI >40 kg/m2) diabetic subjects with the variant. In nondiabetic spouses, the variant was associated with higher fasting insulin (P = 0.033), systolic blood pressure (P = 0.021), and diastolic blood pressure (P = 0.045). These findings support a role for the PPAR-gamma2 Pro12Ala variant in the etiology of type 2 diabetes and the insulin resistance syndrome. [ABSTRACT FROM AUTHOR]

Published

2001

14. Genome-Wide Association Scan Meta-Analysis Identifies Three Loci Influencing Adiposity and Fat Distribution

Author

Lindgren, Cecilia M., Heid, Iris M., Randall, Joshua C., Lamina, Claudia, Steinthorsdottir, Valgerdur, Speliotes, Elizabeth K., Thorleifsson, Gudmar, Willer, Cristen J., Herrera, Blanca M., Jackson, Anne U., Lim, Noha, Scheet, Paul, Soranzo, Nicole, Amin, Najaf, Aulchenko, Yurii S., Chambers, John C., Drong, Alexander, Luan, Jian'an, Rivadeneira, Fernando, Sanna, Serena, Timpson, Nicholas J., Zillikens, M. Carola, Almgren, Peter, Bandinelli, Stefania, Bennett, Amanda J., Bergman, Richard N., Bonnycastle, Lori L., Bumpstead, Suzannah J., Chanock, Stephen J., Cherkas, Lynn, Chines, Peter, Coin, Lachlan, Cooper, Cyrus, Crawford, Gabriel, Doering, Angela, Dominiczak, Anna, Doney, Alex S. F., Ebrahim, Shah, Elliott, Paul, Erdos, Michael R., Estrada, Karol, Ferrucci, Luigi, Fischer, Guido, Forouhi, Nita G., Gieger, Christian, Grallert, Harald, Groves, Christopher J., Grundy, Scott, Guiducci, Candace, Hadley, David, Hamsten, Anders, Havulinna, Aki S., Holle, Rolf, Holloway, John W., Illig, Thomas, Isomaa, Bo, Jacobs, Leonie C., Jameson, Karen, Jousilahti, Pekka, Karpe, Fredrik, Kuusisto, Johanna, Laitinen, Jaana, Lathrop, G. Mark, Lawlor, Debbie A., Mangino, Massimo, McArdle, Wendy L., Meitinger, Thomas, Morken, Mario A., Morris, Andrew P., Munroe, Patricia, Narisu, Narisu, Nordström, Anna, Nordström, Peter, Oostra, Ben A., Palmer, Colin N. A., Payne, Felicity, Peden, John F., Prokopenko, Inga, Renström, Frida, Ruokonen, Aimo, Salomaa, Veikko, Sandhu, Manjinder S., Scuteri, Angelo, Silander, Kaisa, Song, Kijoung, Stringham, Heather M., Swift, Amy J., Tuomi, Tiinamaija, Uda, Manuela, Vollenweider, Peter, Waeber, Gerard, Wallace, Chris, Walters, G. Bragi, Weedon, Michael N., Witteman, Jacqueline C. M., Zhang, Cuilin, Zhang, Weihua, Caulfield, Mark J., Collins, Francis S., Davey Smith, George, Day, Ian N. M., Franks, Paul W., Hattersley, Andrew T., Jarvelin, Marjo-Riitta, Kong, Augustine, Kooner, Jaspal S., Laakso, Markku, Lakatta, Edward, Mooser, Vincent, Morris, Andrew D., Peltonen, Leena, Samani, Nilesh J., Spector, Timothy D., Strachan, David P., Tanaka, Toshiko, Tuomilehto, Jaakko, Uitterlinden, André G., van Duijn, Cornelia M., Wareham, Nicholas J., Waterworth, Dawn M., Boehnke, Michael, Deloukas, Panos, Groop, Leif, Thorsteinsdottir, Unnur, Schlessinger, David, Wichmann, H.-Erich, Frayling, Timothy M., Abecasis, Gonçalo R., Loos, Ruth J. F., Stefansson, Kari, Mohlke, Karen L., Barroso, Inês, Hirschhorn, Joel Naom, McCarthy, Mark I., Watkins, Hugh, The Wellcome Trust Case Control Consortium, Hunter, David J., Hu, Frank B., Yuan, Xin, Scott, Laura J., Hofman, Albert, Zhao, Jing Hua, Lyon, Helen N, and Qi, Lu

Subjects

diabetes and endocrinology, obesity, type 2 diabetes, complex traits, genetics and genomics

Abstract

To identify genetic loci influencing central obesity and fat distribution, we performed a meta-analysis of 16 genome-wide association studies (GWAS, N = 38,580) informative for adult waist circumference (WC) and waist–hip ratio (WHR). We selected 26 SNPs for follow-up, for which the evidence of association with measures of central adiposity (WC and/or WHR) was strong and disproportionate to that for overall adiposity or height. Follow-up studies in a maximum of 70,689 individuals identified two loci strongly associated with measures of central adiposity; these map near TFAP2B (WC, P = 1.9×\(10^{-11}\)) and MSRA (WC, P = 8.9×\(10^{-9}\)). A third locus, near LYPLAL1, was associated with WHR in women only (P = 2.6×\(10^{-8}\)). The variants near TFAP2B appear to influence central adiposity through an effect on overall obesity/fat-mass, whereas LYPLAL1 displays a strong female-only association with fat distribution. By focusing on anthropometric measures of central obesity and fat distribution, we have identified three loci implicated in the regulation of human adiposity.

Published

2009

15. Genetic variant effects on gene expression in human pancreatic islets and their implications for T2D.

Author

Viñuela, Ana, Varshney, Arushi, van de Bunt, Martijn, Prasad, Rashmi B., Asplund, Olof, Bennett, Amanda, Boehnke, Michael, Brown, Andrew A., Erdos, Michael R., Fadista, João, Hansson, Ola, Hatem, Gad, Howald, Cédric, Iyengar, Apoorva K., Johnson, Paul, Krus, Ulrika, MacDonald, Patrick E., Mahajan, Anubha, Manning Fox, Jocelyn E., and Narisu, Narisu

Subjects

GENE expression, ISLANDS of Langerhans, HUMAN genes, TYPE 2 diabetes

Abstract

Most signals detected by genome-wide association studies map to non-coding sequence and their tissue-specific effects influence transcriptional regulation. However, key tissues and cell-types required for functional inference are absent from large-scale resources. Here we explore the relationship between genetic variants influencing predisposition to type 2 diabetes (T2D) and related glycemic traits, and human pancreatic islet transcription using data from 420 donors. We find: (a) 7741 cis-eQTLs in islets with a replication rate across 44 GTEx tissues between 40% and 73%; (b) marked overlap between islet cis-eQTL signals and active regulatory sequences in islets, with reduced eQTL effect size observed in the stretch enhancers most strongly implicated in GWAS signal location; (c) enrichment of islet cis-eQTL signals with T2D risk variants identified in genome-wide association studies; and (d) colocalization between 47 islet cis-eQTLs and variants influencing T2D or glycemic traits, including DGKB and TCF7L2. Our findings illustrate the advantages of performing functional and regulatory studies in disease relevant tissues. Mechanistic inference following GWAS is hampered by the lack of tissue-specific transcriptomic resources. Here the authors combine genetic variants predisposing to type 2 diabetes with human pancreatic islet RNA-seq data. They identify 7741 islet expression quantitative trait loci (eQTLs), providing a resource for functional interpretation of association signals mapping to non-coding sequence. [ABSTRACT FROM AUTHOR]

Published

2020

16. Multiomic Profiling Identifies cis-Regulatory Networks Underlying Human Pancreatic β Cell Identity and Function.

Author

Lawlor, Nathan, Márquez, Eladio J., Orchard, Peter, Narisu, Narisu, Shamim, Muhammad Saad, Thibodeau, Asa, Varshney, Arushi, Kursawe, Romy, Erdos, Michael R., Kanke, Matt, Gu, Huiya, Pak, Evgenia, Dutra, Amalia, Russell, Sheikh, Li, Xingwang, Piecuch, Emaly, Luo, Oscar, Chines, Peter S., Fuchbserger, Christian, and Sethupathy, Praveen

Abstract

Summary EndoC-βH1 is emerging as a critical human β cell model to study the genetic and environmental etiologies of β cell (dys)function and diabetes. Comprehensive knowledge of its molecular landscape is lacking, yet required, for effective use of this model. Here, we report chromosomal (spectral karyotyping), genetic (genotyping), epigenomic (ChIP-seq and ATAC-seq), chromatin interaction (Hi-C and Pol2 ChIA-PET), and transcriptomic (RNA-seq and miRNA-seq) maps of EndoC-βH1. Analyses of these maps define known (e.g., PDX1 and ISL1) and putative (e.g., PCSK1 and mir-375) β cell-specific transcriptional cis -regulatory networks and identify allelic effects on cis- regulatory element use. Importantly, comparison with maps generated in primary human islets and/or β cells indicates preservation of chromatin looping but also highlights chromosomal aberrations and fetal genomic signatures in EndoC-βH1. Together, these maps, and a web application we created for their exploration, provide important tools for the design of experiments to probe and manipulate the genetic programs governing β cell identity and (dys)function in diabetes. Graphical Abstract Highlights • Comprehensive multiomic maps of EndoC-βH1 human β cell line and primary islets • Sequence motifs enriched in EndoC-specific enhancers reflect its precursor state • Identification of regulatory hubs preserved between EndoC-βH1 and human islets • Identified SNP alleles (including T2D GWAS) altering cis -regulatory signatures EndoC-βH1 is becoming an important cellular model to study genes and pathways governing human β cell identity and function, but its (epi)genomic similarity to primary human islets is unknown. Lawlor et al. complete and compare extensive EndoC and primary human islet multiomic maps to identify shared and distinct genomic circuitry. [ABSTRACT FROM AUTHOR]

Published

2019

17. A Genome-Wide Association Study of Type 2 Diabetes in Finns Detects Multiple Susceptibility Variants.

Author

Scott, Laura J., Mohlke, Karen L., Bonnycastle, Lori L., Willer, Cristen J., Yun Li, Duren, William L., Erdos, Michael R., Stringham, Heather M., Chines, Peter S., Jackson, Anne U., Prokunina-Olsson, Ludmila, Chia-Jen Ding, Swift, Amy J., Narisu, Narisu, Tianle Hu, Pruim, Randall, Rui Xiao, Xiao-Yi Li, Conneely, Karen N., and Riebow, Nancy L.

Subjects

*TYPE 2 diabetes, *DIABETES, *GENETIC polymorphisms, *GENES, *HUMAN genetic variation, *CHROMOSOMES, *GENOMICS, *BIOTECHNOLOGY research

Abstract

Identifying the genetic variants that increase the risk of type 2 diabetes (T2D) in humans has been a formidable challenge. Adopting a genome-wide association strategy, we genotyped 1161 Finnish 120 cases and 1174 Finnish normal glucose-tolerant (NGT) controls with >315,000 single-nucleotide polymorphisms (SNPs) and imputed genotypes for an additional >2 million autosomal SNPs. We carried out association analysis with these SNPs to identify genetic variants that predispose to T2D, compared our T2D association results with the results of two similar studies, and genotyped 80 SNPs in an additional 1215 Finnish T2D cases and 1258 Finnish NGT controls. We identify T2D-associated variants in an intergenic region of chromosome 11p12, contribute to the identification of T2D-associated variants near the genes IGF2BP2 and CDKAL1 and the region of CDKN2A and CDKN2B, and confirm that variants near TCF7L2, SLC30A8, HHEX, FTO, PPARG, and KCNJ11 are associated with T2D risk. This brings the number of T2D loci now confidently identified to at least 10. [ABSTRACT FROM AUTHOR]

Published

2007