Your search keyword '"Zachary T, Yoneda"' showing total 3 results

1. Arrhythmia variant associations and reclassifications in the eMERGE-III sequencing study

Author

Gail P. Jarvik, Carlos G. Vanoye, Reshma R. Desai, Lauren Lee Rinke, Hakon Hakonarson, Eric B. Larson, Ozan Dikilitas, Christian M. Shaffer, Zachary T. Yoneda, Ning Shang, George Hripcsak, Teri A. Manolio, Giovanni Davogustto, Bahram Namjou, Tooraj Mirshahi, Patrick Sleiman, Ayesha Muhammad, Elizabeth M. McNally, Olivia R. Kalash, Quinn S. Wells, Kathleen A. Leppig, Jonathan D. Mosley, Driest Slv, Jonathan Z. Luo, Daniel J. Schaid, Yuko Wada, Shoemaker Mb, Tao Yang, Wei-Qi Wei, Brett M. Kroncke, James D. Ralston, Sarah Bland, David Carrell, J. Glessner, Devyn Mitchell, Jennifer A. Pacheco, Cong Liu, Wendy K. Chung, Dan M. Roden, Chunhua Weng, Iftikhar J. Kullo, Tarek Alsaied, Sunghwan Sohn, Josh C. Denny, Adam S. Gordon, Rajbir Singh, Ashutosh Singhal, Alfred L. George, Eric Farber-Eger, and Andrew M. Glazer

Subjects

Long QT syndrome, Bioinformatics, Article, Genomic Medicine, Likely benign, Physiology (medical), medicine, Humans, Genetic Predisposition to Disease, Genetic Testing, Prospective Studies, Functional studies, Uncertain significance, Gene, Likely pathogenic, Disease gene, business.industry, Arrhythmias, Cardiac, Genomics, medicine.disease, Phenotype, Death, Sudden, Cardiac, HEK293 Cells, Cardiology and Cardiovascular Medicine, business

Abstract

Background: Sequencing Mendelian arrhythmia genes in individuals without an indication for arrhythmia genetic testing can identify carriers of pathogenic or likely pathogenic (P/LP) variants. However, the extent to which these variants are associated with clinically meaningful phenotypes before or after return of variant results is unclear. In addition, the majority of discovered variants are currently classified as variants of uncertain significance, limiting clinical actionability. Methods: The eMERGE-III study (Electronic Medical Records and Genomics Phase III) is a multicenter prospective cohort that included 21 846 participants without previous indication for cardiac genetic testing. Participants were sequenced for 109 Mendelian disease genes, including 10 linked to arrhythmia syndromes. Variant carriers were assessed with electronic health record–derived phenotypes and follow-up clinical examination. Selected variants of uncertain significance (n=50) were characterized in vitro with automated electrophysiology experiments in HEK293 cells. Results: As previously reported, 3.0% of participants had P/LP variants in the 109 genes. Herein, we report 120 participants (0.6%) with P/LP arrhythmia variants. Compared with noncarriers, arrhythmia P/LP carriers had a significantly higher burden of arrhythmia phenotypes in their electronic health records. Fifty-four participants had variant results returned. Nineteen of these 54 participants had inherited arrhythmia syndrome diagnoses (primarily long-QT syndrome), and 12 of these 19 diagnoses were made only after variant results were returned (0.05%). After in vitro functional evaluation of 50 variants of uncertain significance, we reclassified 11 variants: 3 to likely benign and 8 to P/LP. Conclusions: Genome sequencing in a large population without indication for arrhythmia genetic testing identified phenotype-positive carriers of variants in congenital arrhythmia syndrome disease genes. As the genomes of large numbers of people are sequenced, the disease risk from rare variants in arrhythmia genes can be assessed by integrating genomic screening, electronic health record phenotypes, and in vitro functional studies. Registration: URL: https://www.clinicaltrials.gov ; Unique identifier; NCT03394859.

Published

2021

2. Bidirectional Mendelian randomization supports bidirectional causality between telomere length and clonal hematopoiesis of intermediate potential

Author

Dan M. Roden, John Blangero, Myriam Fornage, Kerri L. Wiggins, Benjamin L. Ebert, Gina M. Peloso, Tetsushi Nakao, John Lane, Russell P. Tracy, Lisa de las Fuentes, Ryan L. Minster, Donna K. Arnett, Seyedeh M. Zekavat, Laura M. Raffield, Akhil Pampana, Stephen S. Rich, Kathleen C. Barnes, R. Mathias, Alyna T. Khan, Lewis C. Becker, James E. Hixson, Gabriel K. Griffin, Nicholas L. Smith, JoAnn E. Manson, Robert C. Kaplan, Gonçalo R. Abecasis, Nathan Pankratz, Alexander P. Reiner, Donald M. Lloyd-Jones, Sharon L.R. Kardia, C. Charles Gu, Wendy Post, Lisa R. Yanek, Tanika N. Kelly, Hemant K. Tiwari, Jennifer A. Smith, Shoa L. Clarke, Ramachandran S. Vasan, Themistocles L. Assimes, Betty S. Pace, Jill M. Johnsen, Cara L. Carty, Pinkal Desai, Barry I. Freedman, Pradeep Natarajan, Margaret A. Taub, S Redline, Adrienne M. Stilp, Ranjan Deka, Alexander G. Bick, Donald W. Bowden, Mariza de Andrade, Abhishek Niroula, Joanne E. Curran, Quenna Wong, Siddhartha Jaiswal, Chii-Min Hwu, Michael Preuss, Christie M. Ballantyne, Shannon Kelly, Patrick T. Ellinor, Sameer Chavan, Dandi Qiao, Nicola L. Hawley, Charles Kooperberg, Juan M. Peralta, Braxton D. Mitchell, Solomon K. Musani, Jerome I. Rotter, Ruth J.F. Loos, Zachary T. Yoneda, Bruce M. Psaty, Christopher J. Gibson, Ron Do, Barbara A. Konkle, Marguerite R. Irvin, Jai G. Broome, Take Naseri, Alanna C. Morrison, L. Adrienne Cupples, Bertha A. Hildalgo, Jiang He, Mesbah Uddin, Dawood Darbar, Cecelia A. Laurie, Eric A. Whitsel, Patricia A. Peyser, Brian Custer, Michael H. Cho, Scott T. Weiss, Peter Libby, Susan R. Heckbert, Albert V. Smith, Joshua S. Weinstock, Meher Preethi Boorgula, M. Benjamin Shoemaker, Muagututi’a S. Reupena, Michael C. Honigberg, Nicholette D. Palmer, Wei Zhao, Paul S. Vries, Edwin K. Silverman, Daniel E. Weeks, Romit Bhattacharya, Joshua C. Bis, Kari E. North, Thomas W. Blackwell, Dawn L. DeMeo, Stephen T. McGarvey, Leslie S. Emery, A. R. Shuldiner, Yii-Der Ida Chen, Eric Boerwinkle, Adolfo Correa, Deborah A. Meyers, and Eimear E. Kenny

Subjects

Mendelian randomization, Locus (genetics), Telomerase reverse transcriptase, CAD, Computational biology, Biology, Causality, Germline, Telomere, Genetic association

Abstract

Human genetic studies support an inverse causal relationship between leukocyte telomere length (LTL) and coronary artery disease (CAD), but directionally mixed effects for LTL and diverse malignancies. Clonal hematopoiesis of indeterminate potential (CHIP), characterized by expansion of hematopoietic cells bearing leukemogenic mutations, predisposes both hematologic malignancy and CAD. TERT (which encodes telomerase reverse transcriptase) is the most significantly associated germline locus for CHIP in genome-wide association studies. Here, we investigated the relationship between CHIP, LTL, and CAD in Trans-Omics for Precision Medicine (TOPMed) program (N=63,302) and UK Biobank (N=48,658). Bidirectional Mendelian randomization studies were consistent with LTL lengthening increasing propensity to develop CHIP, but CHIP then in turn hastening LTL shortening. We also demonstrated evidence of modest mediation between CHIP and CAD by LTL. Our data promote an understanding of potential causal relationships across CHIP and LTL toward prevention of CAD.

Published

2021

3. Rare Non-coding Variation Identified by Large Scale Whole Genome Sequencing Reveals Unexplained Heritability of Type 2 Diabetes

Author

Heming Wang, Lu-Chen Weng, Ryan W. Kim, May E. Montasser, Stephen T. McGarvey, Anubha Mahajan, Robert Sladek, Marcio Almeida, Dan M. Roden, Deepti Jain, Barry I. Freedman, Jeffrey R. O'Connell, Donna K. Arnett, Alanna C. Morrison, Susan R. Heckbert, Nicholette D. Palmer, Jie Yao, Jorge Ferrer, Timothy D. Majarian, Wei Zhao, JoAnn E. Manson, Mark I. McCarthy, Sharon L.R. Kardia, James A. Perry, Nicholas L. Smith, Alain G. Bertoni, James G. Wilson, Mark O. Goodarzi, Leslie A. Lange, Donald W. Bowden, L. Adrienne Cupples, Laura J. Rasmussen-Torvik, Yii-Der Ida Chen, Jennifer A. Smith, James S. Floyd, Sílvia Bonàs-Guarch, Zachary T. Yoneda, Rita R. Kalyani, Won Jung Choi, Ramachandran S. Vasan, Eric Boerwinkle, Ching-Ti Liu, Stephen C. J. Parker, Susan Redline, Paul S. de Vries, Huichun Xu, Daniel DiCorpo, Adolfo Correa, James S. Pankow, Stephen S. Rich, Heather M. Highland, Ravindranath Duggirala, Elizabeth Selvin, Kent D. Taylor, Dawood Darbar, Tanika N. Kelly, Bruce M. Psaty, Simin Liu, Xianyong Yin, Michael H. Cho, Abigail S. Baldridge, Alexander P. Reiner, Patricia A. Peyser, Seung Hoan Choi, Brian E. Cade, Chloé Sarnowski, Aladdin H. Shadyab, Gregory L Kinney, Daniel E. Weeks, Braxton D. Mitchell, Alisa K. Manning, Douglas Loesch, Steven A. Lubitz, Josée Dupuis, Ryan Irvin, Samantha Lent, Sridharan Raghavan, Bertha Hidalgo, Arushi Varshney, Ricardo D’Oliveira Albanus, Xiuqing Guo, Jennifer Wessel, Rasika A. Mathias, Jennifer A. Brody, Aaron Leong, John Blangero, James B. Meigs, Chung-Shiuan Chen, Lawrence F. Bielak, Lisa R. Yanek, Stella Aslibekyan, Rami Nassir, Karine A. Viaud-Martinez, Natalie R Hasbani, Irene Miguel-Escalada, Alvaro Alonso, Charles Kooperberg, Juan M. Peralta, Jose C. Florez, M. Benjamin Shoemaker, Seonwook Lee, Peitao Wu, Jerome I. Rotter, Jiang He, Patrick T. Ellinor, Mindy D. Szeto, and Joanne E. Curran

Subjects

Whole genome sequencing, Genetics, Minor allele frequency, medicine, Type 2 diabetes, Biology, Heritability, medicine.disease, Scale (music)

Abstract

Type 2 diabetes is increasing in all ancestry groups1. Part of its genetic basis may reside among the rare (minor allele frequency 2. We analyzed high-coverage (mean depth 38.2x) whole genome sequencing from 9,639 individuals with T2D and 34,994 controls in the NHLBI’s Trans-Omics for Precision Medicine (TOPMed) program2 to show that rare, non-coding variants that are poorly captured by genotyping arrays or imputation panels contribute h2=53% (P=4.2×10−5) to the genetic component of risk in the largest (European) ancestry subset. We coupled sequence variation with islet epigenomic signatures3 to annotate and group rare variants with respect to gene expression4, chromatin state5 and three-dimensional chromatin architecture6, and show that pancreatic islet regulatory elements contribute to T2D genetic risk (h2=8%, P=2.4×10−3). We used islet annotation to create a non-coding framework for rare variant aggregation testing. This approach identified five loci containing rare alleles in islet regulatory elements that suggest novel biological mechanisms readily linked to hypotheses about variant-to-function. Large scale whole genome sequence analysis reveals the substantial contribution of rare, non-coding variation to the genetic architecture of T2D and highlights the value of tissue-specific regulatory annotation for variant-to-function discovery.

Published

2020