Lu-Chen Weng, Joel T. Rämö, Sean J. Jurgens, Shaan Khurshid, Mark Chaffin, Amelia Weber Hall, Valerie N. Morrill, Xin Wang, Victor Nauffal, Yan V. Sun, Dominik Beer, Simon Lee, Girish N. Nadkarni, ThuyVy Duong, Biqi Wang, Tomasz Czuba, Thomas R. Austin, Zachary T. Yoneda, Daniel J. Friedman, Anne Clayton, Matthew C. Hyman, Renae L. Judy, Allan C. Skanes, Kate M. Orland, Timothy M. Treu, Matthew T. Oetjens, Alvaro Alonso, Elsayed Z. Soliman, Honghuang Lin, Kathryn L. Lunetta, Jesper van der Pals, Tariq Z. Issa, Navid A. Nafissi, Heidi T. May, Peter Leong-Sit, Carolina Roselli, Seung Hoan Choi, FinnGen, Million Veteran Program, Regeneron Genetics Center, Habib R. Khan, Stacey Knight, Richard Karlsson Linnér, Connie R. Bezzina, Samuli Ripatti, Susan R. Heckbert, J. Michael Gaziano, Ruth J. F. Loos, Bruce M. Psaty, J. Gustav Smith, Emelia J. Benjamin, Dan E. Arking, Daniel J. Rader, Svati H. Shah, Dan M. Roden, Scott M. Damrauer, Lee L. Eckhardt, Jason D. Roberts, Michael J. Cutler, M. Benjamin Shoemaker, Christopher M. Haggerty, Kelly Cho, Aarno Palotie, Peter W. F. Wilson, Patrick T. Ellinor, Steven A. Lubitz
{"title":"常见和罕见基因变异对慢性心律失常发展的影响","authors":"Lu-Chen Weng, Joel T. Rämö, Sean J. Jurgens, Shaan Khurshid, Mark Chaffin, Amelia Weber Hall, Valerie N. Morrill, Xin Wang, Victor Nauffal, Yan V. Sun, Dominik Beer, Simon Lee, Girish N. Nadkarni, ThuyVy Duong, Biqi Wang, Tomasz Czuba, Thomas R. Austin, Zachary T. Yoneda, Daniel J. Friedman, Anne Clayton, Matthew C. Hyman, Renae L. Judy, Allan C. Skanes, Kate M. Orland, Timothy M. Treu, Matthew T. Oetjens, Alvaro Alonso, Elsayed Z. Soliman, Honghuang Lin, Kathryn L. Lunetta, Jesper van der Pals, Tariq Z. Issa, Navid A. Nafissi, Heidi T. May, Peter Leong-Sit, Carolina Roselli, Seung Hoan Choi, FinnGen, Million Veteran Program, Regeneron Genetics Center, Habib R. Khan, Stacey Knight, Richard Karlsson Linnér, Connie R. Bezzina, Samuli Ripatti, Susan R. Heckbert, J. Michael Gaziano, Ruth J. F. Loos, Bruce M. Psaty, J. Gustav Smith, Emelia J. Benjamin, Dan E. Arking, Daniel J. Rader, Svati H. Shah, Dan M. Roden, Scott M. Damrauer, Lee L. Eckhardt, Jason D. Roberts, Michael J. Cutler, M. Benjamin Shoemaker, Christopher M. Haggerty, Kelly Cho, Aarno Palotie, Peter W. F. Wilson, Patrick T. Ellinor, Steven A. Lubitz","doi":"10.1038/s41588-024-01978-2","DOIUrl":null,"url":null,"abstract":"To broaden our understanding of bradyarrhythmias and conduction disease, we performed common variant genome-wide association analyses in up to 1.3 million individuals and rare variant burden testing in 460,000 individuals for sinus node dysfunction (SND), distal conduction disease (DCD) and pacemaker (PM) implantation. We identified 13, 31 and 21 common variant loci for SND, DCD and PM, respectively. Four well-known loci (SCN5A/SCN10A, CCDC141, TBX20 and CAMK2D) were shared for SND and DCD, while others were more specific for SND or DCD. SND and DCD showed a moderate genetic correlation (rg = 0.63). Cardiomyocyte-expressed genes were enriched for contributions to DCD heritability. Rare-variant analyses implicated LMNA for all bradyarrhythmia phenotypes, SMAD6 and SCN5A for DCD and TTN, MYBPC3 and SCN5A for PM. These results show that variation in multiple genetic pathways (for example, ion channel function, cardiac developmental programs, sarcomeric structure and cellular homeostasis) appear critical to the development of bradyarrhythmias. Genome-wide analyses identify variants associated with sinus node dysfunction, distal conduction disease and pacemaker implantation, implicating ion channel function, cardiac developmental programs and sarcomeric structure in bradyarrhythmia susceptibility.","PeriodicalId":18985,"journal":{"name":"Nature genetics","volume":"57 1","pages":"53-64"},"PeriodicalIF":31.7000,"publicationDate":"2025-01-02","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.nature.com/articles/s41588-024-01978-2.pdf","citationCount":"0","resultStr":"{\"title\":\"The impact of common and rare genetic variants on bradyarrhythmia development\",\"authors\":\"Lu-Chen Weng, Joel T. Rämö, Sean J. Jurgens, Shaan Khurshid, Mark Chaffin, Amelia Weber Hall, Valerie N. Morrill, Xin Wang, Victor Nauffal, Yan V. Sun, Dominik Beer, Simon Lee, Girish N. Nadkarni, ThuyVy Duong, Biqi Wang, Tomasz Czuba, Thomas R. Austin, Zachary T. Yoneda, Daniel J. Friedman, Anne Clayton, Matthew C. Hyman, Renae L. Judy, Allan C. Skanes, Kate M. Orland, Timothy M. Treu, Matthew T. Oetjens, Alvaro Alonso, Elsayed Z. Soliman, Honghuang Lin, Kathryn L. Lunetta, Jesper van der Pals, Tariq Z. Issa, Navid A. Nafissi, Heidi T. May, Peter Leong-Sit, Carolina Roselli, Seung Hoan Choi, FinnGen, Million Veteran Program, Regeneron Genetics Center, Habib R. Khan, Stacey Knight, Richard Karlsson Linnér, Connie R. Bezzina, Samuli Ripatti, Susan R. Heckbert, J. Michael Gaziano, Ruth J. F. Loos, Bruce M. Psaty, J. Gustav Smith, Emelia J. Benjamin, Dan E. Arking, Daniel J. Rader, Svati H. Shah, Dan M. Roden, Scott M. Damrauer, Lee L. Eckhardt, Jason D. Roberts, Michael J. Cutler, M. Benjamin Shoemaker, Christopher M. Haggerty, Kelly Cho, Aarno Palotie, Peter W. F. Wilson, Patrick T. Ellinor, Steven A. Lubitz\",\"doi\":\"10.1038/s41588-024-01978-2\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"To broaden our understanding of bradyarrhythmias and conduction disease, we performed common variant genome-wide association analyses in up to 1.3 million individuals and rare variant burden testing in 460,000 individuals for sinus node dysfunction (SND), distal conduction disease (DCD) and pacemaker (PM) implantation. We identified 13, 31 and 21 common variant loci for SND, DCD and PM, respectively. Four well-known loci (SCN5A/SCN10A, CCDC141, TBX20 and CAMK2D) were shared for SND and DCD, while others were more specific for SND or DCD. SND and DCD showed a moderate genetic correlation (rg = 0.63). Cardiomyocyte-expressed genes were enriched for contributions to DCD heritability. Rare-variant analyses implicated LMNA for all bradyarrhythmia phenotypes, SMAD6 and SCN5A for DCD and TTN, MYBPC3 and SCN5A for PM. These results show that variation in multiple genetic pathways (for example, ion channel function, cardiac developmental programs, sarcomeric structure and cellular homeostasis) appear critical to the development of bradyarrhythmias. 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The impact of common and rare genetic variants on bradyarrhythmia development
To broaden our understanding of bradyarrhythmias and conduction disease, we performed common variant genome-wide association analyses in up to 1.3 million individuals and rare variant burden testing in 460,000 individuals for sinus node dysfunction (SND), distal conduction disease (DCD) and pacemaker (PM) implantation. We identified 13, 31 and 21 common variant loci for SND, DCD and PM, respectively. Four well-known loci (SCN5A/SCN10A, CCDC141, TBX20 and CAMK2D) were shared for SND and DCD, while others were more specific for SND or DCD. SND and DCD showed a moderate genetic correlation (rg = 0.63). Cardiomyocyte-expressed genes were enriched for contributions to DCD heritability. Rare-variant analyses implicated LMNA for all bradyarrhythmia phenotypes, SMAD6 and SCN5A for DCD and TTN, MYBPC3 and SCN5A for PM. These results show that variation in multiple genetic pathways (for example, ion channel function, cardiac developmental programs, sarcomeric structure and cellular homeostasis) appear critical to the development of bradyarrhythmias. Genome-wide analyses identify variants associated with sinus node dysfunction, distal conduction disease and pacemaker implantation, implicating ion channel function, cardiac developmental programs and sarcomeric structure in bradyarrhythmia susceptibility.
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Nature Genetics publishes the very highest quality research in genetics. It encompasses genetic and functional genomic studies on human and plant traits and on other model organisms. Current emphasis is on the genetic basis for common and complex diseases and on the functional mechanism, architecture and evolution of gene networks, studied by experimental perturbation.
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