Literature DB >> 31844321

Loss of ADAMTS19 causes progressive non-syndromic heart valve disease.

Florian Wünnemann1,2, Asaf Ta-Shma3,4, Gregor Andelfinger5,6,7, Christoph Preuss8, Severine Leclerc1, Patrick Piet van Vliet1,9,10, Andrea Oneglia1, Maryse Thibeault1, Emily Nordquist11,12, Joy Lincoln12,13, Franka Scharfenberg14, Christoph Becker-Pauly14, Philipp Hofmann15, Kirstin Hoff15,16, Enrique Audain15,16, Hans-Heiner Kramer15,16, Wojciech Makalowski2, Amiram Nir3, Sebastian S Gerety17, Matthew Hurles17, Johanna Comes1, Anne Fournier18, Hanna Osinska19, Jeffrey Robins19, Michel Pucéat9,10,20, Orly Elpeleg4, Marc-Phillip Hitz15,16,17,21.   

Abstract

Valvular heart disease is observed in approximately 2% of the general population1. Although the initial observation is often localized (for example, to the aortic or mitral valve), disease manifestations are regularly observed in the other valves and patients frequently require surgery. Despite the high frequency of heart valve disease, only a handful of genes have so far been identified as the monogenic causes of disease2-7. Here we identify two consanguineous families, each with two affected family members presenting with progressive heart valve disease early in life. Whole-exome sequencing revealed homozygous, truncating nonsense alleles in ADAMTS19 in all four affected individuals. Homozygous knockout mice for Adamts19 show aortic valve dysfunction, recapitulating aspects of the human phenotype. Expression analysis using a lacZ reporter and single-cell RNA sequencing highlight Adamts19 as a novel marker for valvular interstitial cells; inference of gene regulatory networks in valvular interstitial cells positions Adamts19 in a highly discriminatory network driven by the transcription factor lymphoid enhancer-binding factor 1 downstream of the Wnt signaling pathway. Upregulation of endocardial Krüppel-like factor 2 in Adamts19 knockout mice precedes hemodynamic perturbation, showing that a tight balance in the Wnt-Adamts19-Klf2 axis is required for proper valve maturation and maintenance.

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Year:  2019        PMID: 31844321      PMCID: PMC7197892          DOI: 10.1038/s41588-019-0536-2

Source DB:  PubMed          Journal:  Nat Genet        ISSN: 1061-4036            Impact factor:   38.330


  54 in total

1.  Rare non-synonymous variations in the transcriptional activation domains of GATA5 in bicuspid aortic valve disease.

Authors:  Ratnasari Padang; Richard D Bagnall; David R Richmond; Paul G Bannon; Christopher Semsarian
Journal:  J Mol Cell Cardiol       Date:  2012-05-26       Impact factor: 5.000

2.  A syndrome of altered cardiovascular, craniofacial, neurocognitive and skeletal development caused by mutations in TGFBR1 or TGFBR2.

Authors:  Bart L Loeys; Junji Chen; Enid R Neptune; Daniel P Judge; Megan Podowski; Tammy Holm; Jennifer Meyers; Carmen C Leitch; Nicholas Katsanis; Neda Sharifi; F Lauren Xu; Loretha A Myers; Philip J Spevak; Duke E Cameron; Julie De Backer; Jan Hellemans; Yan Chen; Elaine C Davis; Catherine L Webb; Wolfram Kress; Paul Coucke; Daniel B Rifkin; Anne M De Paepe; Harry C Dietz
Journal:  Nat Genet       Date:  2005-01-30       Impact factor: 38.330

3.  Marfan syndrome caused by a recurrent de novo missense mutation in the fibrillin gene.

Authors:  H C Dietz; G R Cutting; R E Pyeritz; C L Maslen; L Y Sakai; G M Corson; E G Puffenberger; A Hamosh; E J Nanthakumar; S M Curristin
Journal:  Nature       Date:  1991-07-25       Impact factor: 49.962

4.  Congenital valvular defects associated with deleterious mutations in the PLD1 gene.

Authors:  Asaf Ta-Shma; Kai Zhang; Ekaterina Salimova; Alma Zernecke; Daniel Sieiro-Mosti; David Stegner; Milena Furtado; Avraham Shaag; Zeev Perles; Bernhard Nieswandt; Azaria J J T Rein; Nadia Rosenthal; Aaron M Neiman; Orly Elpeleg
Journal:  J Med Genet       Date:  2016-10-31       Impact factor: 6.318

5.  Burden of valvular heart diseases: a population-based study.

Authors:  Vuyisile T Nkomo; Julius M Gardin; Thomas N Skelton; John S Gottdiener; Christopher G Scott; Maurice Enriquez-Sarano
Journal:  Lancet       Date:  2006-09-16       Impact factor: 79.321

6.  Mutations in NOTCH1 cause aortic valve disease.

Authors:  Vidu Garg; Alecia N Muth; Joshua F Ransom; Marie K Schluterman; Robert Barnes; Isabelle N King; Paul D Grossfeld; Deepak Srivastava
Journal:  Nature       Date:  2005-07-17       Impact factor: 49.962

7.  The spectrum of cardiac anomalies in Noonan syndrome as a result of mutations in the PTPN11 gene.

Authors:  Yves Sznajer; Boris Keren; Clarisse Baumann; Sabrina Pereira; Corinne Alberti; Jacques Elion; Hélène Cavé; Alain Verloes
Journal:  Pediatrics       Date:  2007-05-21       Impact factor: 7.124

8.  Nonsynonymous variants in the SMAD6 gene predispose to congenital cardiovascular malformation.

Authors:  Huay L Tan; Elise Glen; Ana Töpf; Darroch Hall; John J O'Sullivan; Linda Sneddon; Christopher Wren; Peter Avery; Richard J Lewis; Peter ten Dijke; Helen M Arthur; Judith A Goodship; Bernard D Keavney
Journal:  Hum Mutat       Date:  2012-02-14       Impact factor: 4.878

9.  Mutations in DCHS1 cause mitral valve prolapse.

Authors:  Ronen Durst; Kimberly Sauls; David S Peal; Annemarieke deVlaming; Katelynn Toomer; Maire Leyne; Monica Salani; Michael E Talkowski; Harrison Brand; Maëlle Perrocheau; Charles Simpson; Christopher Jett; Matthew R Stone; Florie Charles; Colby Chiang; Stacey N Lynch; Nabila Bouatia-Naji; Francesca N Delling; Lisa A Freed; Christophe Tribouilloy; Thierry Le Tourneau; Hervé LeMarec; Leticia Fernandez-Friera; Jorge Solis; Daniel Trujillano; Stephan Ossowski; Xavier Estivill; Christian Dina; Patrick Bruneval; Adrian Chester; Jean-Jacques Schott; Kenneth D Irvine; Yaopan Mao; Andy Wessels; Tahirali Motiwala; Michel Puceat; Yoshikazu Tsukasaki; Donald R Menick; Harinath Kasiganesan; Xingju Nie; Ann-Marie Broome; Katherine Williams; Amanda Johnson; Roger R Markwald; Xavier Jeunemaitre; Albert Hagege; Robert A Levine; David J Milan; Russell A Norris; Susan A Slaugenhaupt
Journal:  Nature       Date:  2015-08-10       Impact factor: 49.962

10.  ROBO4 variants predispose individuals to bicuspid aortic valve and thoracic aortic aneurysm.

Authors:  Russell A Gould; Hamza Aziz; Courtney E Woods; Manuel Alejandro Seman-Senderos; Elizabeth Sparks; Christoph Preuss; Florian Wünnemann; Djahida Bedja; Cassandra R Moats; Sarah A McClymont; Rebecca Rose; Nara Sobreira; Hua Ling; Gretchen MacCarrick; Ajay Anand Kumar; Ilse Luyckx; Elyssa Cannaerts; Aline Verstraeten; Hanna M Björk; Ann-Cathrin Lehsau; Vinod Jaskula-Ranga; Henrik Lauridsen; Asad A Shah; Christopher L Bennett; Patrick T Ellinor; Honghuang Lin; Eric M Isselbacher; Christian Lacks Lino Cardenas; Jonathan T Butcher; G Chad Hughes; Mark E Lindsay; Luc Mertens; Anders Franco-Cereceda; Judith M A Verhagen; Marja Wessels; Salah A Mohamed; Per Eriksson; Seema Mital; Lut Van Laer; Bart L Loeys; Gregor Andelfinger; Andrew S McCallion; Harry C Dietz
Journal:  Nat Genet       Date:  2018-11-19       Impact factor: 38.330
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  16 in total

Review 1.  Genetics in bicuspid aortic valve disease: Where are we?

Authors:  Katia Bravo-Jaimes; Siddharth K Prakash
Journal:  Prog Cardiovasc Dis       Date:  2020-06-27       Impact factor: 8.194

Review 2.  Mechanisms of heart valve development and disease.

Authors:  Anna O'Donnell; Katherine E Yutzey
Journal:  Development       Date:  2020-07-03       Impact factor: 6.868

3.  ADAM and ADAMTS disintegrin and metalloproteinases as major factors and molecular targets in vascular malfunction and disease.

Authors:  HaiFeng Yang; Raouf A Khalil
Journal:  Adv Pharmacol       Date:  2022-01-24

4.  ADAMTS proteases in cardiovascular physiology and disease.

Authors:  Salvatore Santamaria; Rens de Groot
Journal:  Open Biol       Date:  2020-12-23       Impact factor: 6.411

Review 5.  Insights on the Pathogenesis of Aneurysm through the Study of Hereditary Aortopathies.

Authors:  Tyler J Creamer; Emily E Bramel; Elena Gallo MacFarlane
Journal:  Genes (Basel)       Date:  2021-01-27       Impact factor: 4.096

Review 6.  Single-cell RNA Sequencing: In-depth Decoding of Heart Biology and Cardiovascular Diseases.

Authors:  Zhongli Chen; Liang Wei; Firat Duru; Liang Chen
Journal:  Curr Genomics       Date:  2020-12       Impact factor: 2.236

Review 7.  Regulation of ADAMTS Proteases.

Authors:  Keron W J Rose; Nandaraj Taye; Stylianos Z Karoulias; Dirk Hubmacher
Journal:  Front Mol Biosci       Date:  2021-06-29

Review 8.  The ADAMTS/Fibrillin Connection: Insights into the Biological Functions of ADAMTS10 and ADAMTS17 and Their Respective Sister Proteases.

Authors:  Stylianos Z Karoulias; Nandaraj Taye; Sarah Stanley; Dirk Hubmacher
Journal:  Biomolecules       Date:  2020-04-12

9.  Genomic Landscape and Mutational Spectrum of ADAMTS Family Genes in Mendelian Disorders Based on Gene Evidence Review for Variant Interpretation.

Authors:  John Hoon Rim; Yo Jun Choi; Heon Yung Gee
Journal:  Biomolecules       Date:  2020-03-13

Review 10.  The quest for substrates and binding partners: A critical barrier for understanding the role of ADAMTS proteases in musculoskeletal development and disease.

Authors:  Brandon Satz-Jacobowitz; Dirk Hubmacher
Journal:  Dev Dyn       Date:  2020-09-17       Impact factor: 3.780
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