Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 Elucidation of MRAS-mediated Noonan syndrome with cardiac hypertrophy.

Literature DB >> 28289718

Elucidation of MRAS-mediated Noonan syndrome with cardiac hypertrophy.

Erin M Higgins¹, J Martijn Bos^2,3, Heather Mason-Suares^4,5, David J Tester^2,6, Jaeger P Ackerman², Calum A MacRae^7,8,9,10, Katia Sol-Church¹¹, Karen W Gripp^11,12, Raul Urrutia^13,14, Michael J Ackerman^2,3,6.

Abstract

Noonan syndrome (NS; MIM 163950) is an autosomal dominant disorder and a member of a family of developmental disorders termed "RASopathies," which are caused mainly by gain-of-function mutations in genes encoding RAS/MAPK signaling pathway proteins. Whole exome sequencing (WES) and trio-based genomic triangulation of a 15-year-old female with a clinical diagnosis of NS and concomitant cardiac hypertrophy and her unaffected parents identified a de novo variant in MRAS-encoded RAS-related protein 3 as the cause of her disease. Mutation analysis using in silico mutation prediction tools and molecular dynamics simulations predicted the identified variant, p.Gly23Val-MRAS, to be damaging to normal protein function and adversely affect effector interaction regions and the GTP-binding site. Subsequent ectopic expression experiments revealed a 40-fold increase in MRAS activation for p.Gly23Val-MRAS compared with WT-MRAS. Additional biochemical assays demonstrated enhanced activation of both RAS/MAPK pathway signaling and downstream gene expression in cells expressing p.Gly23Val-MRAS. Mutational analysis of MRAS in a cohort of 109 unrelated patients with phenotype-positive/genotype-negative NS and cardiac hypertrophy yielded another patient with a sporadic de novo MRAS variant (p.Thr68Ile, c.203C>T). Herein, we describe the discovery of mutations in MRAS in patients with NS and cardiac hypertrophy, establishing MRAS as the newest NS with cardiac hypertrophy-susceptibility gene.

Entities: Chemical Disease Gene Mutation Species

Mesh：

Year: 2017 PMID： 28289718 PMCID： PMC5333962 DOI： 10.1172/jci.insight.91225

Source DB: PubMed Journal: JCI Insight ISSN： 2379-3708

65 in total

1. T-Coffee: A novel method for fast and accurate multiple sequence alignment.

Authors: C Notredame; D G Higgins; J Heringa
Journal: J Mol Biol Date: 2000-09-08 Impact factor: 5.469

Review 2. The extracellular signal-regulated kinase: multiple substrates regulate diverse cellular functions.

Authors: Seunghee Yoon; Rony Seger
Journal: Growth Factors Date: 2006-03 Impact factor: 2.511

3. Comprehensive statistical study of 452 BRCA1 missense substitutions with classification of eight recurrent substitutions as neutral.

Authors: S V Tavtigian; A M Deffenbaugh; L Yin; T Judkins; T Scholl; P B Samollow; D de Silva; A Zharkikh; A Thomas
Journal: J Med Genet Date: 2005-07-13 Impact factor: 6.318

4. Molecular and clinical analysis of RAF1 in Noonan syndrome and related disorders: dephosphorylation of serine 259 as the essential mechanism for mutant activation.

Authors: Tomoko Kobayashi; Yoko Aoki; Tetsuya Niihori; Hélène Cavé; Alain Verloes; Nobuhiko Okamoto; Hiroshi Kawame; Ikuma Fujiwara; Fumio Takada; Takako Ohata; Satoru Sakazume; Tatsuya Ando; Noriko Nakagawa; Pablo Lapunzina; Antonio G Meneses; Gabriele Gillessen-Kaesbach; Dagmar Wieczorek; Kenji Kurosawa; Seiji Mizuno; Hirofumi Ohashi; Albert David; Nicole Philip; Afag Guliyeva; Yoko Narumi; Shigeo Kure; Shigeru Tsuchiya; Yoichi Matsubara
Journal: Hum Mutat Date: 2010-03 Impact factor: 4.878

5. A novel rasopathy caused by recurrent de novo missense mutations in PPP1CB closely resembles Noonan syndrome with loose anagen hair.

Authors: Karen W Gripp; Kimberly A Aldinger; James T Bennett; Laura Baker; Jessica Tusi; Nina Powell-Hamilton; Deborah Stabley; Katia Sol-Church; Andrew E Timms; William B Dobyns
Journal: Am J Med Genet A Date: 2016-06-05 Impact factor: 2.802

6. Germline KRAS mutations cause Noonan syndrome.

Authors: Suzanne Schubbert; Martin Zenker; Sara L Rowe; Silke Böll; Cornelia Klein; Gideon Bollag; Ineke van der Burgt; Luciana Musante; Vera Kalscheuer; Lars-Erik Wehner; Hoa Nguyen; Brian West; Kam Y J Zhang; Erik Sistermans; Anita Rauch; Charlotte M Niemeyer; Kevin Shannon; Christian P Kratz
Journal: Nat Genet Date: 2006-02-12 Impact factor: 38.330

7. Costello syndrome associated with novel germline HRAS mutations: an attenuated phenotype?

Authors: Karen W Gripp; A Micheil Innes; Marni E Axelrad; Tanya L Gillan; Jillian S Parboosingh; Christine Davies; Norma J Leonard; Monique Lapointe; Daniel Doyle; Sarah Catalano; Linda Nicholson; Deborah L Stabley; Katia Sol-Church
Journal: Am J Med Genet A Date: 2008-03-15 Impact factor: 2.802

8. Genotype and phenotype in patients with Noonan syndrome and a RIT1 mutation.

Authors: Karim Kouz; Christina Lissewski; Stephanie Spranger; Diana Mitter; Angelika Riess; Vanesa Lopez-Gonzalez; Sabine Lüttgen; Hatip Aydin; Florian von Deimling; Christina Evers; Andreas Hahn; Maja Hempel; Ulrike Issa; Anne-Karin Kahlert; Adrian Lieb; Pablo Villavicencio-Lorini; Maria Juliana Ballesta-Martinez; Sheela Nampoothiri; Angela Ovens-Raeder; Alena Puchmajerová; Robin Satanovskij; Heide Seidel; Stephan Unkelbach; Bernhard Zabel; Kerstin Kutsche; Martin Zenker
Journal: Genet Med Date: 2016-04-21 Impact factor: 8.822

9. Expression Atlas update--an integrated database of gene and protein expression in humans, animals and plants.

Authors: Robert Petryszak; Maria Keays; Y Amy Tang; Nuno A Fonseca; Elisabet Barrera; Tony Burdett; Anja Füllgrabe; Alfonso Muñoz-Pomer Fuentes; Simon Jupp; Satu Koskinen; Oliver Mannion; Laura Huerta; Karine Megy; Catherine Snow; Eleanor Williams; Mitra Barzine; Emma Hastings; Hendrik Weisser; James Wright; Pankaj Jaiswal; Wolfgang Huber; Jyoti Choudhary; Helen E Parkinson; Alvis Brazma
Journal: Nucleic Acids Res Date: 2015-10-19 Impact factor: 16.971

10. Predicting the functional, molecular, and phenotypic consequences of amino acid substitutions using hidden Markov models.

Authors: Hashem A Shihab; Julian Gough; David N Cooper; Peter D Stenson; Gary L A Barker; Keith J Edwards; Ian N M Day; Tom R Gaunt
Journal: Hum Mutat Date: 2012-11-02 Impact factor: 4.878

27 in total

1. Germline-Activating RRAS2 Mutations Cause Noonan Syndrome.

Authors: Tetsuya Niihori; Koki Nagai; Atsushi Fujita; Hirofumi Ohashi; Nobuhiko Okamoto; Satoshi Okada; Atsuko Harada; Hirotaka Kihara; Thomas Arbogast; Ryo Funayama; Matsuyuki Shirota; Keiko Nakayama; Taiki Abe; Shin-Ichi Inoue; I-Chun Tsai; Naomichi Matsumoto; Erica E Davis; Nicholas Katsanis; Yoko Aoki
Journal: Am J Hum Genet Date: 2019-05-23 Impact factor: 11.025

2. Activating Mutations of RRAS2 Are a Rare Cause of Noonan Syndrome.

Authors: Yline Capri; Elisabetta Flex; Oliver H F Krumbach; Giovanna Carpentieri; Serena Cecchetti; Christina Lißewski; Soheila Rezaei Adariani; Denny Schanze; Julia Brinkmann; Juliette Piard; Francesca Pantaleoni; Francesca R Lepri; Elaine Suk-Ying Goh; Karen Chong; Elliot Stieglitz; Julia Meyer; Alma Kuechler; Nuria C Bramswig; Stephanie Sacharow; Marion Strullu; Yoann Vial; Cédric Vignal; George Kensah; Goran Cuturilo; Neda S Kazemein Jasemi; Radovan Dvorsky; Kristin G Monaghan; Lisa M Vincent; Hélène Cavé; Alain Verloes; Mohammad R Ahmadian; Marco Tartaglia; Martin Zenker
Journal: Am J Hum Genet Date: 2019-05-23 Impact factor: 11.025

Review 3. RAS Proteins and Their Regulators in Human Disease.

Authors: Dhirendra K Simanshu; Dwight V Nissley; Frank McCormick
Journal: Cell Date: 2017-06-29 Impact factor: 41.582

4. Synthetic Lethal Interaction of SHOC2 Depletion with MEK Inhibition in RAS-Driven Cancers.

Authors: Rita Sulahian; Jason J Kwon; Katherine H Walsh; Emma Pailler; Timothy L Bosse; Maneesha Thaker; Diego Almanza; Joshua M Dempster; Joshua Pan; Federica Piccioni; Nancy Dumont; Alfredo Gonzalez; Jonathan Rennhack; Behnam Nabet; John A Bachman; Amy Goodale; Yenarae Lee; Mukta Bagul; Rosy Liao; Adrija Navarro; Tina L Yuan; Raymond W S Ng; Srivatsan Raghavan; Nathanael S Gray; Aviad Tsherniak; Francisca Vazquez; David E Root; Ari J Firestone; Jeff Settleman; William C Hahn; Andrew J Aguirre
Journal: Cell Rep Date: 2019-10-01 Impact factor: 9.423

5. LZTR1 facilitates polyubiquitination and degradation of RAS-GTPases.

Authors: Taiki Abe; Ikumi Umeki; Shin-Ichiro Kanno; Shin-Ichi Inoue; Tetsuya Niihori; Yoko Aoki
Journal: Cell Death Differ Date: 2019-07-23 Impact factor: 15.828

6. RIT1 oncoproteins escape LZTR1-mediated proteolysis.

Authors: Pau Castel; Alice Cheng; Antonio Cuevas-Navarro; David B Everman; Alex G Papageorge; Dhirendra K Simanshu; Alexandra Tankka; Jacqueline Galeas; Anatoly Urisman; Frank McCormick
Journal: Science Date: 2019-03-15 Impact factor: 47.728

7. SHOC2-MRAS-PP1 complex positively regulates RAF activity and contributes to Noonan syndrome pathogenesis.

Authors: Lucy C Young; Nicole Hartig; Isabel Boned Del Río; Sibel Sari; Benjamin Ringham-Terry; Joshua R Wainwright; Greg G Jones; Frank McCormick; Pablo Rodriguez-Viciana
Journal: Proc Natl Acad Sci U S A Date: 2018-10-22 Impact factor: 11.205

8. NGS testing for cardiomyopathy: Utility of adding RASopathy-associated genes.

Authors: Ozge Ceyhan-Birsoy; Maya M Miatkowski; Elizabeth Hynes; Birgit H Funke; Heather Mason-Suares
Journal: Hum Mutat Date: 2018-05-16 Impact factor: 4.878

9. Delineation of LZTR1 mutation-positive patients with Noonan syndrome and identification of LZTR1 binding to RAF1-PPP1CB complexes.

Authors: Ikumi Umeki; Tetsuya Niihori; Taiki Abe; Shin-Ichiro Kanno; Nobuhiko Okamoto; Seiji Mizuno; Kenji Kurosawa; Keisuke Nagasaki; Makoto Yoshida; Hirofumi Ohashi; Shin-Ichi Inoue; Yoichi Matsubara; Ikuma Fujiwara; Shigeo Kure; Yoko Aoki
Journal: Hum Genet Date: 2018-10-27 Impact factor: 4.132

10. Integrated in silico MS-based phosphoproteomics and network enrichment analysis of RASopathy proteins.

Authors: Javier-Fernando Montero-Bullón; Óscar González-Velasco; María Isidoro-García; Jesus Lacal
Journal: Orphanet J Rare Dis Date: 2021-07-06 Impact factor: 4.123