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Literature DB >> 17033969

A novel mutation in FGFR3 causes camptodactyly, tall stature, and hearing loss (CATSHL) syndrome.

Reha M Toydemir¹, Anna E Brassington, Pinar Bayrak-Toydemir, Patrycja A Krakowiak, Lynn B Jorde, Frank G Whitby, Nicola Longo, David H Viskochil, John C Carey, Michael J Bamshad.

Abstract

Activating mutations of FGFR3, a negative regulator of bone growth, are well known to cause a variety of short-limbed bone dysplasias and craniosynostosis syndromes. We mapped the locus causing a novel disorder characterized by camptodactyly, tall stature, scoliosis, and hearing loss (CATSHL syndrome) to chromosome 4p. Because this syndrome recapitulated the phenotype of the Fgfr3 knockout mouse, we screened FGFR3 and subsequently identified a heterozygous missense mutation that is predicted to cause a p.R621H substitution in the tyrosine kinase domain and partial loss of FGFR3 function. These findings indicate that abnormal FGFR3 signaling can cause human anomalies by promoting as well as inhibiting endochondral bone growth.

Entities: Disease Gene Mutation Species

Mesh：

Substances：

Year: 2006 PMID： 17033969 PMCID： PMC1698566 DOI： 10.1086/508433

Source DB: PubMed Journal: Am J Hum Genet ISSN： 0002-9297 Impact factor: 11.025

16 in total

1. Naturally occurring amino acid substitutions at Arg1174 in the human insulin receptor result in differential effects on receptor biosynthesis and hybrid formation, leading to discordant clinical phenotypes.

Authors: H Rau; M Kocova; S O'Rahilly; J P Whitehead
Journal: Diabetes Date: 2000-07 Impact factor: 9.461

2. Multiple activation loop conformations and their regulatory properties in the insulin receptor's kinase domain.

Authors: A J Ablooglu; M Frankel; E Rusinova; J B Ross; R A Kohanski
Journal: J Biol Chem Date: 2001-10-11 Impact factor: 5.157

3. Radiographic diagnosis of hereditary chondrodysplasia in newborn lambs.

Authors: J A Vanek; P A Walter; A D Alstad
Journal: J Am Vet Med Assoc Date: 1989-01-15 Impact factor: 1.936

4. Mutations in different components of FGF signaling in LADD syndrome.

Authors: Edyta Rohmann; Han G Brunner; Hülya Kayserili; Oya Uyguner; Gudrun Nürnberg; Erin D Lew; Angus Dobbie; Veraragavan P Eswarakumar; Abdullah Uzumcu; Melike Ulubil-Emeroglu; Jules G Leroy; Yun Li; Christian Becker; Kai Lehnerdt; Cor W R J Cremers; Memnune Yüksel-Apak; Peter Nürnberg; Christian Kubisch; Chriütian Kubisch; Joseph Schlessinger; Hans van Bokhoven; Bernd Wollnik
Journal: Nat Genet Date: 2006-02-26 Impact factor: 38.330

5. Chemical rescue of a mutant protein-tyrosine kinase.

Authors: D M Williams; D Wang; P A Cole
Journal: J Biol Chem Date: 2000-12-08 Impact factor: 5.157

6. Expression of a dominant-negative mutant human insulin receptor in the muscle of transgenic mice.

Authors: P Y Chang; H Benecke; Y Le Marchand-Brustel; J Lawitts; D E Moller
Journal: J Biol Chem Date: 1994-06-10 Impact factor: 5.157

Review 7. FGFs, their receptors, and human limb malformations: clinical and molecular correlations.

Authors: Andrew O M Wilkie; Susannah J Patey; Shih-Hsin Kan; Ans M W van den Ouweland; Ben C J Hamel
Journal: Am J Med Genet Date: 2002-10-15

8. Fibroblast growth factor receptor 3 is a negative regulator of bone growth.

Authors: C Deng; A Wynshaw-Boris; F Zhou; A Kuo; P Leder
Journal: Cell Date: 1996-03-22 Impact factor: 41.582

9. Skeletal overgrowth and deafness in mice lacking fibroblast growth factor receptor 3.

Authors: J S Colvin; B A Bohne; G W Harding; D G McEwen; D M Ornitz
Journal: Nat Genet Date: 1996-04 Impact factor: 38.330

10. The site of action of neuronal acidic fibroblast growth factor is the organ of Corti of the rat cochlea.

Authors: U Pirvola; Y Cao; C Oellig; Z Suoqiang; R F Pettersson; J Ylikoski
Journal: Proc Natl Acad Sci U S A Date: 1995-09-26 Impact factor: 11.205

47 in total

1. Genetic inactivation of ERK1 and ERK2 in chondrocytes promotes bone growth and enlarges the spinal canal.

Authors: Arjun Sebastian; Takehiko Matsushita; Aya Kawanami; Susan Mackem; Gary E Landreth; Shunichi Murakami
Journal: J Orthop Res Date: 2010-10-04 Impact factor: 3.494

Review 2. Sixteen years and counting: the current understanding of fibroblast growth factor receptor 3 (FGFR3) signaling in skeletal dysplasias.

Authors: Silvie Foldynova-Trantirkova; William R Wilcox; Pavel Krejci
Journal: Hum Mutat Date: 2011-11-16 Impact factor: 4.878

3. FGF signaling in the osteoprogenitor lineage non-autonomously regulates postnatal chondrocyte proliferation and skeletal growth.

Authors: Kannan Karuppaiah; Kai Yu; Joohyun Lim; Jianquan Chen; Craig Smith; Fanxin Long; David M Ornitz
Journal: Development Date: 2016-04-06 Impact factor: 6.868

Review 4. Genetics of Short Stature.

Authors: Youn Hee Jee; Anenisia C Andrade; Jeffrey Baron; Ola Nilsson
Journal: Endocrinol Metab Clin North Am Date: 2017-02-23 Impact factor: 4.741

Review 5. Height matters-from monogenic disorders to normal variation.

Authors: Claudia Durand; Gudrun A Rappold
Journal: Nat Rev Endocrinol Date: 2013-01-22 Impact factor: 43.330

6. Fibroblast growth factor expression during skeletal fracture healing in mice.

Authors: Gregory J Schmid; Chikashi Kobayashi; Linda J Sandell; David M Ornitz
Journal: Dev Dyn Date: 2009-03 Impact factor: 3.780

7. Gain-of-function mutation in FGFR3 in mice leads to decreased bone mass by affecting both osteoblastogenesis and osteoclastogenesis.

Authors: Nan Su; Qidi Sun; Can Li; Xiumin Lu; Huabing Qi; Siyu Chen; Jing Yang; Xiaolan Du; Ling Zhao; Qifen He; Min Jin; Yue Shen; Di Chen; Lin Chen
Journal: Hum Mol Genet Date: 2010-01-06 Impact factor: 6.150