Douglas J. Wilkin scite author profile

Thanatophoric dysplasia (TD), the most common neonatal lethal skeletal dysplasia, affects one out of 20,000 live births. Affected individuals display features similar to those seen in homozygous achondroplasia. Mutations causing achondroplasia are in FGFR3, suggesting that mutations in this gene may cause TD. A sporadic mutation causing a Lys650Glu change in the tyrosine kinase domain of FGFR3 was found in 16 of 16 individuals with one type of TD. Of 39 individuals with a second type of TD, 22 had a mutation causing an Arg248Cys change and one had a Ser371Cys substitution, both in the extracellular region of the protein. None of these mutations were found in 50 controls showing that mutations affecting different functional domains of FGFR3 cause different forms of this lethal disorder.

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Calcification in atherosclerosis: Bone biology and chronic inflammation at the arterial crossroads

Doherty

Asotra

Fitzpatrick

et al. 2003

Proc. Natl. Acad. Sci. U.S.A.

409

320

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Dystrophic or ectopic mineral deposition occurs in many pathologic conditions, including atherosclerosis. Calcium mineral deposits that frequently accompany atherosclerosis are readily quantifiable radiographically, serve as a surrogate marker for the disease, and predict a higher risk of myocardial infarction and death. Accelerating research interest has been propelled by a clear need to understand how plaque structure, composition, and stability lead to devastating cardiovascular events. In atherosclerotic plaque, accumulating evidence is consistent with the notion that calcification involves the participation of arterial osteoblasts and osteoclasts. Here we summarize current models of intimal arterial plaque calcification and highlight intriguing questions that require further investigation. Because atherosclerosis is a chronic vascular inflammation, we propose that arterial plaque calcification is best conceptualized as a convergence of bone biology with vascular inflammatory pathobiology.P laque structure and composition importantly impact clinical expression of atherosclerosis. Molecular medicine in the 21st century has turned toward a comprehensive understanding of the dynamic processes that influence the composition and stability of atheroma and of how structural plaque components impact clinical outcomes. Recently, increasing interest has focused on understanding how atherosclerotic pathology is related to a common plaque constituent: calcium mineral deposits. Pathologists have long known that calcified atherosclerotic arteries can contain tissue that is histomorphologically indistinguishable from bone (1, 2). Important studies in the last decade have now spawned a model wherein calcification in atherosclerotic plaque is viewed as an active, complex, and therefore presumably regulated process that exhibits intriguing similarities to new bone formation, or remodeling. Ectopic and dystrophic mineral deposition and extracellular matrix calcification can occur in numerous pathologic conditions by passive precipitation. Here we focus on one specific type of mineral deposition with high relevance to cardiac pathology: intimal arterial calcification in the context of atherosclerotic plaque. The emerging view is that plaque calcification represents a meeting of bone biology with chronic plaque inflammation. Remarkable cellular ontogenetic versatility in atherosclerosis appears to effect profound structural alterations, with significant ramifications for plaque stability and clinical outcomes. Clinical SignificanceAtherosclerotic lesions frequently become calcified. The process can begin early and accelerates as the disease progresses and more complex lesions develop. Calcium deposits in coronary arteries indicate the presence of plaque, but the converse statement that an absence of coronary calcium indicates an absence of atheromatous plaque is not true (1). Because calcification is a surrogate measure of coronary atherosclerosis, clinical interest has focused on the usefulness of noninvasive detection of calci...

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Heterozygous mutations in the gene encoding noggin affect human joint morphogenesis

et al. 1999

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The secreted polypeptide noggin (encoded by the Nog gene) binds and inactivates members of the transforming growth factor beta superfamily of signalling proteins (TGFbeta-FMs), such as BMP4 (ref. 1). By diffusing through extracellular matrices more efficiently than TGFbeta-FMs, noggin may have a principal role in creating morphogenic gradients. During mouse embryogenesis, Nog is expressed at multiple sites, including developing bones. Nog-/- mice die at birth from multiple defects that include bony fusion of the appendicular skeleton. We have identified five dominant human NOG mutations in unrelated families segregating proximal symphalangism (SYM1; OMIM 185800) and a de novo mutation in a patient with unaffected parents. We also found a dominant NOG mutation in a family segregating multiple synostoses syndrome (SYNS1; OMIM 186500); both SYM1 and SYNS1 have multiple joint fusion as their principal feature. All seven NOG mutations alter evolutionarily conserved amino acid residues. The findings reported here confirm that NOG is essential for joint formation and suggest that NOG requirements during skeletogenesis differ between species and between specific skeletal elements within species.

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Mutations in Fibroblast Growth-Factor Receptor 3 in Sporadic Cases of Achondroplasia Occur Exclusively on the Paternally Derived Chromosome

Wilkin

Szabo

Cameron

et al. 1998

The American Journal of Human Genetics

210

135

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More than 97% of achondroplasia cases are caused by one of two mutations (G1138A and G1138C) in the fibroblast growth factor receptor 3 (FGFR3) gene, which results in a specific amino acid substitution, G380R. Sporadic cases of achondroplasia have been associated with advanced paternal age, suggesting that these mutations occur preferentially during spermatogenesis. We have determined the parental origin of the achondroplasia mutation in 40 sporadic cases. Three distinct 1-bp polymorphisms were identified in the FGFR3 gene, within close proximity to the achondroplasia mutation site. Ninety-nine families, each with a sporadic case of achondroplasia in a child, were analyzed in this study. In this population, the achondroplasia mutation occurred on the paternal chromosome in all 40 cases in which parental origin was unambiguous. This observation is consistent with the clinical observation of advanced paternal age resulting in new cases of achondroplasia and suggests that factors influencing DNA replication or repair during spermatogenesis, but not during oogenesis, may predispose to the occurrence of the G1138 FGFR3 mutations.

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Douglas J. Wilkin

Thanatophoric dysplasia (types I and II) caused by distinct mutations in fibroblast growth factor receptor 3

Calcification in atherosclerosis: Bone biology and chronic inflammation at the arterial crossroads

Heterozygous mutations in the gene encoding noggin affect human joint morphogenesis

Mutations in Fibroblast Growth-Factor Receptor 3 in Sporadic Cases of Achondroplasia Occur Exclusively on the Paternally Derived Chromosome

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