阿斯科格-斯科特综合征:表型和遗传异质性

M. Jabalameli, I. Briceño, J. Martinez, R. Pengelly, S. Ennis, A. Collins
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引用次数: 7

摘要

Aarskog-Scott综合征(AAS)是一种罕见的发育障碍,主要影响男性,在一般人群中相对患病率为1 / 25,000。AAS患者通常表现为发育并发症,包括身材矮小、面部、骨骼和泌尿生殖器异常。AAS的基因型-表型相关谱尚不清楚,X染色体近端短臂FGD1基因突变仅占该疾病发病率的20%。在接受FGD1筛查的患者中未能发现致病变异,表明该疾病的病理生理学存在异质性。此外,AAS与其他几种发育障碍的重叠特征增加了诊断的复杂性。细胞骨架信号可能参与AAS的病理生理过程。FGD1蛋白家族在CDC42(细胞分裂控制蛋白42同源物)的激活中发挥作用,CDC42在细胞外基质的重塑和许多发育调节剂的转录激活中具有核心功能。因此,CDC42所属的EGFR1(表皮生长因子受体1)信号通路组分的突变可能有助于病理生理。平行测序策略(所谓的下一代测序或高通量测序)能够同时产生数百万个测序reads,极大地促进了对异质性单基因疾病中隐突变的经济有效鉴定。在这里,我们回顾了在AAS背景下表型和遗传异质性的来源,并讨论了下一代测序在鉴定AAS基础上的新突变的适用性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Aarskog-Scott syndrome: phenotypic and genetic heterogeneity
Abstract Aarskog-Scott syndrome (AAS) is a rare developmental disorder which primarily affects males and has a relative prevalence of 1 in 25,000 in the general population. AAS patients usually present with developmental complications including short stature and facial, skeletal and urogenital anomalies. The spectrum of genotype-phenotype correlations in AAS is unclear and mutations of the FGD1 gene on the proximal short arm of chromosome X account for only 20% of the incidence of the disorder. Failure to identify pathogenic variants in patients referred for FGD1 screening suggests heterogeneity underlying pathophysiology of the condition. Furthermore, overlapping features of AAS with several other developmental disorders increase the complexity of diagnosis. Cytoskeletal signaling may be involved in the pathophysiology of AAS. The FGD1 protein family has a role in activation of CDC42 (Cell Division Control protein 42 homolog) which has a core function in remodeling of extracellular matrix and the transcriptional activation of many modulators of development. Therefore, mutations in components in the EGFR1 (Epidermal Growth Factor Receptor 1) signaling pathway, to which CDC42 belongs, may contribute to pathophysiology. Parallel sequencing strategies (so-called next generation sequencing or high throughput sequencing) enables simultaneous production of millions of sequencing reads that enormously facilitate cost-effective identification of cryptic mutations in heterogeneous monogenic disorders. Here we review the source of phenotypic and genetic heterogeneity in the context of AAS and discuss the applicability of next generation sequencing for identification of novel mutations underlying AAS.
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AIMS Genetics
AIMS Genetics GENETICS & HEREDITY-
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