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FGFR2突变对颅面形状和颅底软骨结合部细胞动力学的剂量依赖性影响。

Dosage-dependent effects of FGFR2 mutation on craniofacial shape and cellular dynamics of the basicranial synchondroses.

作者信息

Richbourg Heather A, Vidal-García Marta, Brakora Katherine A, Devine Jay, Takenaka Risa, Young Nathan M, Gong Siew-Ging, Neves Amanda, Hallgrímsson Benedikt, Marcucio Ralph S

机构信息

Department of Orthopedic Surgery, University of California, San Francisco, San Francisco, California, USA.

Alberta Children's Hospital Research Institute, University of Calgary, Calgary, Alberta, Canada.

出版信息

Anat Rec (Hoboken). 2024 Feb 26. doi: 10.1002/ar.25398.

DOI:10.1002/ar.25398
PMID:38409943
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11345876/
Abstract

Craniosynostosis is a common yet complex birth defect, characterized by premature fusion of the cranial sutures that can be syndromic or nonsyndromic. With over 180 syndromic associations, reaching genetic diagnoses and understanding variations in underlying cellular mechanisms remains a challenge. Variants of FGFR2 are highly associated with craniosynostosis and warrant further investigation. Using the missense mutation FGFR2 , an effective mouse model of Crouzon syndrome, craniofacial features were analyzed using geometric morphometrics across developmental time (E10.5-adulthood, n = 665 total). Given the interrelationship between the cranial vault and basicranium in craniosynostosis patients, the basicranium and synchondroses were analyzed in perinates. Embryonic time points showed minimal significant shape differences. However, hetero- and homozygous mutant perinates and adults showed significant differences in shape and size of the cranial vault, face, and basicranium, which were associated with cranial doming and shortening of the basicranium and skull. Although there were also significant shape and size differences associated with the basicranial bones and clear reductions in basicranial ossification in cleared whole-mount samples, there were no significant alterations in chondrocyte cell shape, size, or orientation along the spheno-occipital synchondrosis. Finally, shape differences in the cranial vault and basicranium were interrelated at perinatal stages. These results point toward the possibility that facial shape phenotypes in craniosynostosis may result in part from pleiotropic effects of the causative mutations rather than only from the secondary consequences of the sutural defects, indicating a novel direction of research that may shed light on the etiology of the broad changes in craniofacial morphology observed in craniosynostosis syndromes.

摘要

颅缝早闭是一种常见但复杂的出生缺陷,其特征是颅缝过早融合,可伴有综合征或无综合征。颅缝早闭有超过180种综合征关联,实现基因诊断并理解潜在细胞机制的变异仍然是一项挑战。FGFR2的变异与颅缝早闭高度相关,值得进一步研究。利用错义突变FGFR2,构建了一种有效的克鲁宗综合征小鼠模型,通过几何形态计量学分析了整个发育时期(从胚胎第10.5天到成年期,共665只)的颅面特征。鉴于颅缝早闭患者颅顶和颅底之间的相互关系,对围产期婴儿的颅底和软骨结合进行了分析。胚胎期各时间点的形状差异极小。然而,杂合子和纯合子突变围产期婴儿及成年小鼠在颅顶、面部和颅底的形状和大小上存在显著差异,这些差异与颅穹隆、颅底和颅骨缩短有关。尽管在清除后的整体样本中,颅底骨也存在显著的形状和大小差异,且颅底骨化明显减少,但蝶枕软骨结合处的软骨细胞形状、大小或方向并无显著改变。最后,围产期颅顶和颅底的形状差异是相互关联的。这些结果表明,颅缝早闭的面部形状表型可能部分源于致病突变的多效性效应,而非仅源于缝合缺陷的继发后果,这为研究颅缝早闭综合征中观察到的颅面形态广泛变化的病因指明了一个新方向。

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