跨膜蛋白 53 颅管发育不良症(OMIM # 619727):这种新疾病会导致骨骼疾病和失明。

IF 3.5 2区 医学 Q2 ENDOCRINOLOGY & METABOLISM Bone Pub Date : 2024-07-30 DOI:10.1016/j.bone.2024.117218
Michael P. Whyte , Robert S. Weinstein , Paul H. Phillips , William H. McAlister , Raghuhr H. Ramakrishnaiah , G. Bradley Schaefer , Rongsheng Cai , Michele R. Hutchison , Shenghui Duan , Gary S. Gottesman , Steven Mumm
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引用次数: 0

摘要

池川型颅管发育不良(OMIM #619727)是2021年发现的一种常染色体隐性遗传骨骼疾病,其特征是儿童期失明。四个印度家庭中的五名年轻成员在编码跨膜蛋白53(TMEM53)的基因TMEM53(OMIM *619722)中存在一个同源染色体嵌合。在完整的情况下,TMEM53 可跨越骨生成细胞的核包膜,抑制 BMP-SMAD 信号传导,从而减缓骨形成。因此,有缺陷的 TMEM53 会加速骨形成。在本文中,一名美国男孩是TMEM53中一个新型缺失突变和一个新型错义突变的复合杂合子。他的视力和感音神经性听力受损。影像学检查显示,他的头骨呈二倍体增厚,颅骨和面部骨骼宽大,骨骼建模错误,椎体扁平,肋骨宽大,骨骼膨大骨质疏松。DXA 骨密度(克/平方厘米)Z 值偏低。他的视神经、听神经和脊椎管狭窄。矿物质代谢正常。血清碱性磷酸酶和骨钙素水平正常,但 CTX 偏高。髂嵴组织形态测量显示骨形成加速。在服用强的松、进行视神经管减压术和视神经鞘切开术后,他的急性视力减退情况曾短暂好转,但随后尽管进行了进一步手术和旨在抑制骨转换的唑来膦酸盐治疗,病情仍在恶化。对与骨骼质量升高(包括高骨转换)相关的基因进行了新一代测序,但并未发现病因。随后,全基因组测序发现 TMEM53 中存在:i)父方遗传的 54 碱基缺失,其中包括第 2 外显子的 mRNA 剪接受体位点以及 31 碱基的外显子序列(c. 62-23_92del);ii)母方遗传的错义变异(c.650C>T,p.Ser217Leu:NM_024587.4/NP_078863.2),它在 gnomAD 中极为罕见(频率 = 0.000036),取代了跨物种高度保守的 Ser217,并被 SIFT 和 Mutation Taster 评定为损伤性变异。我们将这种新的骨病称为 TMEM53 颅管发育不良。
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Transmembrane protein 53 craniotubular dysplasia (OMIM # 619727): The skeletal disease and consequent blindness of this new disorder

Craniotubular dysplasia, Ikegawa type (OMIM #619727) denotes the autosomal recessive skeletal disease identified in 2021 featuring blindness acquired in childhood. Five young members of four Indian families harbored a homozygous indel within TMEM53 (OMIM *619722), the gene that encodes transmembrane protein 53 (TMEM53). When intact, TMEM53 spans the nuclear envelope of osteoprogenitor cells, dampens BMP-SMAD signaling, and thereby slows bone formation. Consequently, defective TMEM53 accelerates osteogenesis. Herein, an American boy is compound heterozygous for a novel deletion and a novel missense mutation within TMEM53. His vision and sensorineural hearing became impaired. Radiographic survey revealed diploic thickening of his skull, broad calvarial and facial bones, skeletal modeling errors, vertebral body flattening, wide ribs, and osteopenia of expanded bones. DXA areal bone density (gm/cm2) Z-scores were low. His optic, auditory, and spinal canals were narrow. Mineral metabolism was intact. Serum alkaline phosphatase and osteocalcin levels were normal yet CTX was high. Iliac crest histomorphometry documented accelerated bone formation. His acute vision loss briefly improved following prednisone administration, optic canal decompression, and optic nerve sheath fenestration, but then progressed despite further surgeries and zoledronate treatment aimed to suppress bone turnover. Next generation sequencing of genes associated with elevated skeletal mass, including from high bone turnover, did not suggest an etiology. Whole genome sequencing then revealed within TMEM53: i) a paternally transmitted 54-base deletion, which included the mRNA splice acceptor site for exon 2 as well as 31 bases of exonic sequence (c. 62-23_92del), and ii) a maternally transmitted missense variant (c.650C > T, p.Ser217Leu: NM_024587.4/NP_078863.2) which is extremely rare in gnomAD (frequency = 0.000036), replaces Ser217 highly conserved across species, and is scored as damaging by SIFT and Mutation Taster. We call this new osteopathy TMEM53 craniotubular dysplasia.

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来源期刊
Bone
Bone 医学-内分泌学与代谢
CiteScore
8.90
自引率
4.90%
发文量
264
审稿时长
30 days
期刊介绍: BONE is an interdisciplinary forum for the rapid publication of original articles and reviews on basic, translational, and clinical aspects of bone and mineral metabolism. The Journal also encourages submissions related to interactions of bone with other organ systems, including cartilage, endocrine, muscle, fat, neural, vascular, gastrointestinal, hematopoietic, and immune systems. Particular attention is placed on the application of experimental studies to clinical practice.
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