同义 FAM111A 变异是肯尼-卡菲综合征常染色体隐性遗传的基础。

IF 2.6 3区 生物学 Q2 GENETICS & HEREDITY Journal of Human Genetics Pub Date : 2024-11-06 DOI:10.1038/s10038-024-01301-1
Loisa Dana Bonde, Ibrahim M Abdelrazek, Lara Seif, Malik Alawi, Khaled Matrawy, Karim Nabil, Ebtesam Abdalla, Kerstin Kutsche, Frederike Leonie Harms
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引用次数: 0

摘要

FAM111A(序列相似性家族111成员A)是一种丝氨酸蛋白酶,能在DNA复制过程中去除DNA与蛋白质的共价交联。FAM111A 的杂合子功能增益变体会导致骨骼发育不良,如围产期致死性骨质疏松症和较轻的肯尼-卡菲综合征(KCS)。我们报告了两对兄弟姐妹,他们的父母为近亲结婚,所生子女具有畸形的颅面特征、出生后生长迟缓、眼科表现、毛发和指甲异常以及骨骼异常(如皮质增厚和长骨髓腔狭窄),这提示他们患有 KCS。通过外显子组测序,在两个兄弟姐妹中发现了一个同义 FAM111A 变体 NM_001312909.2:c.81 G > A; p.Pro27=,该变体影响外显子的最后一个碱基,预计会改变 FAM111A 的前 mRNA 剪接。我们在两名患者的成纤维细胞中都发现了异常剪接的 FAM111A 转录本、降低的 FAM111A mRNA 水平和几乎完全缺失的 FAM111A 蛋白质。用不同浓度的喜树碱处理患者和对照组成纤维细胞后(喜树碱可诱导共价 DNA 蛋白交联),我们观察到患者成纤维细胞中代谢活跃细胞的比例趋于低于对照组成纤维细胞。然而,在这些培养条件下,我们并未发现患者细胞和对照组细胞在细胞周期进展和细胞凋亡方面存在一致且具有统计学意义的差异。我们的研究结果表明,FAM111A 缺陷是 FAM111A 相关 KCS 常染色体隐性遗传形式的基础。根据我们的研究结果和已发表的数据,我们推测,FAM111A的缺失和FAM111A蛋白酶的亢进,正如在功能增益型患者变异蛋白中观察到的那样,可能与骨骼发育不良的病理机制相似。
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Homozygous synonymous FAM111A variant underlies an autosomal recessive form of Kenny-Caffey syndrome.

FAM111A (family with sequence similarity 111 member A) is a serine protease and removes covalent DNA-protein cross-links during DNA replication. Heterozygous gain-of-function variants in FAM111A cause skeletal dysplasias, such as the perinatal lethal osteocraniostenosis and the milder Kenny-Caffey syndrome (KCS). We report two siblings born to consanguineous parents with dysmorphic craniofacial features, postnatal growth retardation, ophthalmologic manifestations, hair and nail anomalies, and skeletal abnormalities such as thickened cortex and stenosis of the medullary cavity of the long bones suggestive of KCS. Using exome sequencing, a homozygous synonymous FAM111A variant, NM_001312909.2:c.81 G > A; p.Pro27=, that affects the last base of the exon and is predicted to alter FAM111A pre-mRNA splicing, was identified in both siblings. We identified aberrantly spliced FAM111A transcripts, reduced FAM111A mRNA levels, and near-complete absence of FAM111A protein in fibroblasts of both patients. After treatment of patient and control fibroblasts with different concentrations of camptothecin that induces covalent DNA-protein cross-links, we observed a tendency towards a reduced proportion of metabolically active cells in patient compared to control fibroblasts. However, under these culture conditions, we did not find consistent and statistically significant differences in cell cycle progression and apoptotic cell death between patient and control cells. Our findings show that FAM111A deficiency underlies an autosomal recessive form of FAM111A-related KCS. Based on our results and published data, we hypothesize that loss of FAM111A and FAM111A protease hyperactivity, as observed for gain-of-function patient-variant proteins, may converge on a similar pathomechanism underlying skeletal dysplasias.

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来源期刊
Journal of Human Genetics
Journal of Human Genetics 生物-遗传学
CiteScore
7.20
自引率
0.00%
发文量
101
审稿时长
4-8 weeks
期刊介绍: The Journal of Human Genetics is an international journal publishing articles on human genetics, including medical genetics and human genome analysis. It covers all aspects of human genetics, including molecular genetics, clinical genetics, behavioral genetics, immunogenetics, pharmacogenomics, population genetics, functional genomics, epigenetics, genetic counseling and gene therapy. Articles on the following areas are especially welcome: genetic factors of monogenic and complex disorders, genome-wide association studies, genetic epidemiology, cancer genetics, personal genomics, genotype-phenotype relationships and genome diversity.
期刊最新文献
Preimplantation genetic testing for inborn errors of metabolism: observations from a reproductive genetic laboratory in China. Identification of biallelic intronic EPM2A mutations in a Lafora disease kindred. Expanding the spectrum of HSPB8-related myopathy: a novel mutation causing atypical pediatric-onset axial and limb-girdle involvement with autophagy abnormalities and molecular dynamics studies. Novel variants in DNAH9 are present in two infertile patients with severe asthenospermia. Homozygous synonymous FAM111A variant underlies an autosomal recessive form of Kenny-Caffey syndrome.
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