Heterozygous Missense Variants in the ATPase Phospholipid Transporting 9A Gene, ATP9A, Alter Dendritic Spine Maturation and Cause Dominantly Inherited Nonsyndromic Intellectual Disability

IF 3.3 2区医学 Q2 GENETICS & HEREDITY

Human Mutation Pub Date : 2025-03-05 DOI:10.1155/humu/7085599

Amélie Cordovado, Yvan Hérenger, Coline Cormier, Estrella López-Martín, Hannah Stamberger, Laurence Faivre, Anne-Sophie Denommé-Pichon, Antonio Vitobello, Hamza Hadj Abdallah, Giulia Barcia, Thomas Courtin, Beatriz Martínez-Delgado, Eva Bermejo-Sánchez, María J. Barrero, Brooklynn Gasser, Stéphane Bezieau, Sébastien Küry, Sarah Weckhuysen, Frédéric Laumonnier, Annick Toutain, Marie-Laure Vuillaume

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Abstract

Intellectual disability is a neurodevelopmental disorder, affecting 2%–3% of the population, with a genetic cause in the majority of cases. ATP9A (Online Mendelian Inheritance in Man (OMIM) ^∗609126, NM_006045.3) has recently been added to the list of candidate genes involved in this disorder with the identification of biallelic truncating variants in patients with a neurodevelopmental disorder. In this study, we propose a novel mode of inheritance for ATP9A-related disorders with the identification of five de novo heterozygous missense variants (p.(Thr393Arg), p.(Glu400Gln), p.(Lys461Glu), p.(Gly552Ala), and p.(His713Asp)), in patients with intellectual disability. In a patient with a similar phenotype, we also identified two truncating variants in ATP9A (p.(Arg145 ^∗), p.(Glu901 ^∗)), adding a novel family to the six already described in the literature with the recessive mode of inheritance. Functional studies were performed to assess the pathogenicity of these variants. Overexpression of four selected missense mutant forms of Atp9a in HeLa cells and in primary neuronal cultures led to a loss of mature dendritic spines. In HeLa cells, the endosomal localization of the protein encoded by three of these missense variants was preserved whereas the fourth remained blocked in the endoplasmic reticulum. To mimic the effect on neuronal morphology and spine density of nonsense variants, small hairpin RNAs (shRNAs) were used. They induced a decreased expression of ATP9A, affecting the neuronal arborization by decreasing the number of dendrites per neuron. Our results therefore demonstrate the pathogenicity of ATP9A heterozygous missense variants and confirm the role of ATP9A in neuronal maturation and in brain wiring during development. They strengthen the association of ATP9A with neurodevelopmental disorders and demonstrate that a double mode of inheritance should be considered for ATP9A-related disorders.

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ATPase磷脂转运9A基因的杂合错义变异，ATP9A，改变树突状脊柱成熟并导致显性遗传性非综合征性智力残疾

智力残疾是一种神经发育障碍，影响2%-3%的人口，在大多数情况下是遗传原因。ATP9A（在线孟德尔遗传在人(OMIM) * 609126, NM_006045.3）最近被添加到该疾病的候选基因列表中，并在神经发育障碍患者中发现双等位基因截断变异。在这项研究中，我们提出了一种新的atp9a相关疾病的遗传模式，在智力残疾患者中鉴定出五种新杂合错义变异(p.(Thr393Arg), p.(Glu400Gln), p.（Lys461Glu), p.（Gly552Ala）和p.(His713Asp)）。在一个具有相似表型的患者中，我们还发现了ATP9A的两个截断变异体(p.(Arg145∗),p.(Glu901∗))，为文献中已经描述的六个具有隐性遗传模式的家族增加了一个新的家族。进行功能研究以评估这些变异的致病性。在HeLa细胞和原代神经元培养中，四种选择的错义突变形式的Atp9a过表达导致成熟树突棘的缺失。在HeLa细胞中，三种错义变异体编码的蛋白的内体定位得以保留，而第四种错义变异体在内质网中被阻断。为了模拟无义变异对神经元形态和脊柱密度的影响，使用了小发夹rna （shrna）。它们诱导ATP9A表达降低，通过减少每个神经元的树突数量来影响神经元的树突化。因此，我们的研究结果证明了ATP9A杂合错义变异体的致病性，并证实了ATP9A在发育过程中神经元成熟和大脑布线中的作用。他们加强了ATP9A与神经发育障碍的联系，并表明ATP9A相关疾病应考虑双重遗传模式。

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来源期刊

Human Mutation 医学-遗传学

CiteScore

8.40

自引率

5.10%

发文量

190

审稿时长

2 months

期刊介绍： Human Mutation is a peer-reviewed journal that offers publication of original Research Articles, Methods, Mutation Updates, Reviews, Database Articles, Rapid Communications, and Letters on broad aspects of mutation research in humans. Reports of novel DNA variations and their phenotypic consequences, reports of SNPs demonstrated as valuable for genomic analysis, descriptions of new molecular detection methods, and novel approaches to clinical diagnosis are welcomed. Novel reports of gene organization at the genomic level, reported in the context of mutation investigation, may be considered. The journal provides a unique forum for the exchange of ideas, methods, and applications of interest to molecular, human, and medical geneticists in academic, industrial, and clinical research settings worldwide.