KAT6A mutations in Arboleda-Tham syndrome drive epigenetic regulation of posterior HOXC cluster.

IF 3.8 2区生物学 Q2 GENETICS & HEREDITY

Human Genetics Pub Date : 2023-12-01 Epub Date: 2023-10-20 DOI:10.1007/s00439-023-02608-3

Meghna Singh, Sarah J Spendlove, Angela Wei, Leroy M Bondhus, Aileen A Nava, Francisca N de L Vitorino, Seth Amano, Jacob Lee, Gesenia Echeverria, Dianne Gomez, Benjamin A Garcia, Valerie A Arboleda

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Abstract

Arboleda-Tham Syndrome (ARTHS) is a rare genetic disorder caused by heterozygous, de novo mutations in Lysine(K) acetyltransferase 6A (KAT6A). ARTHS is clinically heterogeneous and characterized by several common features, including intellectual disability, developmental and speech delay, and hypotonia, and affects multiple organ systems. KAT6A is the enzymatic core of a histone-acetylation protein complex; however, the direct histone targets and gene regulatory effects remain unknown. In this study, we use ARTHS patient (n = 8) and control (n = 14) dermal fibroblasts and perform comprehensive profiling of the epigenome and transcriptome caused by KAT6A mutations. We identified differential chromatin accessibility within the promoter or gene body of 23% (14/60) of genes that were differentially expressed between ARTHS and controls. Within fibroblasts, we show a distinct set of genes from the posterior HOXC gene cluster (HOXC10, HOXC11, HOXC-AS3, HOXC-AS2, and HOTAIR) that are overexpressed in ARTHS and are transcription factors critical for early development body segment patterning. The genomic loci harboring HOXC genes are epigenetically regulated with increased chromatin accessibility, high levels of H3K23ac, and increased gene-body DNA methylation compared to controls, all of which are consistent with transcriptomic overexpression. Finally, we used unbiased proteomic mass spectrometry and identified two new histone post-translational modifications (PTMs) that are disrupted in ARTHS: H2A and H3K56 acetylation. Our multi-omics assays have identified novel histone and gene regulatory roles of KAT6A in a large group of ARTHS patients harboring diverse pathogenic mutations. This work provides insight into the role of KAT6A on the epigenomic regulation in somatic cell types.

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Arboleda Tham综合征中的KAT6A突变驱动后HOXC簇的表观遗传学调控。

Arboleda Tham综合征（ARTHS）是一种罕见的遗传病，由赖氨酸（K）乙酰转移酶6A（KAT6A）的杂合、从头突变引起。ARTHS在临床上是异质性的，具有几个常见特征，包括智力残疾、发育和言语迟缓以及张力减退，并影响多个器官系统。KAT6A是组蛋白乙酰化蛋白复合物的酶核心；然而，组蛋白的直接靶点和基因调控作用尚不清楚。在本研究中，我们使用ARTHS患者（n = 8）和控制（n = 14）真皮成纤维细胞，并对KAT6A突变引起的表观基因组和转录组进行全面分析。我们在启动子或基因体中鉴定了23%（14/60）在ARTHS和对照之间差异表达的基因的染色质可及性差异。在成纤维细胞中，我们展示了一组来自后HOXC基因簇的不同基因（HOXC10、HOXC11、HOXC-AS3、HOXC-AS2和HOTAIR），它们在ARTHS中过表达，是早期发育体节模式的关键转录因子。与对照组相比，携带HOXC基因的基因组基因座受到表观遗传学调控，染色质可及性增加，H3K23ac水平高，基因体DNA甲基化增加，所有这些都与转录组过度表达一致。最后，我们使用无偏蛋白质组学质谱法，鉴定了两种在ARTHS中被破坏的新的组蛋白翻译后修饰（PTMs）：H2A和H3K56乙酰化。我们的多组学分析已经在一大群携带不同致病突变的ARTHS患者中确定了KAT6A的新组蛋白和基因调控作用。这项工作深入了解了KAT6A在体细胞类型表观基因组调控中的作用。

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来源期刊

Human Genetics 生物-遗传学

CiteScore

10.80

自引率

3.80%

发文量

审稿时长

1 months

期刊介绍： Human Genetics is a monthly journal publishing original and timely articles on all aspects of human genetics. The Journal particularly welcomes articles in the areas of Behavioral genetics, Bioinformatics, Cancer genetics and genomics, Cytogenetics, Developmental genetics, Disease association studies, Dysmorphology, ELSI (ethical, legal and social issues), Evolutionary genetics, Gene expression, Gene structure and organization, Genetics of complex diseases and epistatic interactions, Genetic epidemiology, Genome biology, Genome structure and organization, Genotype-phenotype relationships, Human Genomics, Immunogenetics and genomics, Linkage analysis and genetic mapping, Methods in Statistical Genetics, Molecular diagnostics, Mutation detection and analysis, Neurogenetics, Physical mapping and Population Genetics. Articles reporting animal models relevant to human biology or disease are also welcome. Preference will be given to those articles which address clinically relevant questions or which provide new insights into human biology. Unless reporting entirely novel and unusual aspects of a topic, clinical case reports, cytogenetic case reports, papers on descriptive population genetics, articles dealing with the frequency of polymorphisms or additional mutations within genes in which numerous lesions have already been described, and papers that report meta-analyses of previously published datasets will normally not be accepted. The Journal typically will not consider for publication manuscripts that report merely the isolation, map position, structure, and tissue expression profile of a gene of unknown function unless the gene is of particular interest or is a candidate gene involved in a human trait or disorder.