Identifying Aging and Alzheimer Disease-Associated Somatic Variations in Excitatory Neurons From the Human Frontal Cortex.

IF 3 3区医学 Q2 CLINICAL NEUROLOGY

Neurology-Genetics Pub Date : 2023-06-01 DOI:10.1212/NXG.0000000000200066

Meng Zhang, Gerard A Bouland, Henne Holstege, Marcel J T Reinders

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Abstract

Background and objectives: With age, somatic mutations accumulated in human brain cells can lead to various neurologic disorders and brain tumors. Because the incidence rate of Alzheimer disease (AD) increases exponentially with age, investigating the association between AD and the accumulation of somatic mutation can help understand the etiology of AD.

Methods: We designed a somatic mutation detection workflow by contrasting genotypes derived from whole-genome sequencing (WGS) data with genotypes derived from scRNA-seq data and applied this workflow to 76 participants from the Religious Order Study and the Rush Memory and Aging Project (ROSMAP) cohort. We focused only on excitatory neurons, the dominant cell type in the scRNA-seq data.

Results: We identified 196 sites that harbored at least 1 individual with an excitatory neuron-specific somatic mutation (ENSM), and these 196 sites were mapped to 127 genes. The single base substitution (SBS) pattern of the putative ENSMs was best explained by signature SBS5 from the Catalogue of Somatic Mutations in Cancer (COSMIC) mutational signatures, a clock-like pattern correlating with the age of the individual. The count of ENSMs per individual also showed an increasing trend with age. Among the mutated sites, we found 2 sites tend to have more mutations in older individuals (16:6899517 [RBFOX1], p = 0.04; 4:21788463 [KCNIP4], p < 0.05). In addition, 2 sites were found to have a higher odds ratio to detect a somatic mutation in AD samples (6:73374221 [KCNQ5], p = 0.01 and 13:36667102 [DCLK1], p = 0.02). Thirty-two genes that harbor somatic mutations unique to AD and the KCNQ5 and DCLK1 genes were used for gene ontology (GO)-term enrichment analysis. We found the AD-specific ENSMs enriched in the GO-term "vocalization behavior" and "intraspecies interaction between organisms." Of interest we observed both age-specific and AD-specific ENSMs enriched in the K⁺ channel-associated genes.

Discussion: Our results show that combining scRNA-seq and WGS data can successfully detect putative somatic mutations. The putative somatic mutations detected from ROSMAP data set have provided new insights into the association of AD and aging with brain somatic mutagenesis.

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识别人类额叶皮层兴奋性神经元的衰老和阿尔茨海默病相关体细胞变异。

背景与目的:随着年龄的增长，体细胞突变在人类脑细胞中积累，可导致各种神经系统疾病和脑肿瘤。由于阿尔茨海默病(AD)的发病率随着年龄的增长呈指数增长，因此研究AD与体细胞突变积累的关系有助于了解AD的病因。方法:通过对比全基因组测序(WGS)数据的基因型和scRNA-seq数据的基因型，设计了体细胞突变检测工作流程，并将该工作流程应用于来自宗教秩序研究和Rush记忆与衰老项目(ROSMAP)队列的76名参与者。我们只关注兴奋性神经元，这是scRNA-seq数据中的主要细胞类型。结果:我们确定了196个位点包含至少1个兴奋性神经元特异性体细胞突变(ENSM)个体，这196个位点被定位到127个基因。假定的ensm的单碱基取代(SBS)模式最好的解释是来自癌症体细胞突变目录(COSMIC)的突变签名SBS5，这是一种与个体年龄相关的时钟样模式。个体enms数也随年龄增长呈增加趋势。在突变位点中，我们发现2个位点在老年个体中突变较多(16:68 . 99 . 517 [RBFOX1]， p = 0.04;[04:21 . 17] [KCNIP4]， p < 0.05]。另外，2个位点在AD样本中检测体细胞突变的优势比较高(6:73374221 [KCNQ5]， p = 0.01; 13:36667102 [DCLK1]， p = 0.02)。32个携带AD特有体细胞突变的基因以及KCNQ5和DCLK1基因被用于基因本体(GO) term富集分析。我们发现ad特异性ensm富含go术语“发声行为”和“生物之间的种内相互作用”。有趣的是，我们观察到年龄特异性和ad特异性ensm都富含K+通道相关基因。讨论:我们的研究结果表明，结合scRNA-seq和WGS数据可以成功地检测出假定的体细胞突变。从ROSMAP数据集中检测到的假定体细胞突变为阿尔茨海默病和衰老与大脑体细胞突变的关联提供了新的见解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Neurology-Genetics Medicine-Neurology (clinical)

CiteScore

6.30

自引率

3.20%

发文量

107

审稿时长

15 weeks

期刊介绍： Neurology: Genetics is an online open access journal publishing peer-reviewed reports in the field of neurogenetics. Original articles in all areas of neurogenetics will be published including rare and common genetic variation, genotype-phenotype correlations, outlier phenotypes as a result of mutations in known disease-genes, and genetic variations with a putative link to diseases. This will include studies reporting on genetic disease risk and pharmacogenomics. In addition, Neurology: Genetics will publish results of gene-based clinical trials (viral, ASO, etc.). Genetically engineered model systems are not a primary focus of Neurology: Genetics, but studies using model systems for treatment trials are welcome, including well-powered studies reporting negative results.