阿尔茨海默病(AD)危险基因的脑区域依赖性选择性剪接与AD的神经病理特征相关

IF 1.8 3区 医学 Q3 UROLOGY & NEPHROLOGY
Sara Kim, Seonggyun Han, Soo-Ah Cho, Kwangsik Nho, Insong Koh, Younghee Lee
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引用次数: 3

摘要

目的:阿尔茨海默病(AD)是最复杂的疾病之一,其特点是AD相关的神经病理特征,包括淀粉样蛋白-β斑块和tau神经原纤维缠结的积累。选择性剪接(AS)的失调促成了这些特征,AD患者在不同脑区之间的特征存在异质性,导致不同的严重程度和进展率;然而,大脑区域特异性的AS机制仍不清楚。因此,我们旨在系统地研究AD患者多脑区AS及其对临床特征的影响。方法:我们分析了从AD患者的大脑区域(额叶和颞叶)获得的RNA测序(RNA- seq)数据。使用STAR比对器将Reads映射到hg19参考基因组,并通过rMATs估计外显子跳变(ES)率为剪接在(PSI)中的百分比。我们关注通过全基因组关联研究发现的ad风险基因,并相应地评估ad风险基因中跳过外显子的PSI与每个脑区Braak阶段和斑块密度平均值(PM)之间的关系。我们还将确定样本的全基因组测序数据与RNA-Seq数据相结合,以确定特征相关ES的遗传调控因子。结果:在额叶区和颞叶区分别鉴定出26个和41个与Braak期相关的ES, 10个和50个与PM相关的ES。其中,10个是额特异性的(CLU和NTRK2), 65个是时间特异性的(HIF1A和TRPC4AP), 26个共享ES (APP)伴随着功能基因本体术语,包括共享ES基因的轴突发生。我们进一步确定了44个ES(占总数的44%)的遗传调控因子。最后,我们介绍了APP中ES的系统调控,这在AD发病机制中很重要。结论:该研究为AD风险基因结构的脑区域依赖性调节提供了新的见解,该基因结构有助于AD病理,最终允许识别AD的治疗靶点和区域特异性生物标志物。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Brain Region-Dependent Alternative Splicing of Alzheimer Disease (AD)-Risk Genes Is Associated With Neuropathological Features in AD.

Brain Region-Dependent Alternative Splicing of Alzheimer Disease (AD)-Risk Genes Is Associated With Neuropathological Features in AD.

Brain Region-Dependent Alternative Splicing of Alzheimer Disease (AD)-Risk Genes Is Associated With Neuropathological Features in AD.

Brain Region-Dependent Alternative Splicing of Alzheimer Disease (AD)-Risk Genes Is Associated With Neuropathological Features in AD.

Purpose: Alzheimer disease (AD) is one of the most complex diseases and is characterized by AD-related neuropathological features, including accumulation of amyloid-β plaques and tau neurofibrillary tangles. Dysregulation of alternative splicing (AS) contributes to these features, and there is heterogeneity in features across brain regions between AD patients, leading to different severity and progression rates; however, brain region-specific AS mechanisms still remain unclear. Therefore, we aimed to systemically investigate AS in multiple brain regions of AD patients and how they affect clinical features.

Methods: We analyzed RNA sequencing (RNA-Seq) data obtained from brain regions (frontal and temporal) of AD patients. Reads were mapped to the hg19 reference genome using the STAR aligner, and exon skipping (ES) rates were estimated as percent spliced in (PSI) by rMATs. We focused on AD-risk genes discovered by genome-wide association studies, and accordingly evaluated associations between PSI of skipped exons in AD-risk genes and Braak stage and plaque density mean (PM) for each brain region. We also integrated whole-genome sequencing data of the ascertained samples with RNA-Seq data to identify genetic regulators of feature-associated ES.

Results: We identified 26 and 41 ES associated with Braak stage in frontal and temporal regions, respectively, and 10 and 50 ES associated with PM. Among those, 10 were frontal-specific (CLU and NTRK2), 65 temporal-specific (HIF1A and TRPC4AP), and 26 shared ES (APP) that accompanied functional Gene Ontology terms, including axonogenesis in shared-ES genes. We further identified genetic regulators that account for 44 ES (44% of the total). Finally, we present as a case study the systematic regulation of an ES in APP, which is important in AD pathogenesis.

Conclusion: This study provides new insights into brain region-dependent AS regulation of the architecture of AD-risk genes that contributes to AD pathologies, ultimately allowing identification of a treatment target and region-specific biomarkers for AD.

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来源期刊
International Neurourology Journal
International Neurourology Journal UROLOGY & NEPHROLOGY-
CiteScore
4.40
自引率
21.70%
发文量
41
审稿时长
4 weeks
期刊介绍: The International Neurourology Journal (Int Neurourol J, INJ) is a quarterly international journal that publishes high-quality research papers that provide the most significant and promising achievements in the fields of clinical neurourology and fundamental science. Specifically, fundamental science includes the most influential research papers from all fields of science and technology, revolutionizing what physicians and researchers practicing the art of neurourology worldwide know. Thus, we welcome valuable basic research articles to introduce cutting-edge translational research of fundamental sciences to clinical neurourology. In the editorials, urologists will present their perspectives on these articles. The original mission statement of the INJ was published on October 12, 1997. INJ provides authors a fast review of their work and makes a decision in an average of three to four weeks of receiving submissions. If accepted, articles are posted online in fully citable form. Supplementary issues will be published interim to quarterlies, as necessary, to fully allow berth to accept and publish relevant articles.
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