Huntington's disease iPSC models-using human patient cells to understand the pathology caused by expanded CAG repeats.

Faculty reviews Pub Date : 2022-01-01 DOI:10.12703/r/11-16
Julia Kaye, Terry Reisine, Steven Finkbeiner
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引用次数: 3

Abstract

A major advance in the study of Huntington's disease (HD) has been the development of human disease models employing induced pluripotent stem cells (iPSCs) derived from patients with HD. Because iPSCs provide an unlimited source of cells and can be obtained from large numbers of HD patients, they are a uniquely valuable tool for investigating disease mechanisms and for discovering potential disease-modifying therapeutics. Here, we summarize some of the important findings in HD pathophysiology that have emerged from studies of patient-derived iPSC lines. Because they retain the genome and actual disease mutations of the patient, they provide a cell source to investigate genetic contributions to the disease. iPSCs provide advantages over other disease models. While iPSC-based technology erases some epigenetic marks, newly developed transdifferentiation methods now let us investigate epigenetic factors that control expression of mutant huntingtin (mHTT). Human HD iPSC lines allow us to investigate how endogenous levels of mHTT affect cell health, in contrast to other models that often rely on overexpressing the protein. iPSCs can be differentiated into neurons and other disease-related cells such as astrocytes from different brain regions to study brain regional differences in the disease process, as well as the cell-cell dependencies involved in HD-associated neurodegeneration. They also serve as a tissue source to investigate factors that impact CAG repeat instability, which is involved in regional differences in neurodegeneration in the HD brain. Human iPSC models can serve as a powerful model system to identify genetic modifiers that may impact disease onset, progression, and symptomatology, providing novel molecular targets for drug discovery.

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亨廷顿氏病iPSC模型-使用人类患者细胞了解扩增CAG重复引起的病理。
亨廷顿舞蹈病(HD)研究的一个重大进展是利用来自亨廷顿舞蹈病患者的诱导多能干细胞(iPSCs)建立人类疾病模型。由于iPSCs提供了无限的细胞来源,并且可以从大量HD患者中获得,因此它们是研究疾病机制和发现潜在疾病改善疗法的独特有价值的工具。在这里,我们总结了从患者来源的iPSC系研究中出现的HD病理生理学的一些重要发现。因为它们保留了患者的基因组和实际的疾病突变,它们提供了一个细胞来源来研究遗传对疾病的贡献。与其他疾病模型相比,iPSCs具有优势。虽然基于ipsc的技术抹去了一些表观遗传标记,但新开发的转分化方法现在让我们研究控制突变亨廷顿蛋白(mHTT)表达的表观遗传因素。人类HD iPSC细胞系使我们能够研究内源性mHTT水平如何影响细胞健康,这与其他通常依赖于过表达该蛋白的模型形成了对比。iPSCs可以分化为神经元和其他疾病相关细胞,如来自大脑不同区域的星形胶质细胞,以研究疾病过程中的大脑区域差异,以及hd相关神经变性所涉及的细胞-细胞依赖性。它们也可以作为组织来源来研究影响CAG重复不稳定性的因素,CAG重复不稳定性与HD大脑神经退行性变的区域差异有关。人类iPSC模型可以作为一个强大的模型系统来识别可能影响疾病发病、进展和症状的遗传修饰因子,为药物发现提供新的分子靶点。
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