Neuroscience Research laboratory, National Neuroscience Institute, Duke NUS Medical School, Singapore.
Department of Neurology, Singapore General Hospital, Singapore.
Neuroscientist. 2020 Apr;26(2):170-184. doi: 10.1177/1073858419871214. Epub 2019 Sep 16.
mutations have been identified in various neurological diseases such as Parkinson's disease (PD), frontotemporal dementia (FTD), and Alzheimer's disease (AD). It is also the first mitochondrial gene whose mutations lead to PD. CHCHD10 is a homolog of CHCHD2; similar to CHCHD2, various mutations of CHCHD10 have been identified in a broad spectrum of neurological disorders, including FTD and AD, with a high frequency of CHCHD10 mutations found in motor neuron diseases. Functionally, CHCHD2 and CHCHD10 have been demonstrated to interact with each other in mitochondria. Recent studies link the biological functions of CHCHD2 to the MICOS complex (mitochondrial inner membrane organizing system). Multiple experimental models suggest that CHCHD2 maintains mitochondrial cristae and disease-associated CHCHD2 mutations function in a loss-of-function manner. However, both CHCHD2 and CHCHD10 knockout mouse models appear phenotypically normal, with no obvious mitochondrial defects. Strategies to maintain or enhance mitochondria cristae could provide opportunities to correct the associated cellular defects in disease state and unravel potential novel targets for CHCHD2-linked neurological conditions.
已经在各种神经疾病中鉴定出突变,如帕金森病 (PD)、额颞叶痴呆 (FTD) 和阿尔茨海默病 (AD)。它也是第一个其突变导致 PD 的线粒体基因。CHCHD10 是 CHCHD2 的同源物;与 CHCHD2 类似,在广泛的神经疾病中已鉴定出各种 CHCHD10 突变,在运动神经元疾病中发现 CHCHD10 突变的频率很高。功能上,CHCHD2 和 CHCHD10 已被证明在线粒体中相互作用。最近的研究将 CHCHD2 的生物学功能与 MICOS 复合物 (线粒体内膜组织系统) 联系起来。多个实验模型表明,CHCHD2 维持线粒体嵴,与疾病相关的 CHCHD2 突变以功能丧失的方式发挥作用。然而,CHCHD2 和 CHCHD10 敲除小鼠模型均表现出表型正常,没有明显的线粒体缺陷。维持或增强线粒体嵴的策略可能为纠正疾病状态下相关的细胞缺陷提供机会,并揭示 CHCHD2 相关神经疾病的潜在新靶点。
