通过突触体与无线粒体DNA细胞融合在培养细胞中克隆神经元线粒体DNA变体。

Cloning of neuronal mtDNA variants in cultured cells by synaptosome fusion with mtDNA-less cells.

作者信息

Trounce I, Schmiedel J, Yen H C, Hosseini S, Brown M D, Olson J J, Wallace D C

机构信息

Center for Molecular Medicine, Emory University School of Medicine, Atlanta, GA 30329, USA.

出版信息

Nucleic Acids Res. 2000 May 15;28(10):2164-70. doi: 10.1093/nar/28.10.2164.

DOI:10.1093/nar/28.10.2164

PMID:10773087

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC105374/

Abstract

Synaptosome cybrids were used to confirm the presence of heteroplasmic mtDNA sequence variants in the human brain. Synaptosomes contain one to several mitochondria, and when fused to mtDNA-deficient (rho degrees ) mouse or human cell lines result in viable cybrid cell lines. The brain origin of mouse synaptosome cybrid mtDNAs was confirmed using sequence polymorphisms in the mtDNA COIII, ND3 and tRNA(Arg)genes. The brain origin of the human synaptosome cybrids was confirmed using a rare mtDNA Mbo I polymorphism. Fusion of synaptosomes from the brain of a 35-year-old woman resulted in 71 synaptosome cybrids. Sequencing the mtDNA control region of these cybrid clones revealed differences in the number of Cs in a poly C track between nucleotide pairs (nps) 301 and 309. Three percent of the cybrid clones had mtDNAs with 10 Cs, 76% had nine, 18% had eight and 3% had seven Cs. Comparable results were obtained by PCR amplification, cloning and sequencing of mtDNA control regions directly from the patient's brain tissue, but not when the control region was amplified and cloned from a synaptosome cybrid homoplasmic for a mtDNA with nine Cs. Thus, we have clonally recovered mtDNA control region length variants from an adult human brain without recourse to PCR, and established the variant mtDNAs within living cultured cells. This confirms that some mtDNA heteroplasmy can exist in human neurons, and provides the opportunity to study its functional significance.

摘要

突触体胞质杂种被用于确认人脑中异质性线粒体DNA序列变异的存在。突触体含有一到几个线粒体，当与线粒体DNA缺陷（ρ0）的小鼠或人类细胞系融合时，会产生有活力的胞质杂种细胞系。利用线粒体DNA COIII、ND3和tRNA（Arg）基因中的序列多态性，确认了小鼠突触体胞质杂种线粒体DNA的脑源性。利用一种罕见的线粒体DNA Mbo I多态性，确认了人类突触体胞质杂种的脑源性。来自一名35岁女性大脑的突触体融合产生了71个突触体胞质杂种。对这些胞质杂种克隆的线粒体DNA控制区进行测序，发现在核苷酸对（nps）301和309之间的多聚C序列中C的数量存在差异。3%的胞质杂种克隆的线粒体DNA有10个C，76%有9个，18%有8个，3%有7个C。通过直接从患者脑组织中进行线粒体DNA控制区的PCR扩增、克隆和测序也获得了类似结果，但从一个线粒体DNA有9个C的突触体胞质杂种纯质体中扩增和克隆控制区时则未得到类似结果。因此，我们无需借助PCR就从成人脑中克隆性地获得了线粒体DNA控制区长度变异，并在活的培养细胞中建立了变异的线粒体DNA。这证实了人类神经元中可以存在一些线粒体DNA异质性，并为研究其功能意义提供了机会。

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通过突触体与无线粒体DNA细胞融合在培养细胞中克隆神经元线粒体DNA变体。

Cloning of neuronal mtDNA variants in cultured cells by synaptosome fusion with mtDNA-less cells.

作者信息

Trounce I, Schmiedel J, Yen H C, Hosseini S, Brown M D, Olson J J, Wallace D C

机构信息

Center for Molecular Medicine, Emory University School of Medicine, Atlanta, GA 30329, USA.

出版信息

Nucleic Acids Res. 2000 May 15;28(10):2164-70. doi: 10.1093/nar/28.10.2164.

DOI:10.1093/nar/28.10.2164

PMID:10773087

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC105374/

Abstract

摘要

通过突触体与无线粒体DNA细胞融合在培养细胞中克隆神经元线粒体DNA变体。

Cloning of neuronal mtDNA variants in cultured cells by synaptosome fusion with mtDNA-less cells.

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通过突触体与无线粒体DNA细胞融合在培养细胞中克隆神经元线粒体DNA变体。

Cloning of neuronal mtDNA variants in cultured cells by synaptosome fusion with mtDNA-less cells.

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出版信息