无核增殖提示线粒体细胞(MitoCells)为原核细胞

Kazutoshi Nakano, T. Nakayama, Y. Shirato, N. Nakayama, E. Tachikawa, Kaori Sasaki, Mikako Tarashima, Kayoko Saito, M. Ōsawa
{"title":"无核增殖提示线粒体细胞(MitoCells)为原核细胞","authors":"Kazutoshi Nakano, T. Nakayama, Y. Shirato, N. Nakayama, E. Tachikawa, Kaori Sasaki, Mikako Tarashima, Kayoko Saito, M. Ōsawa","doi":"10.15761/IMM.1000267","DOIUrl":null,"url":null,"abstract":"It is widely believed that evolutionarily advanced cells require nuclei rich in DNA to proliferate, while mitochondria isolated from nuclei cannot proliferate. We have developed a novel stable cell line, designated “mitochondrial cells (MitoCells)”, maintaining active mitochondria, the majority of which lacked nuclei. MitoCells can be continuously generated in culture. Herein, we report proliferation studies of MitoCells. We found that the nuclear DNA-less (nDNA-less) MitoCells, which were sorted with flow cytometry and were filtrated with 1.2 μmeter and 3 μmeter isopore membrane filters, could exist and proliferate. We also confirmed that the sorted nDNA-less MitoCells had mitochondrial DNA(mtDNA) with T9176C mutation analysis and that the unsorted MitoCells had SURF-1 gene of nDNA. These results suggest that MitoCells could have prokaryotic nature with both mtDNA and nDNA. Introduction The eukaryotes, by definition and in contrast to prokaryotes, have a nucleus, which contains most of the cell’s DNA, enclosed by double layered membranes [1]. The prokaryotes have no nucleus and have few or no organelles. Eukaryotes must have a nucleus and mitochondria in order to exist and proliferate with some exceptions [2-4]. Mitochondria which are isolated from nuclei are believed to be unable to exist or proliferate [5,6]. It is hypothesized that most of the ancestral mitochondrial genome was transferred to the nucleus as the symbiotic relationship between eukaryotes and ancestral mitochondria developed [7-9]. The respiratory chain /oxidative phosphorylation system (OPHOS) has five complexes, the polypeptides of which are encoded by mitochondrial DNA (mtDNA) and/or nuclear DNA (nDNA): only 13 polypeptides are encoded by mtDNA: complex I has 7 polypeptides encoded by mtDNA, complex II none, complex III one, complex IV three and complex V two. All other polypeptides of mitochondria are encoded by nDNA. We reported a series of novel stable cell lines, designated “mitochondrial cells (MitoCells)”, derived from cybrids obtained by fusing mitochondria-less HeLa cells with platelets [10,11]. All MitoCells have active mitochondria. The majority of these MitoCells lack nuclei but have a small amount of DNA, while the minority (less than 3 percent) have the same amount of DNA as cells with nuclei (nDNA-rich). We have recently reported that the MitoCells can survive under anaerobic condition and they could produce energy employing an anaerobic metabolic pathway, maintaining the electron transport enzyme activities, but losing the activity of tricarboxylic acid (TCA) cycle by means of mitochondrial enzyme assay and Western blot analyses [12]. This report suggests that energy production of MitoCells is far from the original cybrid cells which are eukaryote, although the MitoCells have enough polypeptides encoded by mtDNA and nDNA for maintaining their lives. Although most MitoCells have no nuclei, they can be continuously generated in culture. Therefore, it is important to know the feature of the nuclear DNA-less (nDNAless) MitoCells, which do not possess nucleus. Herein, we assessed the proliferation study and mtDNA analysis of the nDNA-less MitoCells, Materials MitoCell lines were obtained by transformation of cybrids derived by fusing mitochondria-less HeLa cells with platelets from Leigh syndrome patients and controls. The MitoCells from patients with Leigh syndrome, a subtype of mitochondrial encephalomyopathy, contain a pathogenic point mutation, T9176C, in their mtDNA [1315]. Our cell lines #1 and #2 were derived from heteroplasmic T9176C mutant cybrids, while cell line #3 represents wild type homoplasmy from control cybrids. The methods for establishment and culture of cell lines were described in detail in previous subscripts [10,11]. Methods MitoCell proliferation analysis with flow cytometer Sorting of MitoCell by flow cytometry: Two samples were taken from each MitoCell line. After adding 1 μM SYTO Green (Syto 16) (Molecular Probes, Inc. Eugene OR), the samples were left standing for 15 minutes. SYTO Green is a fluorescent dye that stains nucleic acids even in live cells [15]. The samples were gated and sorted by flow cytometry (Epics ALTRATM HyperSortTM, Beckman Coulter Inc., Miami, FL). The SYTO Green intensity range of the nucleus was defined based on the control cybrid data. Culture of the sorted cells and cell count: The sorted MitoCells, (nDNA-less MitoCells) were cultured in fresh RPMI 1640 medium Correspondence to: Kazutoshi Nakano, MD, Nakano Children’s Clinic, Medical Center Kamifukuoka, Fujimino-shi, Saitama, Japan, E-mail: knakano2005@yahoo.co.jp","PeriodicalId":94322,"journal":{"name":"Integrative molecular medicine","volume":"19 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2017-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Proliferation without nuclei suggests mitochondrial cells (MitoCells) to be prokaryotic nature\",\"authors\":\"Kazutoshi Nakano, T. Nakayama, Y. Shirato, N. Nakayama, E. Tachikawa, Kaori Sasaki, Mikako Tarashima, Kayoko Saito, M. Ōsawa\",\"doi\":\"10.15761/IMM.1000267\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"It is widely believed that evolutionarily advanced cells require nuclei rich in DNA to proliferate, while mitochondria isolated from nuclei cannot proliferate. We have developed a novel stable cell line, designated “mitochondrial cells (MitoCells)”, maintaining active mitochondria, the majority of which lacked nuclei. MitoCells can be continuously generated in culture. Herein, we report proliferation studies of MitoCells. We found that the nuclear DNA-less (nDNA-less) MitoCells, which were sorted with flow cytometry and were filtrated with 1.2 μmeter and 3 μmeter isopore membrane filters, could exist and proliferate. We also confirmed that the sorted nDNA-less MitoCells had mitochondrial DNA(mtDNA) with T9176C mutation analysis and that the unsorted MitoCells had SURF-1 gene of nDNA. These results suggest that MitoCells could have prokaryotic nature with both mtDNA and nDNA. Introduction The eukaryotes, by definition and in contrast to prokaryotes, have a nucleus, which contains most of the cell’s DNA, enclosed by double layered membranes [1]. The prokaryotes have no nucleus and have few or no organelles. Eukaryotes must have a nucleus and mitochondria in order to exist and proliferate with some exceptions [2-4]. Mitochondria which are isolated from nuclei are believed to be unable to exist or proliferate [5,6]. It is hypothesized that most of the ancestral mitochondrial genome was transferred to the nucleus as the symbiotic relationship between eukaryotes and ancestral mitochondria developed [7-9]. The respiratory chain /oxidative phosphorylation system (OPHOS) has five complexes, the polypeptides of which are encoded by mitochondrial DNA (mtDNA) and/or nuclear DNA (nDNA): only 13 polypeptides are encoded by mtDNA: complex I has 7 polypeptides encoded by mtDNA, complex II none, complex III one, complex IV three and complex V two. All other polypeptides of mitochondria are encoded by nDNA. We reported a series of novel stable cell lines, designated “mitochondrial cells (MitoCells)”, derived from cybrids obtained by fusing mitochondria-less HeLa cells with platelets [10,11]. All MitoCells have active mitochondria. The majority of these MitoCells lack nuclei but have a small amount of DNA, while the minority (less than 3 percent) have the same amount of DNA as cells with nuclei (nDNA-rich). We have recently reported that the MitoCells can survive under anaerobic condition and they could produce energy employing an anaerobic metabolic pathway, maintaining the electron transport enzyme activities, but losing the activity of tricarboxylic acid (TCA) cycle by means of mitochondrial enzyme assay and Western blot analyses [12]. This report suggests that energy production of MitoCells is far from the original cybrid cells which are eukaryote, although the MitoCells have enough polypeptides encoded by mtDNA and nDNA for maintaining their lives. Although most MitoCells have no nuclei, they can be continuously generated in culture. Therefore, it is important to know the feature of the nuclear DNA-less (nDNAless) MitoCells, which do not possess nucleus. Herein, we assessed the proliferation study and mtDNA analysis of the nDNA-less MitoCells, Materials MitoCell lines were obtained by transformation of cybrids derived by fusing mitochondria-less HeLa cells with platelets from Leigh syndrome patients and controls. The MitoCells from patients with Leigh syndrome, a subtype of mitochondrial encephalomyopathy, contain a pathogenic point mutation, T9176C, in their mtDNA [1315]. Our cell lines #1 and #2 were derived from heteroplasmic T9176C mutant cybrids, while cell line #3 represents wild type homoplasmy from control cybrids. The methods for establishment and culture of cell lines were described in detail in previous subscripts [10,11]. Methods MitoCell proliferation analysis with flow cytometer Sorting of MitoCell by flow cytometry: Two samples were taken from each MitoCell line. After adding 1 μM SYTO Green (Syto 16) (Molecular Probes, Inc. Eugene OR), the samples were left standing for 15 minutes. SYTO Green is a fluorescent dye that stains nucleic acids even in live cells [15]. The samples were gated and sorted by flow cytometry (Epics ALTRATM HyperSortTM, Beckman Coulter Inc., Miami, FL). The SYTO Green intensity range of the nucleus was defined based on the control cybrid data. Culture of the sorted cells and cell count: The sorted MitoCells, (nDNA-less MitoCells) were cultured in fresh RPMI 1640 medium Correspondence to: Kazutoshi Nakano, MD, Nakano Children’s Clinic, Medical Center Kamifukuoka, Fujimino-shi, Saitama, Japan, E-mail: knakano2005@yahoo.co.jp\",\"PeriodicalId\":94322,\"journal\":{\"name\":\"Integrative molecular medicine\",\"volume\":\"19 1\",\"pages\":\"\"},\"PeriodicalIF\":0.0000,\"publicationDate\":\"2017-01-01\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"0\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"Integrative molecular medicine\",\"FirstCategoryId\":\"1085\",\"ListUrlMain\":\"https://doi.org/10.15761/IMM.1000267\",\"RegionNum\":0,\"RegionCategory\":null,\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"\",\"JCRName\":\"\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"Integrative molecular medicine","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.15761/IMM.1000267","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0

摘要

人们普遍认为,进化高级的细胞需要富含DNA的细胞核才能增殖,而从细胞核中分离出来的线粒体不能增殖。我们已经开发了一种新的稳定的细胞系,称为“线粒体细胞(MitoCells)”,保持活跃的线粒体,其中大多数缺乏细胞核。在培养中可以连续产生线粒体。在此,我们报告了线粒体的增殖研究。我们发现,流式细胞术分选后,用1.2 μm和3 μm等孔滤膜过滤后的细胞核无dna (nDNA-less)线粒体能够存在并增殖。我们还通过T9176C突变分析证实,排序后的nDNA-less MitoCells具有线粒体DNA(mtDNA),未排序的MitoCells具有nDNA的SURF-1基因。这些结果表明,线粒体可能具有原核性质,同时具有mtDNA和nDNA。根据定义,真核生物与原核生物不同,真核生物有一个由双层膜包裹的细胞核,细胞核包含细胞的大部分DNA[1]。原核生物没有细胞核,也很少或没有细胞器。真核生物必须有细胞核和线粒体才能生存和增殖,也有一些例外[2-4]。从细胞核中分离出来的线粒体被认为不能存在或增殖[5,6]。据推测,随着真核生物与祖先线粒体共生关系的发展,大部分祖先线粒体基因组被转移到细胞核中[7-9]。呼吸链/氧化磷酸化系统(OPHOS)有5个复合物,其多肽由线粒体DNA (mtDNA)和/或核DNA (nDNA)编码:只有13个多肽由mtDNA编码:复合物I有7个由mtDNA编码的多肽,复合物II没有,复合物III 1,复合物IV 3和复合物v2。线粒体的所有其他多肽都由nDNA编码。我们报道了一系列新的稳定细胞系,命名为“线粒体细胞(mitoccells)”,来源于无线粒体的HeLa细胞与血小板融合获得的细胞系[10,11]。所有的线粒体都有活跃的线粒体。这些线粒体大多数没有细胞核,但有少量的DNA,而少数(少于3%)具有相同数量的DNA与细胞核细胞(富含DNA)。我们最近报道了线粒体细胞可以在厌氧条件下存活,它们可以通过厌氧代谢途径产生能量,保持电子传递酶的活性,但通过线粒体酶测定和Western blot分析失去三羧酸(TCA)循环的活性[12]。这一报告表明,尽管线粒体细胞有足够的由mtDNA和nDNA编码的多肽来维持其生命,但线粒体细胞的能量产生与原始的真核混合细胞相差甚远。虽然大多数有丝分裂细胞没有细胞核,但它们可以在培养中连续产生。因此,了解无核dna (nDNAless)线粒体的特征是很重要的。在此,我们评估了无线粒体线粒体的线粒体细胞的增殖研究和mtDNA分析,材料通过将无线粒体的HeLa细胞与Leigh综合征患者和对照组的血小板融合得到的杂合体转化获得线粒体细胞系。Leigh综合征是线粒体脑肌病的一种亚型,Leigh综合征患者的线粒体dna中含有致病性点突变T9176C[1315]。我们的细胞系#1和#2来自异质T9176C突变细胞系,而细胞系#3代表来自对照细胞系的野生型同源性。细胞系的建立和培养方法在之前的下标中有详细的描述[10,11]。方法流式细胞仪分析线粒体增殖情况。流式细胞仪分选:每个线粒体细胞系取2个样本。加入1 μM SYTO Green (SYTO 16) (Molecular Probes, Inc.)Eugene OR),样品静置15分钟。SYTO Green是一种荧光染料,即使在活细胞中也能染色核酸[15]。通过流式细胞术(epicaltratm HyperSortTM, Beckman Coulter Inc., Miami, FL)对样品进行门控和分选。根据对照杂交数据确定了细胞核的SYTO Green强度范围。分选细胞的培养和细胞计数:分选的MitoCells (nDNA-less MitoCells)在新鲜的RPMI 1640培养基中培养。通讯:Kazutoshi Nakano, MD, Nakano Children 's Clinic, Medical Center Kamifukuoka, Fujimino-shi, Saitama, Japan, E-mail: knakano2005@yahoo.co.jp
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Proliferation without nuclei suggests mitochondrial cells (MitoCells) to be prokaryotic nature
It is widely believed that evolutionarily advanced cells require nuclei rich in DNA to proliferate, while mitochondria isolated from nuclei cannot proliferate. We have developed a novel stable cell line, designated “mitochondrial cells (MitoCells)”, maintaining active mitochondria, the majority of which lacked nuclei. MitoCells can be continuously generated in culture. Herein, we report proliferation studies of MitoCells. We found that the nuclear DNA-less (nDNA-less) MitoCells, which were sorted with flow cytometry and were filtrated with 1.2 μmeter and 3 μmeter isopore membrane filters, could exist and proliferate. We also confirmed that the sorted nDNA-less MitoCells had mitochondrial DNA(mtDNA) with T9176C mutation analysis and that the unsorted MitoCells had SURF-1 gene of nDNA. These results suggest that MitoCells could have prokaryotic nature with both mtDNA and nDNA. Introduction The eukaryotes, by definition and in contrast to prokaryotes, have a nucleus, which contains most of the cell’s DNA, enclosed by double layered membranes [1]. The prokaryotes have no nucleus and have few or no organelles. Eukaryotes must have a nucleus and mitochondria in order to exist and proliferate with some exceptions [2-4]. Mitochondria which are isolated from nuclei are believed to be unable to exist or proliferate [5,6]. It is hypothesized that most of the ancestral mitochondrial genome was transferred to the nucleus as the symbiotic relationship between eukaryotes and ancestral mitochondria developed [7-9]. The respiratory chain /oxidative phosphorylation system (OPHOS) has five complexes, the polypeptides of which are encoded by mitochondrial DNA (mtDNA) and/or nuclear DNA (nDNA): only 13 polypeptides are encoded by mtDNA: complex I has 7 polypeptides encoded by mtDNA, complex II none, complex III one, complex IV three and complex V two. All other polypeptides of mitochondria are encoded by nDNA. We reported a series of novel stable cell lines, designated “mitochondrial cells (MitoCells)”, derived from cybrids obtained by fusing mitochondria-less HeLa cells with platelets [10,11]. All MitoCells have active mitochondria. The majority of these MitoCells lack nuclei but have a small amount of DNA, while the minority (less than 3 percent) have the same amount of DNA as cells with nuclei (nDNA-rich). We have recently reported that the MitoCells can survive under anaerobic condition and they could produce energy employing an anaerobic metabolic pathway, maintaining the electron transport enzyme activities, but losing the activity of tricarboxylic acid (TCA) cycle by means of mitochondrial enzyme assay and Western blot analyses [12]. This report suggests that energy production of MitoCells is far from the original cybrid cells which are eukaryote, although the MitoCells have enough polypeptides encoded by mtDNA and nDNA for maintaining their lives. Although most MitoCells have no nuclei, they can be continuously generated in culture. Therefore, it is important to know the feature of the nuclear DNA-less (nDNAless) MitoCells, which do not possess nucleus. Herein, we assessed the proliferation study and mtDNA analysis of the nDNA-less MitoCells, Materials MitoCell lines were obtained by transformation of cybrids derived by fusing mitochondria-less HeLa cells with platelets from Leigh syndrome patients and controls. The MitoCells from patients with Leigh syndrome, a subtype of mitochondrial encephalomyopathy, contain a pathogenic point mutation, T9176C, in their mtDNA [1315]. Our cell lines #1 and #2 were derived from heteroplasmic T9176C mutant cybrids, while cell line #3 represents wild type homoplasmy from control cybrids. The methods for establishment and culture of cell lines were described in detail in previous subscripts [10,11]. Methods MitoCell proliferation analysis with flow cytometer Sorting of MitoCell by flow cytometry: Two samples were taken from each MitoCell line. After adding 1 μM SYTO Green (Syto 16) (Molecular Probes, Inc. Eugene OR), the samples were left standing for 15 minutes. SYTO Green is a fluorescent dye that stains nucleic acids even in live cells [15]. The samples were gated and sorted by flow cytometry (Epics ALTRATM HyperSortTM, Beckman Coulter Inc., Miami, FL). The SYTO Green intensity range of the nucleus was defined based on the control cybrid data. Culture of the sorted cells and cell count: The sorted MitoCells, (nDNA-less MitoCells) were cultured in fresh RPMI 1640 medium Correspondence to: Kazutoshi Nakano, MD, Nakano Children’s Clinic, Medical Center Kamifukuoka, Fujimino-shi, Saitama, Japan, E-mail: knakano2005@yahoo.co.jp
求助全文
通过发布文献求助,成功后即可免费获取论文全文。 去求助
来源期刊
自引率
0.00%
发文量
0
×
引用
GB/T 7714-2015
复制
MLA
复制
APA
复制
导出至
BibTeX EndNote RefMan NoteFirst NoteExpress
×
提示
您的信息不完整,为了账户安全,请先补充。
现在去补充
×
提示
您因"违规操作"
具体请查看互助需知
我知道了
×
提示
确定
请完成安全验证×
copy
已复制链接
快去分享给好友吧!
我知道了
右上角分享
点击右上角分享
0
联系我们:info@booksci.cn Book学术提供免费学术资源搜索服务,方便国内外学者检索中英文文献。致力于提供最便捷和优质的服务体验。 Copyright © 2023 布克学术 All rights reserved.
京ICP备2023020795号-1
ghs 京公网安备 11010802042870号
Book学术文献互助
Book学术文献互助群
群 号:481959085
Book学术官方微信