线粒体疾病与核基因-线粒体基因的表达调控

线粒体与疾病是当前生物医学领域最前沿之一。本文简单介绍线粒体生物医学的基础知识、线粒体疾病的遗传模式,综述了近年来在线粒体DNA（mtDNA）突变和疾病、核基因突变和疾病等领域的研究进展,着重阐明核基因（特别是核修饰基因）调控mtDNA突变致病表达的分子机制。     

A peep into mitochondrial disorder:multifaceted from mitochondrial DNAmutations to nuclear gene modulation

Mitochondrial genome is responsible for multiple human diseases in a maternal inherited pattern, yet phenotypes of patients in a same pedigree frequently vary largely. Genes involving in epigenetic modification, RNA processing, and other biological pathways, rather than “threshold effect” and environmental factors, provide more specific explanation to the aberrant phenotype. Thus, the double hit theory, mutations both in mitochondrial DNA and modifying genes aggravating the symptom, throws new light on mitochondrial dysfunction processes. In addition, mitochondrial retrograde signaling pathway that leads to reconfiguration of cell metabolism to adapt defects in mitochondria may as well play an active role. Here we review selected examples of modifier genes and mitochondrial retrograde signaling in mitochondrial disorders, which refine our understanding and will guide the rational design of clinical therapies.     

The expanding spectrum of nuclear gene mutations in mitochondrial disorders

Our understanding of the molecular basis of mitochondrial disorders has come primarily from the discovery of an expanding number of mutations of mtDNA. However, a variety of recent observations indicate that many syndromes are due to abnormalities in nuclear genes related to oxidative-phosphorylation (OXPHOS). Nuclear genes encode hundreds of proteins involved in mitochondrial OXPHOS. Nevertheless, the identification of these genes has proceeded at a much slower pace, compared with the discovery and characterization of mtDNA mutations. This scenario is rapidly changing, thanks to the discovery of several OXPHOS-related human genes, and to the identification of mutations responsible for different clinical syndromes.     

Multiple mitochondrial tRNAMLeu[UUR] mutations associated with infantile myopathy

We have identified a cluster of mitochondrial tRNA^Leu[UUR], mutations in a severe case of infantile myopathy. There were A to G transitions found at mtDNA positions 3259, 3261, 3266 and 3268. These point mutations change the anticodon arm and the anticodon UAA, normally found in tRNA^Leu[UUR], to UGA which is the one of the tRNAs^Ser[UCN]. This is the first anticodon alteration described in this tRNA. Another swap straight to the anticodon of tRNA^Pro alone was recently described in a less severe case [1]. Until now infantile myopathies have not been attributed to defined mtDNA alterations. This study reports for the first time mtDNA point mutations causing this early onset of a mitochondrial disorder. The apparent homoplasmy of these mutations and especially the location in the anticodon must be considered lethal, if the child would not have been respirated for 5 years from its birth. (Mol Cell Biochem 174: 231–236, 1997)     

Taxonomy, evolutionary history and biogeography of the broad-toothed field mouse (Apodemus mystacinus) in the eastern Mediterranean area based on mitochondrial and nuclear genes

The broad-toothed field mouse ( Apodemus mystacinus ) is distributed throughout the Balkan Peninsula, Asia Minor and the Middle East. It is generally split into two different specific entities: Apodemus epimelas occurs on the Balkan Peninsula and A. mystacinus inhabits Asia Minor and the Middle East. This analysis, based on two mitochondrial regions (cytochrome b and the D-loop) and the interstitial retinol binding protein (IRBP) nuclear gene, confirms an important level of genetic divergence between the animals from these regions and their separation from each other at least 4.2–5.1 Mya, which is in favour of a distinct specific status. Finally, the broad-toothed field mice from south-western Turkey appear to be closely related to the animals from Crete but highly distinct from the populations of the other Oriental regions. This supports a distinct subspecific level ( A. m. rhodius ) for the insular animals and also for those from south-western Turkey. From a biogeographical point of view, it can be assumed that either late Pliocene or early Pleistocene cooling led to the isolation of two main groups of A. mystacinus , one in the Balkan region and the other one in Turkey and the Near East (Syria and Israel). In this region, it is suggested that a more recent event appeared during the Quaternary period, isolating broad-toothed field mice in Crete and leading to the appearance of two well-differentiated genetic groups: one in Crete and south-western Turkey, and the other widespread in northern and eastern Turkey as well as in the Near East.  © 2005 The Linnean Society of London, Biological Journal of the Linnean Society , 2005, 85 , 53–63.     

核、质基因对肺形侧耳菌丝生长、营养成分及基因表达的影响

本研究通过杂交构建肺形侧耳同核异质菌株N1M1、N1M2和同质异核菌株N1M1、N2M1,比较菌丝形态与生长速度、营养成分以及常见的细胞核基因与线粒体基因的表达量,分析线粒体基因对肺形侧耳菌丝的影响,探讨线粒体基因与核基因的相互作用。由菌丝生长情况可知N1M1和N1M2菌丝形态相似,生长速度差异不显著,N1M1和N2M1菌丝形态差异大,生长速度差异极显著,在菌丝形态与生长速度上细胞核基因作用大于线粒体基因。进一步检测菌株中的主要营养成分发现必需氨基酸与总水解氨基酸含量差异显著,菌株N1M2蛋白含量显著高于N1M1,N1M1维生素C含量是N1M2的1.67倍,菌株N2M1多糖和蛋白含量显著高于N1M1,铁和维生素C含量显著低于N1M1。所以细胞核基因、线粒体基因都能影响肺形侧耳营养成分含量。检测同核异质菌株N1M1、N1M2的7个细胞核常见基因的表达情况发现,N1M2菌丝中6个细胞核基因的表达量都显著高于N1M1,这表明肺形侧耳线粒体基因的不同会影响核基因的表达;同质异核菌株N1M1、N2M1的14个线粒体普通编码蛋白基因表达差异显著,这说明线粒体基因的表达量会因核基因的不同有所差异。综上,肺形侧耳线粒体基因和细胞核基因能够相互影响,共同作用于生命活动。     

高血压相关的线粒体DNA突变

线粒体DNA(mtDNA)突变是高血压发病的分子机制之一。已经报道的与原发性高血压相关的mtDNA突变包括:tRNAMet A4435G,tRNAMet/tRNAGln A4401G,tRNAIle A4263G,T4291C和A4295G突变。这些高血压相关的mtDNA突变改变了相应的线粒体tRNA的结构,导致线粒体tRNA的代谢障碍。而线粒体tRNAs的代谢缺陷则影响蛋白质合成,造成氧化磷酸化缺陷,降低ATP的合成,增加活性氧的产生。因此,线粒体的功能缺陷可能在高血压的发生发展中起一定的作用。mtDNA突变发病的组织特异性则可能与线粒体tRNAs的代谢以及核修饰基因相关。目前发现的这些高血压相关的mtDNA突变则应该作为今后高血压诊断的遗传风险因子。高血压相关的线粒体功能缺陷的深入研究也将进一步诠释母系遗传高血压的分子致病机制,为高血压的预防、控制和治疗提供依据。文章对高血压相关的mtDNA突变进行了综述。     

Pathogenic mutations in antisense mitochondrial tRNAs

Pathogenic mutations in mitochondrial tRNAs are 6.5 times more frequent than in other mitochondrial genes. This suggests that tRNA mutations perturb more than one function. A potential additional tRNA gene function is that of templating for antisense tRNAs. Pathogenic mutations weaken cloverleaf secondary structures of sense tRNAs. Analyses here show similar effects for most antisense tRNAs, especially after adjusting for associations between sense and antisense cloverleaf stabilities. These results imply translational activity by antisense tRNAs. For sense tRNAs Ala and Ser UCN, pathogenicity associates as much with sense as with antisense cloverleaf formation. For tRNA Pro, pathogenicity seems associated only with antisense, not sense tRNA cloverleaf formation. Translational activity by antisense tRNAs is expected for the 11 antisense tRNAs processed by regular sense RNA maturation, those recognized by their cognate amino acid’s tRNA synthetase, and those forming relatively stable cloverleaves as compared to their sense counterpart. Most antisense tRNAs probably function routinely in translation and extend the tRNA pool (extension hypothesis); others do not (avoidance hypothesis). The greater the expected translational activity of an antisense tRNA, the more pathogenic mutations weaken its cloverleaf secondary structure. Some evidence for RNA interference, a more classical role for antisense tRNAs, exists only for tRNA Ser UCN. Mutation pathogenicity probably frequently results from a mixture of effects due to sense and antisense tRNA translational activity for many mitochondrial tRNAs. Genomic studies should routinely explore for translational activity by antisense tRNAs.     

Study of modifiers factors associated to mitochondrial mutations in individuals with hearing impairment

Hearing impairment is the most prevalent sensorial deficit in the general population. Congenital deafness occurs in about 1 in 1000 live births, of which approximately 50% has hereditary cause in development countries. Non-syndromic deafness can be caused by mutations in both nuclear and mitochondrial genes. Mutations in mtDNA have been associated with aminoglycoside-induced and non-syndromic deafness in many families worldwide. However, the nuclear background influences the phenotypic expression of these pathogenic mutations. Indeed, it has been proposed that nuclear modifier genes modulate the phenotypic manifestation of the mitochondrial A1555G mutation in the MTRNR1 gene. The both putative nuclear modifiers genes TRMU and MTO1 encoding a highly conserved mitochondrial related to tRNA modification. It has been hypothesizes that human TRMU and also MTO1 nuclear genes may modulate the phenotypic manifestation of deafness-associated mitochondrial mutations. The aim of this work was to elucidate the contribution of mitochondrial mutations, nuclear modifier genes mutations and aminoglycoside exposure in the deafness phenotype. Our findings suggest that the genetic background of individuals may play an important role in the pathogenesis of deafness-associated with mitochondrial mutation and aminoglycoside-induced.     

Evolutionary transfers of mitochondrial genes to the nucleus in the Populus lineage and coexpression of nuclear and mitochondrial Sdh4 genes

The transfer of mitochondrial genes to the nucleus is an ongoing evolutionary process in flowering plants. Evolutionarily recent gene transfers provide insights into the evolutionary dynamics of the process and the way in which transferred genes become functional in the nucleus. Genes that are present in the mitochondrion of some angiosperms but have been transferred to the nucleus in the Populus lineage were identified by searches of Populus sequence databases. Sequence analyses and expression experiments were used to characterize the transferred genes. Two succinate dehydrogenase genes and six mitochondrial ribosomal protein genes have been transferred to the nucleus in the Populus lineage and have become expressed. Three transferred genes have gained an N-terminal mitochondrial targeting presequence from other pre-existing genes and two of the transferred genes do not contain an N-terminal targeting presequence. Intact copies of the succinate dehydrogenase gene Sdh4 are present in both the mitochondrion and the nucleus. Both copies of Sdh4 are expressed in multiple organs of two Populus species and RNA editing occurs in the mitochondrial copy. These results provide a genome-wide perspective on mitochondrial genes that were transferred to the nucleus and became expressed, functional genes during the evolutionary history of Populus.     

The four subunits of mitochondrial respiratory complex II are encoded by multiple nuclear genes and targeted to mitochondria in Arabidopsis thaliana

Mitochondrial respiratory complex II contains four subunits: a flavoprotein (SDH1), an iron-sulphur subunit (SDH2) and two membrane anchor subunits (SDH3 and SDH4). We have found that in Arabidopsis thaliana SDH1 and SDH3 are encoded by two, and SDH4 by one nuclear genes, respectively. All these encoded polypeptides are found to be imported into isolated plant mitochondria. While both SDH1 proteins are highly conserved when compared to their counterparts in other organisms, SDH3 and SDH4 share little similarity with non-plant homologues. Expression of SDH1-1, SDH3 and SDH4 genes was detected in all tissues analysed, with the highest steady-state mRNA levels found in flowers and inflorescences. In contrast, the second SDH1 gene (SDH1-2) is expressed at a low level.     

Human TRMU encoding the mitochondrial 5-methylaminomethyl-2-thiouridylate-methyltransferase is a putative nuclear modifier gene for the phenotypic expression of the deafness-associated 12S rRNA mutations

Nuclear modifier genes have been proposed to modulate the phenotypic manifestation of human mitochondrial 12S rRNA A1491G mutation associated with deafness in many families world-wide. Here we identified and characterized the putative nuclear modifier gene TRMU encoding a highly conserved mitochondrial protein related to tRNA modification. A 1937bp TRMU cDNA has been isolated and the genomic organization of TRMU has been elucidated. The human TRMU gene containing 11 exons encodes a 421 residue protein with a strong homology to the TRMU-like proteins of bacteria and other homologs. TRMU is ubiquitously expressed in various tissues, but abundantly in tissues with high metabolic rates including heart, liver, kidney, and brain. Immunofluorescence analysis of human 143B cells expressing TRMU-GFP fusion protein demonstrated that the human Trmu localizes and functions in mitochondrion. Furthermore, we show that in families with the deafness-associated 12S rRNA A1491G mutation there is highly suggestive linkage and linkage disequilibrium between microsatellite markers adjacent to TRMU and the presence of deafness. These observations suggest that human TRMU may modulate the phenotypic manifestation of the deafness-associated mitochondrial 12S rRNA mutations.     

The biogeography of mitochondrial and nuclear discordance in animals

Combining nuclear (nuDNA) and mitochondrial DNA (mtDNA) markers has improved the power of molecular data to test phylogenetic and phylogeographic hypotheses and has highlighted the limitations of studies using only mtDNA markers. In fact, in the past decade, many conflicting geographic patterns between mitochondrial and nuclear genetic markers have been identified (i.e. mito-nuclear discordance). Our goals in this synthesis are to: (i) review known cases of mito-nuclear discordance in animal systems, (ii) to summarize the biogeographic patterns in each instance and (iii) to identify common drivers of discordance in various groups. In total, we identified 126 cases in animal systems with strong evidence of discordance between the biogeographic patterns obtained from mitochondrial DNA and those observed in the nuclear genome. In most cases, these patterns are attributed to adaptive introgression of mtDNA, demographic disparities and sex-biased asymmetries, with some studies also implicating hybrid zone movement, human introductions and Wolbachia infection in insects. We also discuss situations where divergent mtDNA clades seem to have arisen in the absence of geographic isolation. For those cases where foreign mtDNA haplotypes are found deep within the range of a second taxon, data suggest that those mtDNA haplotypes are more likely to be at a high frequency and are commonly driven by sex-biased asymmetries and/or adaptive introgression. In addition, we discuss the problems with inferring the processes causing discordance from biogeographic patterns that are common in many studies. In many cases, authors presented more than one explanation for discordant patterns in a given system, which indicates that likely more data are required. Ideally, to resolve this issue, we see important future work shifting focus from documenting the prevalence of mito-nuclear discordance towards testing hypotheses regarding the drivers of discordance. Indeed, there is great potential for certain cases of mitochondrial introgression to become important natural systems within which to test the effect of different mitochondrial genotypes on whole-animal phenotypes.     

Arsenic trioxide promotes mitochondrial DNA mutation and cell apoptosis in primary APL cells and NB4 cell line

This study aimed to investigate the effects of arsenic trioxide (As₂O₃) on the mitochondrial DNA (mtDNA) of acute promyelocytic leukemia (APL) cells. The NB4 cell line was treated with 2.0 μmol/L As₂O₃ in vitro, and the primary APL cells were treated with 2.0 μmol/L As₂O₃ in vitro and 0.16 mg kg⁻¹ d⁻¹ As₂O₃ in vivo. The mitochondrial DNA of all the cells above was amplified by PCR, directly sequenced and analyzed by Sequence Navigatore and Factura software. The apoptosis rates were assayed by flow cytometry. Mitochondrial DNA mutation in the D-loop region was found in NB4 and APL cells before As₂O₃ use, but the mutation spots were remarkably increased after As₂O₃ treatment, which was positively correlated to the rates of cellular apoptosis, the correlation coefficient: r _NB4-As2O3=0.973818, and r _APL-As2O3=0.934703. The mutation types include transition, transversion, codon insertion or deletion, and the mutation spots in all samples were not constant and regular. It is revealed that As₂O₃ aggravates mtDNA mutation in the D-loop region of acute promyelocytic leukemia cells both in vitro and in vivo. Mitochondrial DNA might be one of the targets of As₂O₃ in APL treatment.     

Latent mitochondrial DNA deletion mutations drive muscle fiber loss at old age

With age, somatically derived mitochondrial DNA (mtDNA) deletion mutations arise in many tissues and species. In skeletal muscle, deletion mutations clonally accumulate along the length of individual fibers. At high intrafiber abundances, these mutations disrupt individual cell respiration and are linked to the activation of apoptosis, intrafiber atrophy, breakage, and necrosis, contributing to fiber loss. This sequence of molecular and cellular events suggests a putative mechanism for the permanent loss of muscle fibers with age. To test whether mtDNA deletion mutation accumulation is a significant contributor to the fiber loss observed in aging muscle, we pharmacologically induced deletion mutation accumulation. We observed a 1200% increase in mtDNA deletion mutation‐containing electron transport chain‐deficient muscle fibers, an 18% decrease in muscle fiber number and 22% worsening of muscle mass loss. These data affirm the hypothesized role for mtDNA deletion mutation in the etiology of muscle fiber loss at old age.     

Long-term conservation of six duplicated structural genes in cephalopod mitochondrial genomes

The complete nucleotide sequences of the mitochondrial (mt) genomes of three cephalopods, Octopus vulgaris (Octopodiformes, Octopoda, Incirrata), Todarodes pacificus (Decapodiformes, Oegopsida, Ommastrephidae), and Watasenia scintillans (Decapodiformes, Oegopsida, Enoploteuthidae), were determined. These three mt genomes encode the standard set of metazoan mt genes. However, W. scintillans and T. pacificus mt genomes share duplications of the longest noncoding region, three cytochrome oxidase subunit genes and two ATP synthase subunit genes, and the tRNA(Asp) gene. Southern hybridization analysis of the W. scintillans mt genome shows that this single genome carries both duplicated regions. The near-identical sequence of the duplicates suggests that there are certain concerted evolutionary mechanisms, at least in cephalopod mitochondria. Molecular phylogenetic analyses of mt protein genes are suggestive, although not statistically significantly so, of a monophyletic relationship between W. scintillans and T. pacificus.     

Arsenic trioxide promotes mitochondrial DNA mutation and cell apoptosis in primary APL cells and NB4 cell lines

This study aimed to investigate the effects of arsenic trioxide(As2O3) on the mitochondrial DNA(mtDNA) of acute promyelocytic leukemia(APL) cells.The NB4 cell line was treated with 2.0 μmol/L As2O3 in vitro,and the primary APL cells were treated with 2.0 μmol/L As2O3 in vitro and 0.16 mg kg-1 d-1 As2O3 in vivo.The mitochondrial DNA of all the cells above was amplified by PCR,directly sequenced and analyzed by Sequence Navigatore and Factura software.The apoptosis rates were assayed by flow cytometry.Mitochondrial DNA mutation in the D-loop region was found in NB4 and APL cells before As2O3 use,but the mutation spots were remarkably increased after As2O3 treatment,which was positively correlated to the rates of cellular apoptosis,the correlation coefficient:rNB4-As2O3=0.973818,and rAPL-As2O3=0.934703.The mutation types include transition,transversion,codon insertion or deletion,and the mutation spots in all samples were not constant and regular.It is revealed that As2O3 aggravates mtDNA mutation in the D-loop region of acute promyelocytic leukemia cells both in vitro and in vivo.Mitochondrial DNA might be one of the targets of As2O3 in APL treatment.     

Nucleolar and mitochondrial morphology in bovine embryos reconstructed by nuclear transfer

The nucleolar and mitochondrial morphology of developing reconstructed bovine nuclear transfer (NT) embryos and stage-matched in vivo-produced control embryos were examined under the electron microscope. Each reconstructed embryo at the one-cell (n = 12), two-cell (n = 5), three-cell (n = 3), four-cell (n = 5), 5–8 cell (n = 5) and blastocyst (n = 3) stages was produced by fusion of a 16–32-cell-stage blatomere with an aged enucleated bovine oocyte. The normal and reconstructed embryos showed similar mitochondrial morphology. However, NT embryos produced several pleiomorphic forms not seen in controls, and were more heterogenous at early stages of development. Control embryos exhibited nucleolar features considered indicative of rRNA synthesis from the eight-cell stage onwards. In contrast, the NT embryos presented nucleoli with morphology consistent with rRNA synthesis in all embryos examined, except in the three-cell and in two of the five four-cell embryos. From this nucleolar morphology, it was concluded that nuclear reprogramming does not occur immediately following nuclear transfer, but occurs gradually over the first two or three cell cycles. © 1996 Wiley-Liss, Inc.     

Conflicting patterns of mitochondrial and nuclear DNA diversity in Phylloscopus warblers

Molecular variation is often used to infer the demographic history of species, but sometimes the complexity of species history can make such inference difficult. The willow warbler, Phylloscopus trochilus, shows substantially less geographical variation than the chiffchaff, Phylloscopus collybita, both in morphology and in mitochondrial DNA (mtDNA) divergence. We therefore predicted that the willow warbler should harbour less nuclear DNA diversity than the chiffchaff. We analysed sequence data obtained from multiple samples of willow warblers and chiffchaffs for the mtDNA cytochrome b gene and four nuclear genes. We confirmed that the mtDNA diversity among willow warblers is low (pi = 0.0021). Sequence data from three nuclear genes (CHD-Z, AFLP-WW1 and MC1R) not linked to the mitochondria demonstrated unexpectedly high nucleotide diversity (pi values of 0.0172, 0.0141 and 0.0038) in the willow warbler, on average higher than the nucleotide diversity for the chiffchaff (pi values of 0.0025, 0.0017 and 0.0139). In willow warblers, Tajima's D analyses showed that the mtDNA diversity, but not the nuclear DNA diversity, has been reduced relative to the neutral expectation of molecular evolution, suggesting the action of a selective sweep affecting the maternally inherited genes. The large nuclear diversity seen within willow warblers is not compatible with processes of neutral evolution occurring in a population with a constant population size, unless the long-term effective population size has been very large (N(e) > 10(6)). We suggest that the contrasting patterns of genetic diversity in the willow warbler may reflect a more complex evolutionary history, possibly including historical demographic fluctuations or historical male-biased introgression of nuclear genes from a differentiated population of Phylloscopus warblers.