Mitochondrial DNA Heteroplasmy and Purifying Selection in the Mammalian Female Germ Line

Inherited mutations in the mitochondrial (mt)DNA are a major cause of human disease, with approximately 1 in 5000 people affected by one of the hundreds of identified pathogenic mtDNA point mutations or deletions. Due to the severe, and often untreatable, symptoms of many mitochondrial diseases, identifying how these mutations are inherited from one generation to the next has been an area of intense research in recent years. Despite large advances in our understanding of this complex process, many questions remain unanswered, with one of the most hotly debated being whether or not purifying selection acts against pathogenic mutations during germline development.     

Mitochondrial DNA Purifying Selection in Mammals and Invertebrates

Numerous mitochondrial quality control mechanisms exist within cells, but none have been shown to effectively assess and control the quality of mitochondrial DNA (mtDNA). One reason such mechanisms have yet to be elucidated is that they do not appear to be particularly active in most somatic cells, where many studies are conducted. The female germline, the cell lineage that gives rise to eggs, appears to be an exception. In the germline, strong purifying selection pathways act to eliminate deleterious mtDNA. These pathways have apparently evolved to prevent pathogenic mtDNA mutations from accumulating over successive generations and causing a decline of species via Muller's ratchet. Despite their fundamental biological importance, the mechanisms underlying purifying selection remain poorly understood, with no genes involved in this process yet identified. In this review, we discuss recent studies exploring mechanisms of germline mtDNA purifying selection in both mammalian and invertebrate systems. We also discuss the challenges to future major advances. Understanding the molecular basis of purifying selection is not only a fundamental outstanding question in biology, but may also pave the way to controlling selection in somatic tissues, potentially leading to treatments for people suffering from mitochondrial diseases.     

蕨类植物rbcL基因正选择和负选择位点的鉴定

基于分支模型、位点模型及分支-位点模型对蕨类的rbcL基因所受到的选择压力进行了分析.结果显示:分支模型下检测到大部分分支处于负选择,仅4个分支处于正选择压力下,并且仅2分支具有统计上的显著性;在位点模型下,通过比较模型M1a/M2a和M7/M8,在氨基酸水平上模型M2a和模型M8均鉴定出98L位点被正选择;在模型M8下,鉴定负向选择位点共228个,占总序列的83.82%,从而揭示出负选择对rbcL基因的进化起着非常重要的作用;在分支位点-模型c下鉴定出262A被正选择.98L、262A位点分别位于rbcL羧基末端α/β桶结构域的第3和第8个α螺旋上.蕨类通过该结构域的适应性进化,适应白垩纪被子植物兴起而引发的陆地生态系统改变,研究结果为以后实验分析提供了首选位点.     

Correcting for Purifying Selection: An Improved Human Mitochondrial Molecular Clock

There is currently no calibration available for the whole human mtDNA genome, incorporating both coding and control regions. Furthermore, as several authors have pointed out recently, linear molecular clocks that incorporate selectable characters are in any case problematic. We here confirm a modest effect of purifying selection on the mtDNA coding region and propose an improved molecular clock for dating human mtDNA, based on a worldwide phylogeny of > 2000 complete mtDNA genomes and calibrating against recent evidence for the divergence time of humans and chimpanzees. We focus on a time-dependent mutation rate based on the entire mtDNA genome and supported by a neutral clock based on synonymous mutations alone. We show that the corrected rate is further corroborated by archaeological dating for the settlement of the Canary Islands and Remote Oceania and also, given certain phylogeographic assumptions, by the timing of the first modern human settlement of Europe and resettlement after the Last Glacial Maximum. The corrected rate yields an age of modern human expansion in the Americas at ∼15 kya that—unlike the uncorrected clock—matches the archaeological evidence, but continues to indicate an out-of-Africa dispersal at around 55–70 kya, 5–20 ky before any clear archaeological record, suggesting the need for archaeological research efforts focusing on this time window. We also present improved rates for the mtDNA control region, and the first comprehensive estimates of positional mutation rates for human mtDNA, which are essential for defining mutation models in phylogenetic analyses.     

Comparison of Mitochondrial Mutation Spectra in Ageing Human Colonic Epithelium and Disease: Absence of Evidence for Purifying Selection in Somatic Mitochondrial DNA Point Mutations

Human ageing has been predicted to be caused by the accumulation of molecular damage in cells and tissues. Somatic mitochondrial DNA (mtDNA) mutations have been documented in a number of ageing tissues and have been shown to be associated with cellular mitochondrial dysfunction. It is unknown whether there are selective constraints, which have been shown to occur in the germline, on the occurrence and expansion of these mtDNA mutations within individual somatic cells. Here we compared the pattern and spectrum of mutations observed in ageing human colon to those observed in the general population (germline variants) and those associated with primary mtDNA disease. The pathogenicity of the protein encoding mutations was predicted using a computational programme, MutPred, and the scores obtained for the three groups compared. We show that the mutations associated with ageing are randomly distributed throughout the genome, are more frequently non-synonymous or frameshift mutations than the general population, and are significantly more pathogenic than population variants. Mutations associated with primary mtDNA disease were significantly more pathogenic than ageing or population mutations. These data provide little evidence for any selective constraints on the occurrence and expansion of mtDNA mutations in somatic cells of the human colon during human ageing in contrast to germline mutations seen in the general population.     

Strong Purifying Selection on the Odysseus Gene in Two Clades of Sibling Species of the Drosophila montium Species Subgroup

The Odysseus (OdsH) gene was duplicated from its ancestral neuron-expressed gene, unc-4, and then evolved very rapidly under strong positive Darwinian selection as a speciation gene causing hybrid-male sterility between closely related species of the Drosophila simulans clade. Has OdsH also experienced similar positive selection between Drosophila sibling species other than those of the simulans clade? We cloned and sequenced OdsH and unc-4 from two clades of the Drosophila montium species subgroup, the Drosophila lini and the Drosophila kikkawai clades. The ratios of Ka/Ks for OdsH were remarkably low between sibling species of these two clades, suggesting that OdsH has been subjected to strong purifying selection in these two clades.     

猕猴属五个种mtDNA多态性研究

本文以10种限制性内切酶研究猕猴属5个种(Macaca mulatta.M.nemestrina.M.assemensis.M.thibetana,M arctoides)线粒体DNA进化。在13个个体中,共检出8种限制性类型。恒河猴种内存在广泛的线粒休DNA限制性片段长度多态性(RFLP)。结合日本猴(M.fuscata)的有关资料,构建了猕猴属6个种的分子系统树,并给出各个种的分化时间。结果表明,这6个种可分成4个类群,熊猴和藏酋猴、恒河猴和日本猴之间的遗传距离较近,可分别划为同一类群,红面猴与其他5种猴的遗传距离最远,在系统发生上分离最早。     

Mitochondrial DNA Polymorphism in Natural Populations of the Drosophila virilis Species Group

Restriction fragment length polymorphism (RFLP) analysis has been used to evaluate mitochondrial DNA (mtDNA) variation in 12 sibling species forming the Drosophila virilis species group. The variation thresholds corresponding to the interspecific and interstrain levels have been determined. The results indicate that interspecific hybridization has significantly contributed to the evolutionary history of the virilis species group.     

An Evolutionary Footprint of Age-Related Natural Selection in Mitochondrial DNA

By comparing mtDNA sequences between different orders of mammals, we show that both longevity and generation time are significantly correlated with the nucleotide content of the mtDNA. Specifically, there is a positive correlation between generation time and mt GC content. This correlation is repeated, at a finer evolutionary scale, within the primates. Moreover, a comparison of human and chimpanzee mtDNAs shows that the effect has been very pronounced during the short evolutionary period since the divergence of these two species, with human mtDNA showing a GC-biased pattern of substitution at the variable sites. In addition to these DNA sequence patterns, comparisons between the human and the chimp mt protein sequences also revealed a surprisingly high substitution rate for threonine residues, resulting in a reduction of threonine in the human mt proteome. These patterns of both DNA and protein evolution can be explained by a balance between AT-biased mutational pressure and age-related purifying selection.     

南方鲇肝脏线粒体DNA的简便分离纯化方法

摸索出可消除南方鲇肝脏ｍｔＤＮＡ制备中出现的白色干扰物的方法,采用该方法处理后的ｍｔＤＮＡ可用于限制性分析。     

Reassociation Kinetics for Epstein-Barr Virus DNA: Nonhomology to Mammalian DNA and Homology of Viral DNA in Various Diseases

The number of Epstein-Barr virus (EBV) genomes per cell in established leukocytic lines and tissue specimens has been evaluated by measuring DNA-DNA reassociation kinetics with hydroxyapatite chromatography. Under the proper conditions, this method is sufficiently sensitive to detect EBV DNA in the amount of 0.1 genome per cell. All the samples tested that have been suspected to be without EBV DNA by cRNA hybridization proved negative by this more sensitive specific analysis. These included Hela and Hep2 cells, a negative case of Burkitt's lymphoma, two negative cases of nasopharyngeal carcinoma, and two established human leukocytic lines. Homology tests conducted with single-strand-specific nuclease S1 indicated that the viral DNA from a nasopharyngeal carcinoma and infectious mononucleosis were more than 90% homologous to EBV DNA.     

Mitochondrial DNA Variation Follows a Geographic Pattern in Japanese Beech Species

The amount and distribution of mitochondrial (mt) DNA restriction fragment length polymorphism was determined among individual tree samples of two Japanese beech species, Fagus crenata and F.japonica. Individual plants were collected from 16 F. crenata populations throughout the range of the species, and from three F. japonica populations. We detected enough variation to characterize eleven and three chondriome types in F. crenata and F.japonica, respectively. The grouping of beech chondriome types based upon the cladistic analysis of mtDNA polymorphism allowed us to recognize the apparent geographical patterns of mtDIMA diversity: the resulting three main groups occupied distinct geographic areas. This geographic differentiation is likely to reflect the history of the Japanese beech forests after the last glacial period of the Pleistocene. In addition, the mtDNA polymorphism encountered within F. crenata encompassed all the variation observed in F.japonica. Our result suggests the need for re-evaluation of their phylogenetic relationships.     

Mitochondrial DNA Sequence Divergence among Lycopersicon and Related Solanum Species

Sequence divergence among the mitochondrial (mt) DNA of nine Lycopersicon and two closely related Solanum species was estimated using the shared fragment method. A portion of each mt genome was highlighted by probing total DNA with a series of plasmid clones containing mt-specific DNA fragments from Lycopersicon pennellii. A total of 660 fragments were compared. As calculated by the shared fragment method, sequence divergence among the mtDNAs ranged from 0.4% for the L. esculentum-L. esculentum var. cerasiforme pair to 2.7% for the Solanum rickii-L. pimpinellifolium and L. cheesmanii-L. chilense pairs. The mtDNA divergence is higher than that reported for Lycopersicon chloroplast (cp) DNA, which indicates that the DNAs of the two plant organelles are evolving at different rates. The percentages of shared fragments were used to construct a phenogram that illustrates the present-day relationships of the mtDNAs. The mtDNA-derived phenogram places L. hirsutum closer to L. esculentum than taxonomic and cpDNA comparisons. Further, the recent assignment of L. pennellii to the genus Lycopersicon is supported by the mtDNA analysis.     

Mammalian Mitochondrial DNA Replication Intermediates Are Essentially Duplex but Contain Extensive Tracts of RNA/DNA Hybrid

We demonstrate, using transmission electron microscopy and immunopurification with an antibody specific for RNA/DNA hybrid, that intact mitochondrial DNA replication intermediates are essentially duplex throughout their length but contain extensive RNA tracts on one strand. However, the extent of preservation of RNA in such molecules is highly dependent on the preparative method used. These findings strongly support the strand-coupled model of mitochondrial DNA replication involving RNA incorporation throughout the lagging strand.     

Nucleotide Substitution Rate of Mammalian Mitochondrial Genomes

We present here for the first time a comprehensive study based on the analysis of closely related organisms to provide an accurate determination of the nucleotide substitution rate in mammalian mitochondrial genomes. This study examines the evolutionary pattern of the different functional mtDNA regions as accurately as possible on the grounds of available data, revealing some important ``genomic laws.' The main conclusions can be summarized as follows. (1) High intragenomic variability in the evolutionary dynamic of mtDNA was found. The substitution rate is strongly dependent on the region considered, and slow- and fast-evolving regions can be identified. Nonsynonymous sites, the D-loop central domain, and tRNA and rRNA genes evolve much more slowly than synonymous sites and the two peripheral D-loop region domains. The synonymous rate is fairly uniform over the genome, whereas the rate of nonsynonymous sites depends on functional constraints and therefore differs considerably between genes. (2) The commonly accepted statement that mtDNA evolves more rapidly than nuclear DNA is valid only for some regions, thus it should be referred to specific mitochondrial components. In particular, nonsynonymous sites show comparable rates in mitochondrial and nuclear genes; synonymous sites and small rRNA evolve about 20 times more rapidly and tRNAs about 100 times more rapidly in mitochondria than in their nuclear counterpart. (3) A species-specific evolution is particularly evident in the D-loop region. As the divergence times of the organism pairs under consideration are known with sufficient accuracy, absolute nucleotide substitution rates are also provided. Received: 11 May 1998 / Accepted: 2 September 1998     

猫科动物DNA条形码及线粒体假基因对物种鉴定的影响

在多种动物类群中,基于线粒体细胞色素c氧化酶亚基Ⅰ(COⅠ)基因的DNA条形码是一种高效的物种鉴别手段,然而猫科Felidae动物中广泛存在的线粒体假基因可能影响DNA条形码的有效性。本研究共涉及猫科动物12属25种119个样本。采用3对条形码通用引物对6属11种29个猫科动物样本进行了扩增及测序。结果3个样本扩增失败,8个样本得到假基因,18个样本获得了条形码序列。结合另外93条猫科动物条形码序列(源自BOLD Systems),采用Kimura 2-parameter模型计算遗传距离,构建Neighbor-Joining(NJ)树。结果显示,遗传距离种内为0%~8.1%,平均0.8%;种间为1.4%~13.1%,平均8.7%;属间为8.2%~21.8%,平均15.1%。NJ树显示,除3个种外,其余物种均以极高的置信度(99%)形成单系分支。而假基因序列有些可以单独形成分支,有些夹杂在COⅠ序列形成的分支中,对物种鉴定产生干扰。     

Corresponding Mitochondrial DNA and Niche Divergence for Crested Newt Candidate Species

Genetic divergence of mitochondrial DNA does not necessarily correspond to reproductive isolation. However, if mitochondrial DNA lineages occupy separate segments of environmental space, this supports the notion of their evolutionary independence. We explore niche differentiation among three candidate species of crested newt (characterized by distinct mitochondrial DNA lineages) and interpret the results in the light of differences observed for recognized crested newt species. We quantify niche differences among all crested newt (candidate) species and test hypotheses regarding niche evolution, employing two ordination techniques (PCA-env and ENFA). Niche equivalency is rejected: all (candidate) species are found to occupy significantly different segments of environmental space. Furthermore, niche overlap values for the three candidate species are not significantly higher than those for the recognized species. As the three candidate crested newt species are, not only in terms of mitochondrial DNA genetic divergence, but also ecologically speaking, as diverged as the recognized crested newt species, our findings are in line with the hypothesis that they represent cryptic species. We address potential pitfalls of our methodology.     

Phylogenetic Relationships of 12 Penaeoidea Shrimp Species Deduced from Mitochondrial DNA Sequences

DNA sequences of an 847 bp fragment of mitochondrial cytochrome oxidase subunit I (COI) gene and a 514 bp fragment of 16s rRNA gene were determined to examine the phylogenetic relationships of 12 Penaeoidea shrimp species (Penaeus chinensis, Penaeus japonicus, Penaeus penicillatus, Penaeus vannamei, Penaeus canaliculatus, Trachypenaeus curvirostris, Metapenaeus affinis, Metapenaeus ensis, Metapenaeopsis barbata, Parapenaeus fissuroides, Parapenaeopsis hardiwickii, Solenocera crassicomis). Both fragments of the swimming crab Portunus trituberculaus chosen as the outgroup were also sequenced. Intraspecific sequence divergence of 0.24-1.2% in the COI gene was found in 5 species, while no intraspecific variation was observed in the 16s rRNA gene. Three phylogenetic trees based on the 1361 bp combined sequences of COI and 16s rRNA were concordant in indicating the following suggestions: (1) phylogenetic relationship of the 11 Penaeidae species based on our result support the opinion of Burkenroad (Burkenroad, M.D. (1983). Crustacean Issues 3:279-290) on the basis of morphological features; (2) it seems more reasonable to class Solenocera crassicorni in the family Penaeidae; (3) the fragment of the COI gene chosen here appears to be a good marker for speciation studies and population analysis in Crustaceans, while the 16s rRNA gene fragment here seems suitable for examining phylogenetic relationships at the species or genus levels in Crustaceans. Our time estimates suggest that Penaeus and Metapenaeus might have separated about 6.38 x 10(6)-7.98 x 10(6) years BP in the post-Miocene, and the species separation within Metapenaeus and Penaeus might occur 0.08 x 10(6)-0.4 x 10(6) years BP in the late Pleistocene.     

安徽麝线粒体DNA细胞色素b基因全长序列分析

自80年代安徽麝[Moschus (moschiferus/berezovskii)anhuiensis]被发现以来,其分类地位一直众说纷纭。在本研究中,我们对安徽麝模式皮张标本进行了线粒体DNA细胞色素b基因全长序列分析。研究结果表明,安徽麝同麝属中其他种的遗传分化已经相当明显.分子系统学的分析表明,安徽麝是一个单系群,它同麝属其他种的DNA序列差异已达到种间分化的程度。因此,线粒体DNA序列的证据支持将安徽麝列为麝属中一有效种（Moschus anhuiensis),而不是前人认为的原麝或林麝的亚种。