线粒体表观遗传学研究进展

作为细胞内的"动力工厂",线粒体是细胞内进行氧化磷酸化反应和形成ATP的主要场所。传统观点曾认为线粒体缺乏表观遗传机制,但线粒体DNA甲基化酶以及线粒体DNA中5-甲基胞嘧啶与5-羟甲基胞嘧啶的发现推翻了这一论断。在线粒体中,DNA甲基化酶、DNA甲基化模式及DNA羟甲基化模式与核基因组DNA相比均存在较大差异,而外界环境中不同因子的变化也会对线粒体DNA的甲基化状态造成影响。除此之外,线粒体DNA的表观遗传因素还包括线粒体长链非编码RNA、线粒体mi RNA和线粒体DNA结合蛋白。随着研究技术手段的不断完善,将线粒体DNA的甲基化状态作为生物标记的应用将日益广泛,其与基因组表观遗传调控的关联也将得到进一步的揭示。     

线粒体DNA多态性在海洋动物群体遗传结构研究中的应用

线粒体DNA( mtDNA)分析在揭示物种亲缘关系、遗传比较、系统进化和遗传结构等领域的研究中得到了广泛的应用,尤其是在海洋动物的遗传结构研究中发挥了重要的作用.介绍线粒体DNA的结构特征、多态性研究方法,并对其在海洋动物群体遗传结构研究中的应用进行了综述.     

适于蛹虫草遗传多样性研究的线粒体分子标记的筛选

摘要:【目的】从蛹虫草线粒体DNA中寻找适于遗传多样性研究的分子标记。【方法】通过PCR扩增和序列分析,比较了20个蛹虫草菌株在12个线粒体DNA片段和3个细胞核DNA片段上的序列变异。【结果】蛹虫草在线粒体DNA上的变异水平高于核DNA,主要表现为线粒体基因内含子的插入缺失多样性和较多的碱基变异位点。不同线粒体DNA片段的变异水平也有差异,而且内含子蛋白比外显子编码的蛋白质更易发生氨基酸的改变。增加使用的分子标记数目,其所揭示的遗传多样性程度也在逐渐提高。【结论】我们依 次推荐nad3-cox2、cox2-nad5、cox2、cox3、cob和cox1这6个线粒体DNA位点用于今后蛹虫草遗传多样性或群体遗传结构的分析。     

DNA遗传标记在山羊遗传多样性研究上的应用

综述DNA遗传标记在山羊的遗传多样性分析上的应用,并分别叙述了RFLP、线粒体DNA多态性、RAID、微卫星标记、AFLP等几个方面目前在山羊上的研究。     

鱼类线粒体DNA研究新进展

线粒体DNA是分子生物学研究中的一个热门领域,已成为鱼类进化生物学和群体遗传学研究的重要分子遗传标记。本文对鱼类线粒体DNA分子生物学的最新研究进展进行了较详细的阐述。重点介绍鱼类线粒体DNA全序列的研究进展、组成及特征,鱼类线粒体DNA非编码区结构研究进展,鱼类线粒体DNA多态性及其主要的检测方法;综述了最近有关鱼类线粒体DNA在鱼类系统学、种间杂交渐渗、种群识别、起源和进化、地理分化等研究中的应用情况。     

植物叶绿体DNA与线粒体DNA的遗传变异

植物叶绿体和线粒体含有DNA,它们表现出不同的遗传变异特性。叶绿体基因组的保守性强,含有特征性重复顺序,它的遗传形式多样而以母系遗传为主,在组织培养和体细胞杂交中具有稳定性强,单亲遗传的特点。线粒体基因组变异性很强,含有主基因组和随体DNA,它的遗传形式是母系遗传,但在体细胞杂交中有时表现为双亲本遗传,并有mtDNA重组,mtDNA在组织培养中发生极大的变异性。在细胞核和线粒体、叶绿体之间存在DNA互相运动的现象。     

简析线粒体DNA异质性

线粒体DNA存在异质性,在医学、生物学等领域都有着广泛的应用。本文将着重介绍线粒体在体细胞突变、父系掺入以及杂交等自然情况下的产生机制及其遗传。     

蜜蜂线粒体DNA在遗传分析中的应用

线粒体DNA是动物细胞核外唯一的遗传物质,具有结构简单、进化速度快、母系遗传和基因重组率小等特点。文章在介绍蜜蜂线粒体DNA的结构大小及其多态性的研究的基础上,对其在蜜蜂的种间多态性、亚种间及亚种内多态性、起源进化、群体遗传结构及基因流动、亚种及类型的分类等方面的研究应用进行阐述。     

线粒体遗传

脱氧核糖核酸(DNA）是遗传物质,它以核普 酸的排列顺序形式携带遗传信息。DNA 能够 自我复制,并能将信息转录给信使核糖核酸 (inRNA),在核糖体和氨基酸转移RNA (tRNA) 的作用下,mRNA的密码被转译成蛋白质。这 样的遗传系统在真核生物细胞中存在有两种, 一种是细胞核DNA的遗传系统,这是人们熟知 的。除此之外,在线粒体等细胞器中也含有 DNA。这些细胞器DNA的信息也能独立进行 复制、转录和转译。因此,我们称这种细胞器 DNA为核外的遗传系统。线粒体里的DNA就 是一种核外的遗传系统。     

线粒体DNA序列特点与昆虫系统学研究

昆虫线粒体DNA是昆虫分子系统学研究中应用最为广泛的遗传物质之一。线粒体DNA具有进化速率较核DNA快 ,遗传过程不发生基因重组、倒位、易位等突变 ,并且遵守严格的母系遗传方式等特点。本文概述了mtDNA中的rRNA、tRNA、蛋白编码基因和非编码区的一般属性 ,分析了它们在昆虫分子系统学研究中的应用价值 ,以及应用DNA序列数据来推导分类阶 (单 )元的系统发育关系时 ,基因或DNA片段选择的重要性     

Defects in mitochondrial DNA replication and human disease

Mitochondrial DNA (mtDNA) is replicated by the DNA polymerase g in concert with accessory proteins such as the mtDNA helicase, single stranded DNA binding protein, topoisomerase, and initiating factors. Nucleotide precursors for mtDNA replication arise from the mitochondrial salvage pathway originating from transport of nucleosides, or alternatively from cytoplasmic reduction of ribonucleotides. Defects in mtDNA replication or nucleotide metabolism can cause mitochondrial genetic diseases due to mtDNA deletions, point mutations, or depletion which ultimately cause loss of oxidative phosphorylation. These genetic diseases include mtDNA depletion syndromes such as Alpers or early infantile hepatocerebral syndromes, and mtDNA deletion disorders, such as progressive external ophthalmoplegia (PEO), ataxia-neuropathy, or mitochondrial neurogastrointestinal encephalomyopathy (MNGIE). This review focuses on our current knowledge of genetic defects of mtDNA replication (POLG, POLG2, C10orf2) and nucleotide metabolism (TYMP, TK2, DGOUK, and RRM2B) that cause instability of mtDNA and mitochondrial disease.     

Defects in mitochondrial DNA replication and human disease

Mitochondrial DNA (mtDNA) is replicated by the DNA polymerase g in concert with accessory proteins such as the mtDNA helicase, single stranded DNA binding protein, topoisomerase, and initiating factors. Nucleotide precursors for mtDNA replication arise from the mitochondrial salvage pathway originating from transport of nucleosides, or alternatively from cytoplasmic reduction of ribonucleotides. Defects in mtDNA replication or nucleotide metabolism can cause mitochondrial genetic diseases due to mtDNA deletions, point mutations, or depletion which ultimately cause loss of oxidative phosphorylation. These genetic diseases include mtDNA depletion syndromes such as Alpers or early infantile hepatocerebral syndromes, and mtDNA deletion disorders, such as progressive external ophthalmoplegia (PEO), ataxia-neuropathy, or mitochondrial neurogastrointestinal encephalomyopathy (MNGIE). This review focuses on our current knowledge of genetic defects of mtDNA replication (POLG, POLG2, C10orf2) and nucleotide metabolism (TYMP, TK2, DGOUK, and RRM2B) that cause instability of mtDNA and mitochondrial disease.     

Inheritance of mitochondrial disorders

Over the last decade there have been major advances in our understanding of the genetic basis of mitochondrial disease, enabling genetic counseling for patients with autosomal dominant and autosomal recessive disorders. Genetic counseling for patients with mitochondrial DNA (mtDNA) mutations is less well established. Approximately one-third of adults with a mtDNA disorder are sporadic cases, usually due to a single deletion of mtDNA. About two-thirds of adults with mtDNA disease harbor a maternally transmitted point mutation. The recurrence risks are well documented for homoplasmic mtDNA mutations causing Leber hereditary optic neuropathy, but the situation is less clear for families with heteroplasmic mtDNA disorders. Two large studies have shown that for some heteroplasmic point mutations there appears to be a relationship between the percentage level of mutant mtDNA in a mother's blood and her risk of having clinically affected offspring. The situation is less clear for other point mutations, some of which may cause sporadic disease. Recent evidence has cast light on the general principles behind the transmission of heteroplasmic mtDNA point mutations, which may be important for genetic counseling in the future.     

The strength and timing of the mitochondrial bottleneck in salmon suggests a conserved mechanism in vertebrates

In most species mitochondrial DNA (mtDNA) is inherited maternally in an apparently clonal fashion, although how this is achieved remains uncertain. Population genetic studies show not only that individuals can harbor more than one type of mtDNA (heteroplasmy) but that heteroplasmy is common and widespread across a diversity of taxa. Females harboring a mixture of mtDNAs may transmit varying proportions of each mtDNA type (haplotype) to their offspring. However, mtDNA variants are also observed to segregate rapidly between generations despite the high mtDNA copy number in the oocyte, which suggests a genetic bottleneck acts during mtDNA transmission. Understanding the size and timing of this bottleneck is important for interpreting population genetic relationships and for predicting the inheritance of mtDNA based disease, but despite its importance the underlying mechanisms remain unclear. Empirical studies, restricted to mice, have shown that the mtDNA bottleneck could act either at embryogenesis, oogenesis or both. To investigate whether the size and timing of the mitochondrial bottleneck is conserved between distant vertebrates, we measured the genetic variance in mtDNA heteroplasmy at three developmental stages (female, ova and fry) in chinook salmon and applied a new mathematical model to estimate the number of segregating units (N(e)) of the mitochondrial bottleneck between each stage. Using these data we estimate values for mtDNA Ne of 88.3 for oogenesis, and 80.3 for embryogenesis. Our results confirm the presence of a mitochondrial bottleneck in fish, and show that segregation of mtDNA variation is effectively complete by the end of oogenesis. Considering the extensive differences in reproductive physiology between fish and mammals, our results suggest the mechanism underlying the mtDNA bottleneck is conserved in these distant vertebrates both in terms of it magnitude and timing. This finding may lead to improvements in our understanding of mitochondrial disorders and population interpretations using mtDNA data.     

Mitochondrial DNA paradox: sex-specific genetic structure in a marine mussel - despite maternal inheritance and passive dispersal

ABSTRACT: BACKGROUND: When genetic structure is identified using mitochondrial DNA (mtDNA), but no structure is identified using biparentally-inherited nuclear DNA, the discordance is often attributed to differences in dispersal potential between the sexes. RESULTS: We sampled the intertidal rocky shore mussel Perna perna in a South African bay and along the nearby open coast, and sequenced maternally-inherited mtDNA (there is no evidence for paternally-inherited mtDNA in this species) and a biparentally-inherited marker. By treating males and females as different populations, we identified significant genetic structure on the basis of mtDNA data in the females only. CONCLUSIONS: This is the first study to report sex-specific differences in genetic structure based on matrilineally-inherited mtDNA in a passively dispersing species that lacks social structure or sexual dimorphism. The observed pattern most likely stems from females being more vulnerable to selection in habitats from which they did not originate, which also manifests itself in a male-biased sex ratio. Our results have three important implications for the interpretation of population genetic data. First, even when mtDNA is inherited exclusively in the female line, it also contains information about males. For that reason, using it to identify sex-specific differences in genetic structure by contrasting it with biparentally-inherited markers is problematic. Second, the fact that sex-specific differences were found in a passively dispersing species in which sex-biased dispersal is unlikely highlights the fact that significant genetic structure is not necessarily a function of low dispersal potential or physical barriers. Third, even though mtDNA is typically used to study historical demographic processes, it also contains information about contemporary processes. Higher survival rates of males in non-native habitats can erase the genetic structure present in their mothers within a single generation.     

Making mitochondrial mutants.

Mitochondrial DNA (mtDNA) encodes a mere 13 polypeptides, all with well-defined cellular functions in mitochondrial energy metabolism. It was first sequenced over two decades ago, yet our understanding of the wider physiological role of mtDNA is surprisingly sketchy. Partly, this reflects the fact that the mitochondrial gene products are essential for life; that is, most mtDNA mutations are expected to be lethal. The technical difficulty of engineering mtDNA mutations has been a major handicap in furthering our understanding of the mitochondrial genetic system. Recent developments now offer some possibilities for the genetic manipulation of mtDNA and for elucidating its contribution to human development, physiology and disease.     

The utility of AFLPs for supporting mitochondrial DNA phylogeographical analyses in the Taiwanese bamboo viper, Trimeresurus stejnegeri

An amplified fragment length polymorphism (AFLP) assay was performed on individuals representing discrete haplotypes from two genetically distinct mtDNA lineages of the bamboo viper, Trimeresurus stejnegeri (Schmidt), within Taiwan. AFLP (525 polymorphic markers from five primer pairs) and mtDNA genetic distances were highly correlated and an analysis of molecular variance, and a Bayesian approach similarly partitioned estimates of genetic similarity according to the mtDNA phylogeographical pattern. These results are discussed in relation to biogeographical hypotheses, comparative rates of mtDNA molecular evolution, and in the identification of evolutionary significant units of Taiwanese T. stejnegeri. In spite of the high degree of congruence between the genetic datasets, the AFLP phylogenetic analysis did not support the mtDNA tree, suggesting that no contemporary barriers to gene flow exist between individuals from the two mtDNA lineages.     

Genetic ecological monitoring in human populations: heterozygosity, mtDNA haplotype variation, and genetic load

Yu. P. Altukhov suggested that heterozygosity is an indicator of the state of the gene pool. The idea and a linked concept of genetic ecological monitoring were applied to a new dataset on mtDNA variation in East European ethnic groups. Haplotype diversity (an analog of the average heterozygosity) was shown to gradually decrease northwards. Since a similar trend is known for population density, interlinked changes were assumed for a set of parameters, which were ordered to form a causative chain: latitude increases, land productivity decreases, population density decreases, effective population size decreases, isolation of subpopulations increases, genetic drift increases, and mtDNA haplotype diversity decreases. An increase in genetic drift increases the random inbreeding rate and, consequently, the genetic load. This was confirmed by a significant correlation observed between the incidence of autosomal recessive hereditary diseases and mtDNA haplotype diversity. Based on the findings, mtDNA was assumed to provide an informative genetic system for genetic ecological monitoring; e.g., analyzing the ecology-driven changes in the gene pool.     

Mitochondrial nucleoids maintain genetic autonomy but allow for functional complementation

Mitochondrial DNA (mtDNA) is packaged into DNA-protein assemblies called nucleoids, but the mode of mtDNA propagation via the nucleoid remains controversial. Two mechanisms have been proposed: nucleoids may consistently maintain their mtDNA content faithfully, or nucleoids may exchange mtDNAs dynamically. To test these models directly, two cell lines were fused, each homoplasmic for a partially deleted mtDNA in which the deletions were nonoverlapping and each deficient in mitochondrial protein synthesis, thus allowing the first unequivocal visualization of two mtDNAs at the nucleoid level. The two mtDNAs transcomplemented to restore mitochondrial protein synthesis but were consistently maintained in discrete nucleoids that did not intermix stably. These results indicate that mitochondrial nucleoids tightly regulate their genetic content rather than freely exchanging mtDNAs. This genetic autonomy provides a molecular mechanism to explain patterns of mitochondrial genetic inheritance, in addition to facilitating therapeutic methods to eliminate deleterious mtDNA mutations.