The complete mitochondrial genome of the javeline goby Acanthogobius hasta (Perciformes, Gobiidae) and phylogenetic considerations

We isolated Acanthogobius hasta mitochondrial DNA by long-polymerase chain reaction (long-PCR) with conserved primers, and sequenced this mitogenome with primer walking. The resultant A. hasta mitochondrial DNA sequence was found to consist of 16,663 bp with a structural organization conserved relative to that of other fish. In this paper, we report the basic characteristics of the A. hasta mitochondrial genome including structural organization, base composition of rRNAs and the tRNAs and protein-encoding genes, and characteristics of mitochondrial tRNAs. These findings are applicable to molecular phylogenetics in the suborder Gobioidei.     

The complete mitochondrial genome of the Korean soft-shelled turtle Pelodiscus sinensis (Testudines, Trionychidae).

We isolated Korean soft-shelled turtle, Pelodiscus sinensis, mitochondrial DNA by long-polymerase chain reaction (long-PCR) with conserved primers and sequenced this mitochondrial genome (mitogenome) with primer walking using flanking sequences. The P. sinensis mitochondrial DNA has 17,042 bp and its structural organization is conserved compared to those of other reptiles and mammals. To unveil the phylogenetic relationship of the turtles, we used the NJ, MP, and ML analysis methods after inferring those sequences from the mitochondrial 16S rRNA gene. We also compared two P. sinensis variants from Korea and China using the mitochondrial genome. In this study, we report the basic characteristics of the P. sinensis mitochondrial genome, including structural organization and base composition of the rRNAs, tRNAs and protein-coding genes, as well as characteristics of tRNAs. These features are applicable for the study of phylogenetic relationships in turtles.     

Somatic mtDNA Mutation Spectra in the Aging Human Putamen

The accumulation of heteroplasmic mitochondrial DNA (mtDNA) deletions and single nucleotide variants (SNVs) is a well-accepted facet of the biology of aging, yet comprehensive mutation spectra have not been described. To address this, we have used next generation sequencing of mtDNA-enriched libraries (Mito-Seq) to investigate mtDNA mutation spectra of putamen from young and aged donors. Frequencies of the “common” deletion and other “major arc” deletions were significantly increased in the aged cohort with the fold increase in the frequency of the common deletion exceeding that of major arc deletions. SNVs also increased with age with the highest rate of accumulation in the non-coding control region which contains elements necessary for translation and replication. Examination of predicted amino acid changes revealed a skew towards pathogenic SNVs in the coding region driven by mutation bias. Levels of the pathogenic m.3243A>G tRNA mutation were also found to increase with age. Novel multimeric tandem duplications that resemble murine control region multimers and yeast ρ⁻ mtDNAs, were identified in both young and aged specimens. Clonal ∼50 bp deletions in the control region were found at high frequencies in aged specimens. Our results reveal the complex manner in which the mitochondrial genome alters with age and provides a foundation for studies of other tissues and disease states.     

The pedigree rate of sequence divergence in the human mitochondrial genome: there is a difference between phylogenetic and pedigree rates

We have extended our previous analysis of the pedigree rate of control-region divergence in the human mitochondrial genome. One new germline mutation in the mitochondrial DNA (mtDNA) control region was detected among 185 transmission events (generations) from five Leber hereditary optic neuropathy (LHON) pedigrees. Pooling the LHON pedigree analyses yields a control-region divergence rate of 1.0 mutation/bp/10(6) years (Myr). When the results from eight published studies that used a similar approach were pooled with the LHON pedigree studies, totaling >2,600 transmission events, a pedigree divergence rate of 0.95 mutations/bp/Myr for the control region was obtained with a 99.5% confidence interval of 0.53-1.57. Taken together, the cumulative results support the original conclusion that the pedigree divergence rate for the control region is approximately 10-fold higher than that obtained with phylogenetic analyses. There is no evidence that any one factor explains this discrepancy, and the possible roles of mutational hotspots (rate heterogeneity), selection, and random genetic drift and the limitations of phylogenetic approaches to deal with high levels of homoplasy are discussed. In addition, we have extended our pedigree analysis of divergence in the mtDNA coding region. Finally, divergence of complete mtDNA sequences was analyzed in two tissues, white blood cells and skeletal muscle, from each of 17 individuals. In three of these individuals, there were four instances in which an mtDNA mutation was found in one tissue but not in the other. These results are discussed in terms of the occurrence of somatic mtDNA mutations.     

Stochastic Drift in Mitochondrial DNA Point Mutations: A Novel Perspective Ex Silico

The mitochondrial free radical theory of aging (mFRTA) implicates Reactive Oxygen Species (ROS)-induced mutations of mitochondrial DNA (mtDNA) as a major cause of aging. However, fifty years after its inception, several of its premises are intensely debated. Much of this uncertainty is due to the large range of values in the reported experimental data, for example on oxidative damage and mutational burden in mtDNA. This is in part due to limitations with available measurement technologies. Here we show that sample preparations in some assays necessitating high dilution of DNA (single molecule level) may introduce significant statistical variability. Adding to this complexity is the intrinsically stochastic nature of cellular processes, which manifests in cells from the same tissue harboring varying mutation load. In conjunction, these random elements make the determination of the underlying mutation dynamics extremely challenging. Our in silico stochastic study reveals the effect of coupling the experimental variability and the intrinsic stochasticity of aging process in some of the reported experimental data. We also show that the stochastic nature of a de novo point mutation generated during embryonic development is a major contributor of different mutation burdens in the individuals of mouse population. Analysis of simulation results leads to several new insights on the relevance of mutation stochasticity in the context of dividing tissues and the plausibility of ROS ”vicious cycle” hypothesis.     

Detection of mitochondrial DNA deletions in the cochlea and its structural elements from archival human temporal bone tissue

Large-scale deletions of mitochondrial DNA (mtDNA) have been associated with aging and disease in post-mitotic tissues. These post-mitotic tissues, including skeletal muscle, heart and brain, are heavily dependent on intact functional mitochondria. The cochlear tissues are known to contain an abundance of mitochondria. This observation stimulated a search for mtDNA deletions in the cochlea and its elements using a sensitive nested PCR methodology and long range PCR to explain the functional deficits observed in age-related hearing loss. The presence of the so-called “common” deletion (CD) was detected in cochlear tissue from two individuals with age-related hearing loss, 73 and 78 years of age. Three additional deletions, that to our knowledge have not been previously reported, were also identified in these two individuals, including a 5354 bp deletion flanked with a 3 bp repeat, a 9682 bp deletion flanked by a 10 bp repeat and a 5142 bp deletion without a flanking repeat. The 9682 and 5142 bp deletions were also detected in an individual 39 years of age with normal hearing, however, these two deletions were not detected in a normal hearing individual 9 years of age. In contrast, the 5354 bp deletion was detected in all four of the individuals studied. To localize the deletions within the cochlea, the cochlear elements were removed by laser capture microdissection (LCM) and the mtDNA from these tissues was studied. The 5142 and 5354 bp deletions were detected in the organ of corti, spiral ligament, and ganglion cells, but not in the stria vascularis. These findings correlate with the reduction in the number of spiral ganglion cells and outer hair cells, and the normal stria vascularis volume observed in this individual. All four of these deletions involve the cytochrome c oxidase (COX) subunit III gene, encoded by mtDNA. These observations suggest that multiple mtDNA deletions may contribute to a deficit in mitochondrial function in the cochlea and result in hearing loss if a level of physiological significance is reached.     

A lifetime of retinal light exposure does not appear to increase mitochondrial mutations.

Recently, there have been a number of reports of an accumulation of mutations in the mitochondrial (mt) genome with age. Such mutations may be due in part to the mt oxidative metabolic pathways which provide most of the cell's energy, but also generate free radicals. In addition, the mt genome in some tissues, such as the retina, may also accumulate mutations from the effects of ultraviolet light. To obtain information concerning the possible accumulation of retinal mt mutations with age, we cloned retinal mt DNA from a 71-year-old person. Thirty-two kilobases of sequence from 83 independently isolated clones representing two regions, a coding and a noncoding region, of the mt genome were obtained. Three polymorphisms between these sequences and the standard 'Anderson sequence' were discovered. Only one heteroplasmic mutation was found. These results confirm the low somatic mutation rate found in prior studies utilizing different types of human tissues. In addition, these results suggest that there is little if any accumulated damage to the mt DNA of the retina during normal aging.     

斑翅草螽线粒体基因组序列测定与分析

已经测定的昆虫线粒体基因组中, 直翅目草螽亚科的疑钩额螽Ruspolia dubia线粒体控制区长度最短, 仅70 bp。为此, 本研究采用L-PCR结合二次PCR扩增策略对另一种草螽亚科昆虫斑翅草螽Conocephalus maculates线粒体基因组序列进行了测定。序列注释发现: 斑翅草螽线粒体基因组序列全长15 898 bp, A+T含量为72.05%, 基因排列与典型的节肢动物线粒体基因组一致。全部蛋白质编码基因以典型的ATN作为起始密码子, 9个蛋白质编码基因具有完整的终止密码子, 其余4个以不完整的T作为终止信号。除trnS^AGN外, 其余21个tRNAs均可折叠形成典型的三叶草结构, 依照Steinberg等(1997)线粒体特殊tRNA结构类型-9, trnS^AGN的DHU臂形成一个7 nt环, 反密码子臂则长达9 bp, 含1个突起碱基, 而不是正常的5 bp。斑翅草螽与其他直翅目昆虫线粒体基因组的主要区别在于, 在trnS^UCN和nad1, nad1和trnL^CUN基因间各存在一段罕见的、大段的基因间隔序列, 长度分别为78 bp和360 bp。其中, 位于nad1和trnL^CUN之间的基因间隔序列N链可形成一个包含完整起始、终止密码子(ATT/TAA)、编码103个氨基酸的未知开放阅读框。同义密码子使用偏好与线粒体基因组编码的tRNA反密码子匹配情况无关, 但与密码子第3位点的碱基组成紧密相关; 相对密码子使用频率(relative synonymous codon usage, RSCU)大于1的密码子, 其第3位点全部是A或T。在已经测定的直翅目昆虫线粒体基因组tRNAs中, 均存在一定数量的碱基错配, 且以G-U弱配对为主, 表明G-U配对在线粒体基因组中可能是一种正常的碱基配对形式。本研究测定的斑翅草螽线粒体基因组序列, 和先前已经测定的直翅目线粒体基因组序列一起, 可以为重建直翅目的进化历史提供数据资源。     

Reliable resequencing of the human dystrophin locus by universal long polymerase chain reaction and massive pyrosequencing

The X-linked dystrophin gene is well known for its involvement in Duchenne/Becker muscular dystrophies and for its exceptional megabase size. This locus at Xp21 is prone to frequent random molecular changes, including large deletions and duplications, but also smaller variations. To cope with such huge sequence analysis requirements in forthcoming diagnostic applications, we employed the power of the parallel 454 GS-FLX pyrosequencer to the dystrophin locus. We enriched the genomic region of interest by the robust amplification of 62 fragments under universal conditions by the long-PCR protocol yielding 244,707 bp of sequence. Pooled PCR products were fragmented and used for library preparation and DNA sequencing. To evaluate the entire procedure we analyzed four male DNA samples for sequence coverage and accuracy in DNA sequence variation and for any potential bias. We identified 562 known variations and 55 additional variants not yet reported, among which we detected a causative Arg1844Stop mutation in one sample. Sanger sequencing confirmed all changes. Unexpectedly, only 3× coverage was sufficient for 99.9993% accuracy. Our results show that long PCR combined to massive pyrosequencing is very reliable for the analysis of the biggest gene of the human genome and open the doors to other demanding applications in molecular diagnostics.     

Complete sequence of the mitochondrial genome of the tapeworm Hymenolepis diminuta: gene arrangements indicate that Platyhelminths are Eutrochozoans

Using "long-PCR," we amplified in overlapping fragments the complete mitochondrial genome of the tapeworm Hymenolepis diminuta (Platyhelminthes: Cestoda) and determined its 13,900-nt sequence. The gene content is the same as that typically found for animal mitochondrial DNA (mtDNA) except that atp8 appears to be lacking, a condition found previously for several other animals. Despite the small size of this mtDNA, there are two large noncoding regions, one of which contains 13 repeats of a 31-nt sequence and a potential stem-loop structure of 25 bp with an 11-member loop. Large potential secondary structures were identified also for the noncoding regions of two other cestode mtDNAS: Comparison of the mitochondrial gene arrangement of H. diminuta with those previously published supports a phylogenetic position of flatworms as members of the Eutrochozoa, rather than placing them basal to either a clade of protostomes or a clade of coelomates.     

甜果螨全线粒体基因组测序与分析

【目的】测定和分析甜果螨Carpoglyphus lactis线粒体基因组全序列,并在线粒体基因组水平探讨其在真螨总目(Acariformes)中的系统发育地位,为真螨总目分类及果螨科线粒体基因组研究提供科学依据。【方法】挑取实验室饲养的甜果螨成螨,用传统的酚氯仿抽提法和试剂盒提取法提取甜果螨基因组DNA。然后采用节肢动物或螨类线粒体基因的通用引物PCR扩增出甜果螨线粒体基因cox1,cob,rrnS和nad4-nad5的部分序列;再设计种特异性引物进行Long-PCR扩增和步移法测序,测出甜果螨线粒体基因组全序列。应用SeqMan, SEQUIN 9.0和tRNAscan等生物信息学软件,对甜果螨线粒体基因组的基因结构等进行生物信息学分析。最后基于17种真螨总目螨类的蛋白质编码基因,采用最大似然法构建系统发育树。【结果】甜果螨线粒体全基因组总长为14 060 bp(GenBank登录号:MN073839),为典型的闭合双链DNA分子,共由37个基因组成,包括13个蛋白质编码基因(PCGs)、22个tRNA基因和2个rRNA基因;甜果螨线粒体基因组还包括1个大的非编码区(large non-coding region, LNR)。系统发育分析结果显示,甜果螨Carpoglyphus lactis属于无气门亚目粉螨总科(Acaroidae),与椭圆食粉螨Aleuroglyphus ovatus构成一支。粉螨总科(Acaroidae)和薄口螨总科(Histiostomatoidae)聚成一簇,与痒螨股(Psoroptidia)构成姐妹群。【结论】本研究首次获得并分析了甜果螨线粒体基因组全序列。甜果螨与椭圆食粉螨的亲缘关系较近。     

Analysis of repeat-mediated deletions in the mitochondrial genome of Saccharomyces cerevisiae

Mitochondrial DNA deletions and point mutations accumulate in an age-dependent manner in mammals. The mitochondrial genome in aging humans often displays a 4977-bp deletion flanked by short direct repeats. Additionally, direct repeats flank two-thirds of the reported mitochondrial DNA deletions. The mechanism by which these deletions arise is unknown, but direct-repeat-mediated deletions involving polymerase slippage, homologous recombination, and nonhomologous end joining have been proposed. We have developed a genetic reporter to measure the rate at which direct-repeat-mediated deletions arise in the mitochondrial genome of Saccharomyces cerevisiae. Here we analyze the effect of repeat size and heterology between repeats on the rate of deletions. We find that the dependence on homology for repeat-mediated deletions is linear down to 33 bp. Heterology between repeats does not affect the deletion rate substantially. Analysis of recombination products suggests that the deletions are produced by at least two different pathways, one that generates only deletions and one that appears to generate both deletions and reciprocal products of recombination. We discuss how this reporter may be used to identify the proteins in yeast that have an impact on the generation of direct-repeat-mediated deletions.     

Oxidative stress in human aging and mitochondrial disease-consequences of defective mitochondrial respiration and impaired antioxidant enzyme system

Respiratory function of mitochondria is compromised in aging human tissues and severely impaired in the patients with mitochondrial disease. A wide spectrum of mitochondrial DNA (mtDNA) mutations has been established to associate with mitochondrial diseases. Some of these mtDNA mutations also occur in various human tissues in an age-dependent manner. These mtDNA mutations cause defects in the respiratory chain due to impairment of the gene expression and structure of respiratory chain polypeptides that are encoded by the mitochondrial genome. Since defective mitochondria generate more reactive oxygen species (ROS) such as O2- and H2O2 via electron leak, we hypothesized that oxidative stress is a contributory factor for aging and mitochondrial disease. This hypothesis has been supported by the findings that oxidative stress and oxidative damage in tissues and culture cells are increased in elderly subjects and patients with mitochondrial diseases. Another line of supporting evidence is our recent finding that the enzyme activities of Cu,Zn-SOD, catalase and glutathione peroxidase (GPx) decrease with age in skin fibroblasts. By contrast, Mn-SOD activity increases up to 65 years of age and then slightly declines thereafter. On the other hand, we observed that the RNA, protein and activity levels of Mn-SOD are increased two- to three-fold in skin fibroblasts of the patients with CPEO syndrome but are dramatically decreased in patients with MELAS or MERRF syndrome. However, the other antioxidant enzymes did not change in the same manner. The imbalance in the expression of these antioxidant enzymes indicates that the production of ROS is in excess of their removal, which in turn may elicit an elevation of oxidative stress in the fibroblasts. Indeed, it was found that intracellular levels of H2O2 and oxidative damage to DNA and lipids in skin fibroblasts from elderly subjects or patients with mitochondrial diseases are significantly increased as compared to those of age-matched controls. Furthermore, Mn-SOD or GPx-1 gene knockout mice were found to display neurological disorders and enhanced oxidative damage similar to those observed in the patients with mitochondrial disease. These observations are reviewed in this article to support that oxidative stress elicited by defective respiratory function and impaired antioxidant enzyme system plays a key role in the pathophysiology of mitochondrial disease and human aging.     

Age-associated mitochondrial DNA mutations lead to small but significant changes in cell proliferation and apoptosis in human colonic crypts

Mitochondrial DNA (mtDNA) mutations are a cause of human disease and are proposed to have a role in human aging. Clonally expanded mtDNA point mutations have been detected in replicating tissues and have been shown to cause respiratory chain (RC) defects. The effect of these mutations on other cellular functions has not been established. Here, we investigate the consequences of RC deficiency on human colonic epithelial stem cells and their progeny in elderly individuals. We show for the first time in aging human tissue that RC deficiency attenuates cell proliferation and increases apoptosis in the progeny of RC deficient stem cells, leading to decreased crypt cell population.     

Mitochondrial DNA polymorphism in mitochondrial myopathy

Summary In order to test the hypothesis that mitochondrial myopathy may be caused by mutation of the mitochondrial (mt) genome, restriction fragment length polymorphism in leucocyte mt DNA has been studied in 38 patients with mitochondrial myopathy, 44 of their unaffected matrilineal relatives, and 35 normal control subjects. Previously unreported mt DNA polymorphisms were identified in both patients and controls. No differences in restriction fragment patterns were observed between affected and unaffected individuals in the same maternal line, and there was no evidence of major deletion of mt DNA in patients. This study provides no positive evidence of mitochondrial inheritance in mitochondrial myopathy, but this has not been excluded.     

Multifactorial nature of high frequency of mitochondrial DNA mutations in somatic mammalian cells

The high frequency of mitochondrial DNA (mtDNA) mutations in somatic mammalian cells, which is more than two orders of magnitude higher than the mutation frequency of nuclear DNA (nDNA), significantly correlates with development of a variety of mitochondrial diseases (neurodegenerative diseases, cardiomyopathies, type II diabetes mellitus, cancer, etc.). A direct cause—consequence relationship has been established between mtDNA mutations and aging phenotypes in mammals. However, the unclear nature of the high frequency of mtDNA mutations requires a comprehensive consideration of factors that contribute to this phenomenon: oxidative stress, features of structural organization and repair of the mitochondrial genome, ribonucleotide reductase activity, replication errors, mutations of nuclear genes encoding mitochondrial proteins.     

Genetic mapping of mitochondrial markers by recombinational analysis in Chlamydomonas reinhardtii

The mitochondrial genome of Chlamydomonas reinhardtii is a 15.8 kb linear DNA molecule present in multiple copies. In crosses, the meiotic products only inherit the mitochondrial genome of the mating type minus (paternal) parent. In contrast mitotic zygotes transmit maternal and paternal mitochondrial DNA copies to their diploid progeny and recombinational events between molecules of both origins frequently occur. Six mitochondrial mutants unable to grow in the dark (dk^? mutants) were crossed in various combinations and the percentages of wild-type dk⁺ recombinants were determined in mitotic zygotes when all progeny cells had become homoplasmic for the mitochondrial genome. In crosses between strains mutated in the COB (apocytochrome ) gene and strains mutated in the COX1 (subunit 1 of cytochrome oxidase) gene, the frequency of recombination was 13.7% (± 3.2%). The corresponding physical distance between the mutation sites was 4.3 kb. In crosses between strains carrying mutations separated by about 20 bp, a recombinational frequency of 0.04% (± 0.02%) was found. Two other mutants not yet characterized at the molecular level were also used for recombinational studies. From these data, a linear genetic map of the mitochondrial genome could be drawn. This map is consistent with the positions of the mutation sites on the mitochondrial DNA molecule and thereby validates the method used to generate the map. The frequency of recombination per physical distance unit (3.2% ± 0.7% per kilobase) is compared with those obtained for other organellar genomes in yeasts and Chlamydomonas.