Melanesian mtDNA complexity

Melanesian populations are known for their diversity, but it has been hard to grasp the pattern of the variation or its underlying dynamic. Using 1,223 mitochondrial DNA (mtDNA) sequences from hypervariable regions 1 and 2 (HVR1 and HVR2) from 32 populations, we found the among-group variation is structured by island, island size, and also by language affiliation. The more isolated inland Papuan-speaking groups on the largest islands have the greatest distinctions, while shore dwelling populations are considerably less diverse (at the same time, within-group haplotype diversity is less in the most isolated groups). Persistent differences between shore and inland groups in effective population sizes and marital migration rates probably cause these differences. We also add 16 whole sequences to the Melanesian mtDNA phylogenies. We identify the likely origins of a number of the haplogroups and ancient branches in specific islands, point to some ancient mtDNA connections between Near Oceania and Australia, and show additional Holocene connections between Island Southeast Asia/Taiwan and Island Melanesia with branches of haplogroup E. Coalescence estimates based on synonymous transitions in the coding region suggest an initial settlement and expansion in the region at approximately 30-50,000 years before present (YBP), and a second important expansion from Island Southeast Asia/Taiwan during the interval approximately 3,500-8,000 YBP. However, there are some important variance components in molecular dating that have been overlooked, and the specific nature of ancestral (maternal) Austronesian influence in this region remains unresolved.     

The mutation rate of the human mtDNA deletion mtDNA4977.

The human mitochondrial mutation mtDNA4977 is a 4,977-bp deletion that originates between two 13-bp direct repeats. We grew 220 colonies of cells, each from a single human cell. For each colony, we counted the number of cells and amplified the DNA by PCR to test for the presence of a deletion. To estimate the mutation fate, we used a model that describes the relationship between the mutation rate and the probability that a colony of a given size will contain no mutants, taking into account such factors as possible mitochondrial turnover and mistyping due to PCR error. We estimate that the mutation rate for mtDNA4977 in cultured human cells is 5.95 x 10(-8) per mitochondrial genome replication. This method can be applied to specific chromosomal, as well as mitochondrial, mutations.     

Lineage-specific evolutionary rate in mammalian mtDNA

The existence of a lineage-specific nucleotide substitution rate in mammalian mtDNA has been investigated by analyzing the mtDNA of all available species, that is, 35 complete mitochondrial genomes from 14 mammalian orders. A detailed study of their evolutionary dynamics has been carried out on both ribosomal RNA and first and second codon positions (P12) of H-strand protein-coding genes by using two different types of relative-rate tests. Results are quite congruent between ribosomal and P12 sites. Significant rate variations have been observed among orders and among species of the same order. However, rate variation does not exceed 1.8-fold between the fastest (Proboscidea and Primates) and the slowest (Perissodactyla) evolving orders. Thus, the observed mitochondrial rate variations among taxa do not invalidate the suitability of mtDNA for drawing mammalian phylogeny. Dependence of evolutionary rate differences on variations in mutation and/or fixation rates was examined. Body size, generation time, and metabolic rate were tested, and no significant correlation was observed between them and the taxon-specific evolutionary rates, most likely because the latter might be influenced by multiple overlapping variable constraints.     

mtDNA sequence diversity in Africa.

mtDNA sequences were determined from 241 individuals from nine ethnic groups in Africa. When they were compared with published data from other groups, it was found that the !Kung, Mbuti, and Biaka show on the order of 10 times more sequence differences between the three groups, as well as between those and the other groups (the Fulbe, Hausa, Tuareg, Songhai, Kanuri, Yoruba, Mandenka, Somali, Tukana, and Kikuyu), than these other groups do between one other. Furthermore, the pairwise sequence distributions, patterns of coalescence events, and numbers of variable positions relative to the mean sequence difference indicate that the former three groups have been of constant size over time, whereas the latter have expanded in size. We suggest that this reflects subsistence patterns in that the populations that have expanded in size are food producers whereas those that have not are hunters and gatherers.     

Mitophagy in cells with mtDNA mutations

Despite the emergence of autophagy as a key process for mitochondrial quality control, the existence and persistence of pathogenic mtDNA mutations in human disease suggests that the degradation of dysfunctional mitochondria does not occur widely in vivo. During macroautophagy, a double-membraned cup-shaped structure engulfs cytosolic content. This autophagic vesicle then fuses with lysosomes, allowing hydrolytic enzymes to degrade the contents. Mitochondrial autophagy, or mitophagy, is thought to degrade damaged or nonfunctioning mitochondria specifically. The Parkinson disease-related proteins PINK1 (a mitochondrially localized kinase) and PARK2 (PARKIN, a cytosolically-localized E3 ubiquitin ligase) are essential for targeting mitochondria for mitophagy. Upon chemical uncoupling of the mitochondrial transmembrane potential (Δψ_m), PINK1 located in the mitochondrial outer membrane recruits PARK2 from the cytosol to the mitochondria, followed by delivery of the organelle to the autophagic machinery for degradation.     

Single-cell mtDNA heteroplasmy in colorectal cancer

Human mitochondria can be genetically distinct within the same individual, a phenomenon known as heteroplasmy. In cancer, this phenomenon seems exacerbated, and most mitochondrial mutations seem to be heteroplasmic. How this genetic variation is arranged within and among normal and tumor cells is not well understood. To address this question, here we sequenced single-cell mitochondrial genomes from multiple normal and tumoral locations in four colorectal cancer patients. Our results suggest that single cells, both normal and tumoral, can carry various mitochondrial haplotypes. Remarkably, this intra-cell heteroplasmy can arise before tumor development and be maintained afterward in specific tumoral cell subpopulations. At least in the colorectal patients studied here, the somatic mutations in the single-cells do not seem to have a prominent role in tumorigenesis.     

Keeping mtDNA in Shape between Generations

Since the unexpected discovery that mitochondria contain their own distinct DNA molecules, studies of the mitochondrial DNA (mtDNA) have yielded many surprises. In animals, transmission of the mtDNA genome is explicitly non-Mendelian, with a very high number of genome copies being inherited from the mother after a drastic bottleneck. Recent work has begun to uncover the molecular details of this unusual mode of transmission. Many surprising variations in animal mitochondrial biology are known; however, a series of recent studies have identified a core of evolutionarily conserved mechanisms relating to mtDNA inheritance, e.g., mtDNA bottlenecks during germ cell development, selection against specific mtDNA mutation types during maternal transmission, and targeted destruction of sperm mitochondria. In this review, we outline recent literature on the transmission of mtDNA in animals and highlight the implications for human health and ageing.     

mtDNA microevolution in Southern Chile's archipelagos

The genetic variability of four predominantly Indian populations of southern Chile's archipelagos was examined by determining the frequencies of four mitochondrial DNA haplogroups that characterize the American Indian populations. Over 90% of the individuals analyzed presented Native American mtDNA haplogroups. By means of an unweighted group pair method with arithmetic mean (UPGMA) dendrogram, a principal component analysis (PCA) derived from a distance matrix of mtDNA, and the exact test of population differentiation, we are able to prove the existence of a North‐South cline. The populations in the northern part of the archipelagos are genetically similar to the Huilliche tribe, while the groups from the South are most closely related to the Fueguino tribe from the extreme South of Chile, and secondarily to the Pehuenche and Mapuche, who are found to the North and East of Chiloé archipelago. These results are consistent with a colonization of the southern archipelagos from Tierra del Fuego. We evaluate the evolutionary relationships of the population of the Chiloé area to groups from other geographic areas of Chile, using analysis of molecular variance (AMOVA). Three Amerindian clusters are identified: one formed by the Aymará and Atacameño, a second by the Huilliche, and a third including the Mapuche, Pehuenche, and Fueguino tribes, and the population inhabiting the South of the Chiloé arcipelago. These groups exhibit a North‐South gradient in the frequency of haplogroup B, confirmed by F_ST tests. Am J Phys Anthropol, 2006 © 2005 Wiley‐Liss, Inc.     

Nuclear complementation restores mtDNA levels in cultured cells from a patient with mtDNA depletion.

We have studied cultured skin fibroblasts from a patient with a fatal mitochondrial disease manifesting soon after birth. These fibroblasts were found to grow only in the presence of pyruvate and uridine, a characteristic of cells lacking mtDNA (rho0 cells). Southern blot and PCR analyses confirmed that the patient's fibroblasts contained less than 2% of control levels of mtDNA. Biochemical analyses indicated that the activities of all the respiratory-chain enzymes were severely decreased in mitochondria isolated from these fibroblasts. In order to elucidate the underlying molecular defect, cell fusions were performed between enucleated fibroblasts from this patient and a human-derived rho0 cell line (rho0 A549.B2). The resulting cybrids were plated in medium lacking pyruvate and uridine, to select for the restoration of respiratory-chain function. Complementation was observed between the nuclear genome of the rho0 A549.B2 cells and the mtDNA of the patient's cells, restoring mtDNA levels and respiratory-chain function in the cybrid cells. These results indicate that mtDNA depletion in our patient is under the control of the nuclear genome.     

A modified procedure for quantitative analysis of mtDNA, detecting mtDNA depletion

Quantitative analysis of mitochondrial DNA (mtDNA) is crucial for proper diagnosis of diseases that are caused by or associated with mtDNA depletion. However, such a quantitative characterization of mtDNA is not a simple procedure and requires several laboratory steps at which potential errors can accumulate. Here, we describe a modified procedure for quantitative human mtDNA analysis. The procedure is based on using two PCR-amplified, fluorescein-labeled DNA probes, complementary to mtDNA (detection probe) and chromosomal 18S rDNA (reference probe), both of similar length. Thus, equal amounts of these probes can be used and, contrary to previously published procedures, no mtDNA purification (apart from total DNA isolation) or 18S rDNA cloning is necessary for probe preparation. Two separate hybridizations (each with one probe) are suggested instead of one hybridization with both probes; this decreases background signals and enables adjustment of the strength of specific signals from both probes, which is useful in the subsequent densitometric analysis after superimposing of both pictures. Using different DNA amounts for reactions, we have proved that the procedure is quantitative in a broad range of sample DNA concentrations. Moreover, we were able to detect mtDNA depletion unambiguously in tissue samples from patients suffering from diseases caused by dysfunction of mtDNA.     

Widespread recombination in published animal mtDNA sequences

Mitochondrial DNA (mtDNA) recombination has been observed in several animal species, but there are doubts as to whether it is common or only occurs under special circumstances. Animal mtDNA sequences retrieved from public databases were unambiguously aligned and rigorously tested for evidence of recombination. At least 30 recombination events were detected among 186 alignments examined. Recombinant sequences were found in invertebrates and vertebrates, including primates. It appears that mtDNA recombination may occur regularly in the animal cell but rarely produces new haplotypes because of homoplasmy. Common animal mtDNA recombination would necessitate a reexamination of phylogenetic and biohistorical inference based on the assumption of clonal mtDNA transmission. Recombination may also have an important role in producing and purging mtDNA mutations and thus in mtDNA-based diseases and senescence.     

Extreme mtDNA homogeneity in continental Asian populations

Mitochondrial DNA (mtDNA) variation in continental Asia has not been well-studied. Here, we report mtDNA HV1 sequences for 84 Xi'an and 82 Changsha Han Chinese, 89 Honshu Japanese, and 35 Vietnamese. Comparison of these sequences with other Asian mtDNA sequences reveals high variability within populations, but extremely low differentiation among Asian populations. Correlations between genetic distance and geographic distance, based on mtDNA and Y chromosome variation, indicate a higher migration rate in females than in males. This may reflect patrilocality, as suggested previously, but another plausible hypothesis is that the demographic expansion associated with the spread of agriculture in Asia may be responsible for the extreme genetic homogeneity in Asia.     

Geographic patterns of mtDNA diversity in Europe

Genetic diversity in Europe has been interpreted as a reflection of phenomena occurring during the Paleolithic ( approximately 45,000 years before the present [BP]), Mesolithic ( approximately 18,000 years BP), and Neolithic ( approximately 10,000 years BP) periods. A crucial role of the Neolithic demographic transition is supported by the analysis of most nuclear loci, but the interpretation of mtDNA evidence is controversial. More than 2,600 sequences of the first hypervariable mitochondrial control region were analyzed for geographic patterns in samples from Europe, the Near East, and the Caucasus. Two autocorrelation statistics were used, one based on allele-frequency differences between samples and the other based on both sequence and frequency differences between alleles. In the global analysis, limited geographic patterning was observed, which could largely be attributed to a marked difference between the Saami and all other populations. The distribution of the zones of highest mitochondrial variation (genetic boundaries) confirmed that the Saami are sharply differentiated from an otherwise rather homogeneous set of European samples. However, an area of significant clinal variation was identified around the Mediterranean Sea (and not in the north), even though the differences between northern and southern populations were insignificant. Both a Paleolithic expansion and the Neolithic demic diffusion of farmers could have determined a longitudinal cline of mtDNA diversity. However, additional phenomena must be considered in both models, to account both for the north-south differences and for the greater geographic scope of clinical patterns at nuclear loci. Conversely, two predicted consequences of models of Mesolithic reexpansion from glacial refugia were not observed in the present study.     

mtDNA GeneExtractor: A computer tool for mtDNA gene/region information extraction

The analysis of considerable numbers of DNA sequences is largely dependent on the development of simple software tools for automatically process the genetic data deposited on public databases. However, there are some difficulties in the automation process due to diverse synonyms being used as qualifiers for genes and some inconsistencies in gene locations between related Primate species, this fact happening even in the carefully curated database RefSeq. Here, we present mtDNA GeneEXtractor, a Windows based computer tool developed for the extraction of information for particular gene/regions from mammal mitochondrial DNA sequences deposited under GenBank format. The tool was quite efficient in retrieving organized information for comparative mtDNA gene/region diversity analyses when tested for the evaluation of transition/transversion ratios in humans and between Primates. Taking phylogenetic information into account to avoid redundancy due to ancestry-sharing, the transition/transversion ratios in the 13 protein-coding genes had a mean value of 12.46 for Primates (from 6.46 in ND2 to 17.04 in COX1) and higher (34.74) but more heterogeneous (ranging from 17.30 in ND5 to 74.39 in ND4) in a worldwide human database. The similar patterns of transition/transversion ratios in all positions and in only four fold degenerate positions show no evidence for selection in the 13 mtDNA protein-coding genes.     

线粒体DNA在分子进化研究中的应用

线粒体作为古老的细胞器广泛存在于真核生物中,由于线粒体DNA的高进化速率,已被作为DNA标记广泛应用于现代分子生物学研究。长期以来,线粒体DNA一直被认为是中性进化或者受到纯净化选择。线粒体通过氧化呼吸链提供>95%的动物运动所需的自由能,并提供保持体温的热能。据此,近期已有研究推测并验证了线粒体与动物运动能力及气候适应性的相关性。该文简述线粒体基因组成及其进化,通过列举线粒体DNA在分子进化研究中的应用(如利用线粒体DNA重建物种的系统发育关系、从线粒体DNA角度分析生物能量代谢的适应性进化以及线粒体DNA密码子重定义对生物适应性的作用等),概述了线粒体DNA的分子进化研究。