MITOCHONDRIAL DNA VARIABILITY OF STRIPED DOLPHINS (STENELLA COERULEOALBA) IN THE SPANISH MEDITERRANEAN WATERS

Frozen muscle samples from 44 striped dolphins stranded on the Spanish Mediterranean coasts from 1990 to 1993 have been studied by means of mitochondrial DNA (mtDNA) restriction site analysis. Thirty-five of these dolphins were affected by a die-off occurring during this time in the western Mediterranean Sea. The mtDNA from each dolphin was digested with 15 restriction endonucleases that recognized 61 different restriction sites. The specific location of these sites on the mitochondrial gene map allowed us to determine the distribution of variability along this molecule. From the restriction analysis, a total of 15 different composite patterns or haplotypes was obtained and their phylogenetic relationships established both by cladistic and phenetic methods.
Estimates of sequence divergence among the 15 haplotypes ranged from 0.148% to 0.919%. Haplotype diversity (average heterozygosity) obtained was 0.789, a high value compared to other available data on cetaceans, especially considering that only a small area of the distribution of the species has been sampled. Neither population subdivision nor any evidence of correlation between haplotype frequencies and temporal or geographic distribution of dolphins has been detected.     

The Use of Restriction Endonucleases to Measure Mitochondrial DNA Sequence Relatedness in Natural Populations. I. Population Structure and Evolution in the Genus Peromyscus

In this study we introduce to natural population analysis a molecular technique that involves the use of restriction endonucleases to compare mitochondrial DNA (mtDNA) sequences. We have examined the fragment patterns produced by six restriction endonucleases acting upon mtDNA isolated from 23 samples of three species of the rodent Peromyscus. Our observations confirm the following conclusions derived from previous experiments with laboratory animals: (1) mtDNA within an individual homogeneous; (2) at least the majority of mtDNA present in an individual is inherited from the female parent. Our experiments demonstrate for the first time that there is detectable heterogeneity in mtDNA sequences within and among natural geographic populations of a species and that this heterogeneity can readily be used to estimate relatedness between individuals and populations. Individuals collected within a single locale show less than 0.5% sequence divergence, while those collected from conspecific populations separated by 50 ti 500 miles differ by approximately 1.5%. The mtDNAs of the closely related sibling species P. polionotus and P. maniculatus differ from each other by 13 to 17%; nonsibling species differ by more than 20%. Qualitative and quantitative approaches to analysis of digestion patterns are suggested. The results indicate that restriction analysis of mtNDA may become the most sensitive and powerful technique yet available for reconstructing evolutionary relationships among conspecific organisms.     

Molecular analysis of the inheritance and stability of the mitochondrial genome of an inbred line of maize

Summary We have investigated the inheritance of the mitochondrial DNA (mtDNA) restriction endonuclease digestion patterns of maize inbred line B37N in individual plants and pooled siblings in lineages derived from five separate plants in the third generation following successive self-pollinations. The restriction fragment patterns of the different mtDNA samples were compared after digestion with five endonucleases. No differences were visible in the mobilities of the 199 fragments scored per sample. Hybridization analysis with two different cloned mtDNA probes, one of which contains homologies to a portion of the S2 plasmid characteristic of cms-S maize, failed to reveal cryptic variation. The apparent rate of genomic change in maize mtDNA from inbred plants appears to be very slow, compared with the faster rates of change seen in maize tissue cultures and with the documented rapid rate of inter- and intraspecific variation for mammalian mtDNA.     

The use of restriction endonucleases to compare mitochondrial dna sequences in Mus musculus: A detailed restriction map of mitochondrial DNA from mouse L cells

The complete mitochondrial genome of a chloramphenicol-resistant, oligomycin-resistant mouse L cell has been cloned in E. coli. Using fragments of this DNA, purified by preparative agarose gel electrophoresis, we have mapped 139 restriction sites cleaved by 15 endonucleases. We have then compared the positions of these sites with those found in mtDNA purified from several other L-cell lines, from the tissue of several strains of laboratory mice, and from a plasmid containing mtDNA of a single, wild Mus musculus sample. The results indicate that all of the L-cell mtDNAs are identical except at a single EcoRI site, and that the L-cell sequence is identical to that found in mtDNA from normal tissue. They also suggest that mtDNA sequences found in North American Mus musculus populations may be much more homogeneous than expected from analysis of other rodents.     

Purification of mitochondrial DNA from total cellular DNA of small tissue samples

A method is presented for the isolation of highly purified mitochondrial (mt)DNA from a crude DNA extract, making use of the different mobilities of covalently closed circular mtDNA vs. endonuclease-digested nuclear DNA in agarose gels. The preparation is virtually free of any contaminating linear DNA, as judged from its electron microscopic appearance, and can be used for further procedures such as polymerase chain reaction (PCR). Since isolation of mitochondria is not a prerequisite for this method, it can be applied to tissue samples in the mg range. In principle, the method can be applied to every eukaryotic species, provided a molecular hybridization probe is available which permits the position of mtDNA to be located in an agarose gel. This probe can be a cDNA, a DNA fragment generated by PCR, or mtDNA itself, if only the approximate size of the genome is known.     

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.     

Matrilineal history of the endangered Cape Sable seaside sparrow inferred from mitochondrial DNA polymorphism

Restriction analyses were conducted on mitochondrial DNA (mtDNA) amplified by long-PCR from an endangered bird, the Cape Sable seaside sparrow. The first of several successful mtDNA amplifications was accomplished using the partially digested tissue remains of a transmitter-monitored bird retrieved from the gut of a snake. As many as 91 mtDNA restriction fragments produced by 18 endonucleases were compared in this and four other Cape Sable specimens against mtDNA similarly amplified by long-PCR from other taxonomic forms in the seaside sparrow complex. Results indicate that the Cape Sable birds belong to an 'Atlantic' matrilineal clade, and are highly divergent from other seaside sparrows along the Gulf of Mexico.     

PCR-Free Enrichment of Mitochondrial DNA from Human Blood and Cell Lines for High Quality Next-Generation DNA Sequencing

Recent advances in sequencing technology allow for accurate detection of mitochondrial sequence variants, even those in low abundance at heteroplasmic sites. Considerable sequencing cost savings can be achieved by enriching samples for mitochondrial (relative to nuclear) DNA. Reduction in nuclear DNA (nDNA) content can also help to avoid false positive variants resulting from nuclear mitochondrial sequences (numts). We isolate intact mitochondrial organelles from both human cell lines and blood components using two separate methods: a magnetic bead binding protocol and differential centrifugation. DNA is extracted and further enriched for mitochondrial DNA (mtDNA) by an enzyme digest. Only 1 ng of the purified DNA is necessary for library preparation and next generation sequence (NGS) analysis. Enrichment methods are assessed and compared using mtDNA (versus nDNA) content as a metric, measured by using real-time quantitative PCR and NGS read analysis. Among the various strategies examined, the optimal is differential centrifugation isolation followed by exonuclease digest. This strategy yields >35% mtDNA reads in blood and cell lines, which corresponds to hundreds-fold enrichment over baseline. The strategy also avoids false variant calls that, as we show, can be induced by the long-range PCR approaches that are the current standard in enrichment procedures. This optimization procedure allows mtDNA enrichment for efficient and accurate massively parallel sequencing, enabling NGS from samples with small amounts of starting material. This will decrease costs by increasing the number of samples that may be multiplexed, ultimately facilitating efforts to better understand mitochondria-related diseases.     

qPCR-based mitochondrial DNA quantification: influence of template DNA fragmentation on accuracy

Real-time PCR (qPCR) is the method of choice for quantification of mitochondrial DNA (mtDNA) by relative comparison of a nuclear to a mitochondrial locus. Quantitative abnormal mtDNA content is indicative of mitochondrial disorders and mostly confines in a tissue-specific manner. Thus handling of degradation-prone bioptic material is inevitable. We established a serial qPCR assay based on increasing amplicon size to measure degradation status of any DNA sample. Using this approach we can exclude erroneous mtDNA quantification due to degraded samples (e.g. long post-exicision time, autolytic processus, freeze-thaw cycles) and ensure abnormal DNA content measurements (e.g. depletion) in non-degraded patient material. By preparation of degraded DNA under controlled conditions using sonification and DNaseI digestion we show that erroneous quantification is due to the different preservation qualities of the nuclear and the mitochondrial genome. This disparate degradation of the two genomes results in over- or underestimation of mtDNA copy number in degraded samples. Moreover, as analysis of defined archival tissue would allow to precise the molecular pathomechanism of mitochondrial disorders presenting with abnormal mtDNA content, we compared fresh frozen (FF) with formalin-fixed paraffin-embedded (FFPE) skeletal muscle tissue of the same sample. By extrapolation of measured decay constants for nuclear DNA (λnDNA) and mtDNA (λmtDNA) we present an approach to possibly correct measurements in degraded samples in the future. To our knowledge this is the first time different degradation impact of the two genomes is demonstrated and which evaluates systematically the impact of DNA degradation on quantification of mtDNA copy number.     

Real-time DNA quantification of nuclear and mitochondrial DNA in forensic analysis

The rapid development of molecular genetic analysis tools has made it possible to analyze most biological materialfound at the scene of a crime. Evidence materials containing DNA quantities too low to be analyzed using nuclear markers can be analyzed using the highly abundant mtDNA. However, there is a shortage of sensitive nDNA and mtDNA quantification assays. In this study, an assay for the quantification of very small amounts of DNA, based on the real-time Taq-Man assay, has been developed. This analysis will provide an estimate of the total number of nDNA copies and the total number of mtDNA molecules in a particular evidence material. The quantification is easy to perform, fast, and requires a minimum of the valuable DNA extracted from the evidence materiaL The results will aid in the evaluation of whether the specific sample is suitable for nDNA or mtDNA analysis. Furthermore, the optimal amount of DNA to be used in further analysis can be estimated ensuring that the analysis is successful and that the DNA is retained for future independent analysis. This assay has significant advantages over existing techniques because of its high sensitivity, accuracy, and the combined analysis of nDNA and mtDNA. Moreover, it has the potential to provide additional information about the presence of inhibitors in forensic samples. Subsequent mitochondrial and nuclear analysis of quantified samples illustrated the potential to predict the number of DNA copies required for a successful analysis in a certain typing assay.     

Cloning, physical mapping and genome organization of mitochondrial DNA from Cyprinus carpio oocytes

Summary The mitochondrial genome from Cyprinus carpio oocytes is a 10.5 megadalton, circular DNA molecule. The carp mitochondrial DNA was cloned in pBR325. Three recombinant plasmids accounted for the entire genome. Mapping of this DNA using 11 different restriction endonucleases is reported here. Both the large and small rRNA genes were then localized using Southern blot analysis. The subunit I of the cytochrome oxidase, the cytochrome b, the tRNA^Glu and the URF 4 genes were localized by nucleotide sequence analysis and homology studies with human mtDNA.Our results suggest that a similar gene order has been maintained in the mitochondrial genomes of Chordata and support the hypothesis of a common ancestor for all vertebrate organelle genomes.This study constitutes the first report on the genome organization of a fish mtDNA and provides information for further investigation in connection with sequence determination, replication, and gene expression in carp mitochondria.This work was supported by proyect RS-82-21 from the Universidad Austral de Chile and Grant N^o 1116 from Fondo Nacional de Desarrollo Cientifico y Tecnologico     

Unusual mitochondrial DNA polymorphism in two local populations of blue tit Parus caeruleus

Mitochondrial DNA (mtDNA) from 25 blue tits Parus caeruleus sampled from two populations of the Grenoble region (France) was assayed for polymorphism with 17 restriction endonucleases. Nine genotypes were found. Several mtDNA genotypes were also analysed by amplification via the polymerase chain reaction (PCR) and direct sequencing of 903 bp of the cytochrome b gene. The mtDNA polymorphism is greater in P. caeruleus than in other comparable bird species and results from the presence of two clearly differentiated mitochondrial lineages. Using the data of restriction polymorphism, the mean sequence divergence between individuals of the two lineages is 1.23%. Therefore, P. caeruleus should fall into the category II of phylogeographic pattern sensu Avise et al. (1987): discontinuous mtDNA genotypes which co-occur in the same region. P. caeruleus, like humans and other mobile species with high gene flow, seems to have lost its geographic structure in terms of mtDNA phylogeny. This unusual mitochondrial polymorphism can be explained by the recent admixture of two long-term isolated populations. This could be accounted for by two different scenarios. One assumes a simultaneous post-glacial colonization of the Grenoble region by two isolated European populations of P. caeruleus. Alternatively, hybridization between P. caeruleus and P. cyanus could have caused the observed pattern of mtDNA variation.     

Nuclear mitochondrial pseudogenes

As has been demonstrated recently, the transfer of genetic material from mitochondria to the nucleus and its integration into the nuclear genome is a continuous and dynamic process. Fragments of mitochondrial DNA (mtDNA) are incorporated in the nuclear genome as noncoding sequences, which are called nuclear mitochondrial pseudogenes (NUMT pseudogenes or NUMT inserts). In various eukaryotes, NUMT pseudogenes are distributed through different chromosomes to form a “library” of mtDNA fragments, providing important information on genome evolution. The escape of mtDNA from mitochondria is mostly associated with mitochondrial damage and mitophagy. Fragments of mtDNA may be integrated into nuclear DNA (nDNA) during repair of double-strand breaks (DSBs), which are caused by endogenous or exogenous agents. DSB repair of nDNA with a capture of mtDNA fragments may occur via nonhomologous end joining or a similar mechanism that involves microhomologous terminal sequences. An analysis of the available data makes it possible to suppose that the NUMT pseudogene formation rate depends on the DSB rate in nDNA, the activity of the repair systems, and the number of mtDNA fragments leaving organelles and migrating into the nucleus. Such situations are likely after exposure to damaging agents, first and foremost, ionizing radiation. Not only do new NUMT pseudogenes change the genome structure in the regions of their integration, but they may also have a significant impact on the actualization of genetic information. The de novo integration of NUMT pseudogenes in the nuclear genome may play a role in various pathologies and aging. NUMT pseudogenes may cause errors in PCR-based analyses of free mtDNA as a component of total cell DNA because of their coamplification.     

新生隐球菌线粒体的快速抽提和电镜观察

通过NovoZym234酶溶壁和低渗机械振荡破壁相结合,应用差速离心法分离并纯化了对数生长期的新生隐球菌线粒体,然后从经DNaseI处理的线粒体制备液中分离纯化线粒体DNA;并对差速离心中所获得的菌体、原生质体、线粒体三部分沉淀进行了透射电镜观察,结果均证明了我们所抽提的DNA是纯净的,适用于酶切分析和PCR分析研究,由此成功地建立了快速有效分离和纯化线粒体DNA的方法。 Abstract:Cryptococcus neoformans may be grown to the exponential phase,are broken by a combination of NovoZym234 and mechanical means,and mitochondrial DNA was extracted from DNaseI-treated mitrochondrial preparetion by differential centrifugation.Three pellets,including yeast cell,protoplasts,mitochondrial,were examined by transmission electronic microscopy.The resulting mtDNA is sufficicently pure for restriction endonucleases analysis and PCR in further studying.A rapid and effective method for the preparation of the mtDNA of C.neoformans was established.     

Polymerase chain reaction analysis of mitochondrial DNA polymorphism in N'Dama and Zebu cattle

A study of polymorphisms of mitochondrial DNA (mtDNA) of West African N'Dama (Bos taurus) and East African Zebu (B. indicus) cattle was carried out to obtain information on maternal phylogenetic relationships between these breeds. A relatively large sample size was made possible by using polymerase chain reaction (PCR) amplification of DNA prepared from small blood samples to generate fragments of two known polymorphic mtDNA regions, one within the gene encoding subunit 5 of NADH dehydrogenase and one encompassing the entire D-loop. This approach allowed us to achieve a higher resolution restriction analysis on mtDNA from more animals than would have been possible by conventional methods. PCR-amplified mtDNA of 58 animals from five populations was examined at 26 restriction sites by 16 enzymes. In this way 154 nucleotides of mtDNA were scanned for polymorphism. Six polymorphic sites were located by this means, five of which were within the D-loop and one of which was within the NADH dehydrogenase 5 gene. None of the polymorphisms observed could be con sidered typical of breed or type.     

Restriction enzyme analysis of mitochondrial DNA in colorectal tumours.

Total cellular DNA samples were isolated from 15 colorectal adenocarcinomas, 8 colon adenomas and their adjacent histologically normal colon mucosa. These DNA samples were digested separately with 13 different restriction endonucleases and analysed by Southern blot hybridization using a purified 32P-labelled human mtDNA probe. The fragment patterns from tumour mtDNA were compared to those from corresponding normal mtDNA. No evidence for large deletions, insertions, rearrangements or single base mutations in the detectable regions was detected. This suggests that other mechanisms may be responsible for the changes of colorectal tumour mitochondria.     

Molecular analysis of organelle DNA of different subspecies of rice and the genomic stability of mtDNA in tissue cultured cells of rice

Summary Chloroplast (ct) and mitochondrial (mt) DNAs were isolated from two subspecies of rice (Oryza sativa), japonica (Calrose 76) and indica (PI353705) and compared by restriction endonuclease fragment pattern analysis. Similarly, PI353705 (A5) mtDNA was also compared with the mtDNA of its long term tissue cultured line, BL2. Variation in the ctDNA of the 2 subspecies was detected with two (AvaI and BglI) of the 11 restriction endonucleases tested, whereas their mtDNAs showed considerable variation when restricted by PstI, BamHI, HindIII and XhoI endonucleases. Thus, the chloroplast DNA was more highly conserved than the mtDNA in the subspecies comparisons. Only minor variation was observed between the restriction endonuclease patterns of the mtDNAs of BL2 and A5. Southern blots of mtDNA were hybridized with heterologous probes from maize and spinach organelle genes. Differences were found in the hybridization patterns of the two subspecies for six of the eight (mitochondrial and chloroplast) probes tested. Two of the seven (mitochondrial) probes (coxII and 26S rRNA) detected tissue culture generated variation in mtDNA. The relative values of restriction endonuclease and hybridization patterns for studying phylogenetic and genetic relationships in rice are discussed.Florida Agricultural Experiment Station Journal Series No. 8807. Mention of a trademark or proprietary product does not constitute a guarantee or warranty of the product by the USDA, and does not imply its approval to the exclusion of other products that may also be suitable     

Mapping and characterization of polymorphism in mtDNA of Cryphonectria parasitica: evidence of the presence of an optional intron

The mitochondrial DNA (mtDNA) of the filamentous ascomycete Cryphonectria parasitica is large and polymorphic so, to better understand the nature of the polymorphisms within populations, a small collection of Italian strains of the fungus was examined. Known mtDNA polymorphisms were mapped and found to cluster in four regions of the mtDNA molecule, particularly in the RFLP region 2 where five different mtDNA haplotypes out of 13 strains were identified. This region included an area of 8.4kbp which was entirely sequenced in strain Ep155 showing the presence of two introns. An internal 3.2kbp portion was sequenced also in six additional strains. Sequence comparison of the C. parasitica mitochondrial intronic ORFs revealed similarities to known endonucleases such as those of Podospora anserina and Neurospora crassa. DNA sequence analysis showed that three polymorphisms of this mtDNA region within this population of 12 strains were due to the optional presence in the ND5 gene of an intron and of an intervening sequence within the intron. Evidence was also found within this population of mixed mitochondrial types within a single strain.     

Reconstructing the evolutionary history of China: a caveat about inferences drawn from ancient DNA

The decipherment of the meager information provided by short fragments of ancient mitochondrial DNA (mtDNA) is notoriously difficult but is regarded as a most promising way toward reconstructing the past from the genetic perspective. By haplogroup-specific hypervariable segment (HVS) motif search and matching or near-matching with available modern data sets, most of the ancient mtDNAs can be tentatively assigned to haplogroups, which are often subcontinent specific. Further typing for mtDNA haplogroup-diagnostic coding region polymorphisms, however, is indispensable for establishing the geographic/genetic affinities of ancient samples with less ambiguity. In the present study, we sequenced a fragment (approximately 982 bp) of the mtDNA control region in 76 Han individuals from Taian, Shandong, China, and we combined these data with previously reported samples from Zibo and Qingdao, Shandong. The reanalysis of two previously published ancient mtDNA population data sets from Linzi (same province) then indicates that the ancient populations had features in common with the modern populations from south China rather than any specific affinity to the European mtDNA pool. Our results highlight that ancient mtDNA data obtained under different sampling schemes and subject to potential contamination can easily create the impression of drastic spatiotemporal changes in the genetic structure of a regional population during the past few thousand years if inappropriate methods of data analysis are employed.