Fate of donor mitochondrial DNA in cloned bovine embryos produced by microinjection of cumulus cells

This study examined the fate of donor mitochondrial DNA during preimplantation development after nuclear transfer (NT) in cattle. Frozen-thawed cumulus cells were used as donor cells in the nuclear transfer. Mitochondrial DNA heteroplasmy in the nuclear transfer embryos was analyzed by allele-specific PCR (AS-PCR), direct DNA sequencing, and DNA chromatography. AS-PCR analysis for the detection of donor mitochondrial DNA was performed at the 1-, 2-, 4-, 8-, 16-cell, morula, and blastocyst stages of the embryos. The mitochondrial DNA from donor cells was detected at all developmental stages of the nuclear transfer embryos. However, mitochondrial DNA heteroplasmy was not observed in direct DNA sequencing of displacement-loop sequence from nuclear-transfer-derived blastocyst embryos. To confirm the mtDNA heteroplasmy in cloned embryos, the AS-PCR product from NT-derived blastocysts was analyzed by DNA sequencing and DNA chromatography. The nucleotides of NT-derived blastocysts were in accordance with the nucleotides from donor cells. These results indicate that the foreign cytoplasmic genome from donor cells was not destroyed by cytoplasmic events during preimplantation development that followed nuclear transfer.     

Metazoan OXPHOS gene families: evolutionary forces at the level of mitochondrial and nuclear genomes

Mitochondrial and nuclear DNAs contribute to encode the whole mitochondrial protein complement. The two genomes possess highly divergent features and properties, but the forces influencing their evolution, even if different, require strong coordination. The gene content of mitochondrial genome in all Metazoa is in a frozen state with only few exceptions and thus mitochondrial genome plasticity especially concerns some molecular features, i.e. base composition, codon usage, evolutionary rates. In contrast the high plasticity of nuclear genomes is particularly evident at the macroscopic level, since its redundancy represents the main feature able to introduce genetic material for evolutionary innovations. In this context, genes involved in oxidative phosphorylation (OXPHOS) represent a classical example of the different evolutionary behaviour of mitochondrial and nuclear genomes. The simple DNA sequence of Cytochrome c oxidase I (encoded by the mitochondrial genome) seems to be able to distinguish intra- and inter-species relations between organisms (DNA Barcode). Some OXPHOS subunits (cytochrome c, subunit c of ATP synthase and MLRQ) are encoded by several nuclear duplicated genes which still represent the trace of an ancient segmental/genome duplication event at the origin of vertebrates.     

Similarity of hnRNA sequences in blastula and pluteus stage sea urchin embryos

We have compared the total single-copy sequences transcribed as nuclear RNA in blastula and pluteus stage embryos of the sea urchin Tripneustes gratilla by hybridization of excess nuclear RNA with purified radioactive single-copy DNA. The kinetics of hybridization of either blastula or pluteus nuclear RNA with single-copy DNA show a single pseudo-first-order reaction with 34% of the single-copy genome. From the rate of the reaction and the purity of the nuclear RNA, it can be estimated that the reacting RNAs are present on the average at a concentration of one molecule per 14 nuclei. A mixture of blastula and pluteus RNA also hybridizes with 34% of the single-copy genome, indicating that the total complexity of RNAs transcribed at both stages is no greater than transcribed at each stage alone. The identity of the sequences transcribed by blastula and pluteus embryos was further examined by fractionation of the labeled DNA into sequences complementary and not complementary to pluteus RNA. This was achieved by hybridization of single-copy DNA to high pluteus RNA Cot, and separation of the hybridized and nonhybridized DNA on hydroxylapatite. Using either the DNA complementary or noncomplementary with pluteus RNA, essentially identical amounts of RNA:DNA hybrids are formed at high RNA Cot with blastula or pluteus RNA. Gross changes in the total RNA sequences transcribed do not appear to be involved in the developmental changes between blastula and pluteus, even though 45% of the mRNA sequences change between these two stages (Galau et al., 1976).     

Mitochondrial DNA as a non-invasive biomarker: accurate quantification using real time quantitative PCR without co-amplification of pseudogenes and dilution bias

Circulating mitochondrial DNA (MtDNA) is a potential non-invasive biomarker of cellular mitochondrial dysfunction, the latter known to be central to a wide range of human diseases. Changes in MtDNA are usually determined by quantification of MtDNA relative to nuclear DNA (Mt/N) using real time quantitative PCR. We propose that the methodology for measuring Mt/N needs to be improved and we have identified that current methods have at least one of the following three problems: (1) As much of the mitochondrial genome is duplicated in the nuclear genome, many commonly used MtDNA primers co-amplify homologous pseudogenes found in the nuclear genome; (2) use of regions from genes such as β-actin and 18S rRNA which are repetitive and/or highly variable for qPCR of the nuclear genome leads to errors; and (3) the size difference of mitochondrial and nuclear genomes cause a “dilution bias” when template DNA is diluted. We describe a PCR-based method using unique regions in the human mitochondrial genome not duplicated in the nuclear genome; unique single copy region in the nuclear genome and template treatment to remove dilution bias, to accurately quantify MtDNA from human samples.     

Preferential repair of nuclear matrix associated DNA in xeroderma pigmentosum complementation group C

The distribution of ultraviolet-induced DNA repair patches in the genome of xeroderma pigmentosum cells of complementation group C was investigated by determining the molecular weight distribution of repair labeled DNA and prelabeled DNA in alkaline sucrose gradients after treatment with the dimerspecific endonuclease V of bacteriophage T4. The results were consistent with the data reported by Mansbridge and Hanawalt (1983) and suggest that DNA-repair synthesis in xeroderma pigmentosum cells of complementation group C occurs in localized regions of the genome. Analysis of the spatial distribution of ultraviolet-induced repair patches in DNA loops attached to the nuclear matrix revealed that in xeroderma pigmentosum cells of complementation group C repair patches are preferentially situated near the attachment sites of DNA loops at the nuclear matrix. In normal human fibroblasts we observed no enrichment of repair-labeled DNA at the nuclear matrix and repair patches appeared to be distributed randomly along the DNA loops. The enrichment of repair-labeled DNA at the nuclear matrix in xeroderma pigmentosum cells of complementation group C may indicate that the residual DNA-repair synthesis in these cells occurs preferentially in transcribing regions of the genome.     

A large-subunit mitochondrial ribosomal DNA sequence translocated to the nuclear genome of two stone crabs (Menippe)

Two DNA sequences that appear to be homologous to large-subunit mitochondrial ribosomal RNA genes have been identified in the stone crabs Menippe mercenaria and M. adina. Amplification from whole genomic DNA by polymerase chain reaction (PCR) with oligonucleotide primers based on conserved portions of large-subunit mitochondrial rRNA genes consistently amplified two products of similar length (565 and 567 bp). These products differed at 3% of their nucleotide bases, and could be distinguished by a HindIII site. Only one of these sequences (designated the A sequence) was detected by PCR in purified mitochondrial DNA. The other (designated the B sequence) hybridized to total genomic DNA at a level consistent with a nuclear genome location. It is unlikely that the type B product would have been recognized as a nuclear copy by examination of its sequence alone. This is the first report of a mitochondrial gene sequence translocated into the nuclear genome of a crustacean.      

Mitochondrial DNA variations and nuclear RFLPs reflect different genetic similarities among 23 Arabidopsis thaliana ecotypes

The mitochondrial genome of 23 Arabidopsis thaliana ecotypes was analysed by Southern hybridization in total cellular DNA. Firstly, the extent of divergence between the mitochondrial genomes in closely related lines of one plant species and secondly, the use of mitochondrial versus nuclear RFLPs to determine evolutionary relationships between Arabidopsis ecotype isolates was investigated. Highly divergent stoichiometries of alternative mitochondrial genome arrangements characterize individual ecotypes including the complete loss of a 5 kb region from ecotype Landsberg without apparent effect on plant viability. The genetic similarities between ecotypes suggested by mitochondrial genome arrangements differ from those deduced from 18 nuclear RFLP loci (CAPS markers). Similarity of nuclear RFLP patterns among the 23 Arabidopsis ecotypes neitehr correlates with their geographic origin nor with the observed mitochondrial genome arrangements. A promiscuous mitochondrial sequence insertion previously identified in ecotype Columbia is also found in the nuclear genomes of ecotypes Eifel, Enkheim and Hilversum. Two ecotypes (Eifel and Tabor) displaying identical RFLP patterns at all 18 nuclear loci show differences in both this sequence transfer and a mitochondrial DNA recombination event.     

Molecular research technologies in mitochondrial diseases: the microarray approach

Mitochondria are ubiquitous in eukaryotic cells where they generate much of the cellular energy by the process of oxidative phosphorylation (OXPHOS). The approximately 1500 genes of the mitochondrial genome are distributed between the cytoplasmic, maternally-inherited, mitochondrial DNA (mtDNA) which encodes 37 genes and the nuclear DNA (nDNA) which encompasses the remaining mitochondrial genes. The interplay between the mtDNA and nDNA encoded mitochondrial genes and their role in mitochondrial disorders is still largely unclear. One approach for elucidating the pathophysiology of mitochondrial diseases has been to look at changes in the expression of mtDNA and nDNA-encoded genes in response to specific mitochondrial genetic defects. Initial studies of gene expression changes in response to mtDNA defect employed blot technologies to analyze changes in the expression of individual genes one at a time. While Southern/Northern blot experiments confirmed the importance of nDNA-mtDNA interactions in the pathophysiology of mitochondrial myopathy, the methodology used limited the number of genes that could be analyzed from each patient. This barrier has been overcome, in part by the advent of DNA microarray technology. In DNA microarrays gene sequences or oligonucleotides homologous to gene sequences are arrayed on a solid support. The RNA from the subject is then isolated, the mRNA converted to cDNA and the cDNA labeled with a fluorescent probe. The labeled cDNA is hybridized on the microarray and the fluorescence bound to each array is then quantified. Recently, these technologies have been applied to mitochondrial disease patient tissues and the presence of coordinate changes in mitochondrial gene expression confirmed.     

Rates of DNA Duplication and Mitochondrial DNA Insertion in the Human Genome

The hundreds of mitochondrial pseudogenes in the human nuclear genome sequence (numts) constitute an excellent system for studying and dating DNA duplications and insertions. These pseudogenes are associated with many complete mitochondrial genome sequences and through those with a good fossil record. By comparing individual numts with primate and other mammalian mitochondrial genome sequences, we estimate that these numts arose continuously over the last 58 million years. Our pairwise comparisons between numts suggest that most human numts arose from different mitochondrial insertion events and not by DNA duplication within the nuclear genome. The nuclear genome appears to accumulate mtDNA insertions at a rate high enough to predict within-population polymorphism for the presence/absence of many recent mtDNA insertions. Pairwise analysis of numts and their flanking DNA produces an estimate for the DNA duplication rate in humans of 2.2 × 10^–9 per numt per year. Thus, a nucleotide site is about as likely to be involved in a duplication event as it is to change by point substitution. This estimate of the rate of DNA duplication of noncoding DNA is based on sequences that are not in duplication hotspots, and is close to the rate reported for functional genes in other species.     

Mitochondrial DNA transfer to the nucleus generates extensive insertion site variation in maize

Mitochondrial DNA (mtDNA) insertions into nuclear chromosomes have been documented in a number of eukaryotes. We used fluorescence in situ hybridization (FISH) to examine the variation of mtDNA insertions in maize. Twenty overlapping cosmids, representing the 570-kb maize mitochondrial genome, were individually labeled and hybridized to root tip metaphase chromosomes from the B73 inbred line. A minimum of 15 mtDNA insertion sites on nine chromosomes were detectable using this method. One site near the centromere on chromosome arm 9L was identified by a majority of the cosmids. To examine variation in nuclear mitochondrial DNA sequences (NUMTs), a mixture of labeled cosmids was applied to chromosome spreads of ten diverse inbred lines: A188, A632, B37, B73, BMS, KYS, Mo17, Oh43, W22, and W23. The number of detectable NUMTs varied dramatically among the lines. None of the tested inbred lines other than B73 showed the strong hybridization signal on 9L, suggesting that there is a recent mtDNA insertion at this site in B73. Different sources of B73 and W23 were examined for NUMT variation within inbred lines. Differences were detectable, suggesting either that mtDNA is being incorporated or lost from the maize nuclear genome continuously. The results indicate that mtDNA insertions represent a major source of nuclear chromosomal variation.     

ING2 controls the progression of DNA replication forks to maintain genome stability

Inhibitor of growth 2 (ING2) is a candidate tumour suppressor gene the expression of which is frequently lost in tumours. Here, we identified a new function for ING2 in the control of DNA replication and in the maintenance of genome stability. Global replication rate was markedly reduced during normal S‐phase in small interfering RNA (siRNA) ING2 cells, as seen in a DNA fibre spreading experiment. Accordingly, we found that ING2 interacts with proliferating cell nuclear antigen and regulates its amount to the chromatin fraction, allowing normal replication progression and normal cell proliferation. Deregulation of DNA replication has been previously associated with genome instability. Hence, a high proportion of siRNA ING2 cells presented endoreduplication of their genome as well as an increased frequency of sister chromatid exchange. Thus, we propose for the first time that ING2 might function as a tumour suppressor gene by directly maintaining DNA integrity.     

Complete nucleotide sequence of the 6 kb element and conserved cytochrome b gene sequences among Indian isolates of Plasmodium falciparum.

The malaria parasite contains a nuclear genome with 14 chromosomes and two extrachromosomal DNA molecules of 6 kb and 35 kb in size. The smallest genome, known as the 6 kb element or mitochondrial DNA, has been sequenced from several Plasmodium falciparum isolates because this is a potential drug target. Here we describe the complete nucleotide sequence of this element from an Indian isolate of P. falciparum. It is 5967 bp in size and shows 99.6% homology with the 6 kb element of other isolates. The element contains three open reading frames for mitochondrial proteins-cytochrome oxidase subunit I (CoI), subunit III (CoIII) and cytochrome b (Cyb) which were found to be expressed during blood stages of the parasite. We have also sequenced the entire cyb gene from several Indian isolates of P. falciparum. The rate of mutation in this gene was very low since 12 of 14 isolates showed the identical sequence. Only one isolate showed a maximum change in five amino acids whereas the other isolate showed only one amino acid change. However, none of the Indian isolates showed any change in those amino acids of cyb which are associated with resistance to various drugs as these drugs are not yet commonly used in India.     

The yeast CDC9 gene encodes both a nuclear and a mitochondrial form of DNA ligase I.

BACKGROUND: The yeast CDC9 gene encodes a DNA ligase I activity required during nuclear DNA replication to ligate the Okazaki fragments formed when the lagging DNA strand is synthesised. The only other DNA ligase predicted from the yeast genome sequence, DNL4/LIG4, is specifically involved in a non-homologous DNA end-joining reaction. What then is the source of the DNA ligase activity required for replication of the yeast mitochondrial genome? RESULTS: We report that CDC9 encodes two distinct polypeptides expressed from consecutive in-frame AUG codons. Translational initiation at these two sites gives rise to polypeptides differing by a 23 residue amino-terminal extension, which corresponds to a functional mitochondrial pre-sequence sufficient to direct import into yeast mitochondria. Initiation at the first AUG codon results in a 755 amino-acid polypeptide that is imported into mitochondria, whereupon the pre-sequence is proteolytically removed to yield the mature mitochondrial form of Cdc9p. Initiation at the second AUG codon produces a 732 amino-acid polypeptide, which is localised to the nucleus. Cells expressing only the nuclear isoform were found to be specifically defective in the maintenance of the mitochondrial genome. CONCLUSIONS: CDC9 encodes two distinct forms of DNA ligase I. The first is targeted to the mitochondrion and is required for propagation and maintenance of mitochondrial DNA, the second localises to the nucleus and is sufficient for the essential cell-division function associated with this gene.     

Complete Mitochondrial Genome of the Medicinal Mushroom Ganoderma lucidum

Ganoderma lucidum is one of the well-known medicinal basidiomycetes worldwide. The mitochondrion, referred to as the second genome, is an organelle found in most eukaryotic cells and participates in critical cellular functions. Elucidating the structure and function of this genome is important to understand completely the genetic contents of G. lucidum. In this study, we assembled the mitochondrial genome of G. lucidum and analyzed the differential expressions of its encoded genes across three developmental stages. The mitochondrial genome is a typical circular DNA molecule of 60,630 bp with a GC content of 26.67%. Genome annotation identified genes that encode 15 conserved proteins, 27 tRNAs, small and large rRNAs, four homing endonucleases, and two hypothetical proteins. Except for genes encoding trnW and two hypothetical proteins, all genes were located on the positive strand. For the repeat structure analysis, eight forward, two inverted, and three tandem repeats were detected. A pair of fragments with a total length around 5.5 kb was found in both the nuclear and mitochondrial genomes, which suggests the possible transfer of DNA sequences between two genomes. RNA-Seq data for samples derived from three stages, namely, mycelia, primordia, and fruiting bodies, were mapped to the mitochondrial genome and qualified. The protein-coding genes were expressed higher in mycelia or primordial stages compared with those in the fruiting bodies. The rRNA abundances were significantly higher in all three stages. Two regions were transcribed but did not contain any identified protein or tRNA genes. Furthermore, three RNA-editing sites were detected. Genome synteny analysis showed that significant genome rearrangements occurred in the mitochondrial genomes. This study provides valuable information on the gene contents of the mitochondrial genome and their differential expressions at various developmental stages of G. lucidum. The results contribute to the understanding of the functions and evolution of fungal mitochondrial DNA.     

RAPD markers of mitochondrial origin exhibit lower population diversity and higher differentiation than RAPDs of nuclear origin in Douglas fir

We developed a method of screening RAPD markers for the presence of organelle DNA products using enriched organelle DNA probes, then used these markers to compare the structure of nuclear and mitochondrial RAPD diversity in Douglas fir. Of 237 screened RAPD fragments from 25 primers, 16% were identified as originating in the mitochondrial genome and 3% in the chloroplast genome. The mitochondrial DNA probe correctly distinguished fragments with known maternal inheritance (which is exclusive for the mitochondrial genome in the Pinaceae), and neither of the organelle probes hybridized to biparentally inherited fragments. Mitochondrial RAPD markers exhibited low diversity within populations compared to nuclear RAPD diversity ( H _S = 0.03 and 0.22, respectively), but were much more highly differentiated than were fragments of nuclear origin at both the population ( G _ST = 0.18 and 0.05, respectively) and racial levels ( G _ST = 0.72 and 0.25, respectively). Both nuclear and mitochondrial DNA based phylogenetic analyses identified the varieties as monophyletic groups; the nuclear RAPD markers further separated the north and south interior races.     

Is mitochondrial DNA content a potential biomarker of mitochondrial dysfunction?

Mitochondrial dysfunction is central to numerous diseases of oxidative stress. Changes in mitochondrial DNA (MtDNA) content, often measured as mitochondrial genome to nuclear genome ratio (Mt/N) using real time quantitative PCR, have been reported in a broad range of human diseases, such as diabetes and its complications, obesity, cancer, HIV complications, and ageing. We propose the hypothesis that MtDNA content in body fluids and tissues could be a biomarker of mitochondrial dysfunction and review the evidence supporting this theory. Increased reactive oxygen species resulting from an external trigger such as hyperglycaemia or increased fat in conditions of oxidative stress could lead to enhanced mitochondrial biogenesis, and increased Mt/N. Altered MtDNA levels may contribute to enhanced oxidative stress and inflammation and could play a pathogenic role in mitochondrial dysfunction and disease. Changes in Mt/N are detectable in circulating cells such as peripheral blood mononuclear cells and these could be used as surrogate to predict global changes in tissues and organs. We review a large number of studies reporting changes in MtDNA levels in body fluids such as circulating blood cells, cell free serum, saliva, sperm, and cerebrospinal fluid as well as in tumour and normal tissue samples. However, the data are often conflicting as the current methodology used to measure Mt/N can give false results because of one or more of the following reasons (1) use of mitochondrial primers which co-amplify nuclear pseudogenes (2) use of nuclear genes which are variable and/or duplicated in numerous locations (3) a dilution bias caused by the differing genome sizes of the mitochondrial and nuclear genome and (4) template preparation protocols which affect the yields of nuclear and mitochondrial genomes. Development of robust and reproducible methodology is needed to test the hypothesis that MtDNA content in body fluids is biomarker of mitochondrial dysfunction.     

The mitochondrial tRNAs of Trypanosoma brucei are nuclear encoded

The mitochondrial DNA of Trypanosoma brucei is organized as a catenated network of maxicircles and minicircles. The maxicircles are equivalent to the typical mitochondrial genome except that the genes for the mitochondrial tRNAs have not been identified by sequence analysis of the maxicircle DNA. The apparent absence of tRNA genes in the maxicircle DNA suggests that the mitochondrial tRNAs are encoded by either the minicircle or the nuclear DNA. In order to determine their genomic origin, we isolated and identified the mitochondrial tRNAs of T. brucei. We show that these mitochondrial tRNAs are truly mitochondrially located in vivo and that they are free from detectable contamination by cytosolic RNAs. By hybridization analysis, using mitochondrial tRNAs as the probe, we determined that the mitochondrial tRNAs are encoded by nuclear DNA. This implies that RNAs, like proteins, are imported into the mitochondria. We investigated the relationship between the cytosolic and the mitochondrial tRNA genes and show that there are unique cytosolic tRNA genes, unique mitochondrial tRNA genes, and tRNA genes which appear to be shared and whose products are therefore targeted to both the cytosol and the mitochondrion.     

Mitochondria-mediated nuclear mutator phenotype in Saccharomyces cerevisiae

Using Saccharomyces cerevisiae as a model organism, we analyzed the consequences of disrupting mitochondrial function on mutagenesis of the nuclear genome. We measured the frequency of canavanine-resistant colonies as a measure of nuclear mutator phenotype. Our data suggest that mitochondrial dysfunction leads to a nuclear mutator phenotype (i) when oxidative phosphorylation is blocked in wild-type yeast at mitochondrial complex III by antimycin A and (ii) in mutant strains lacking the entire mitochondrial genome (rho⁰) or those with deleted mitochondrial DNA (rho^–). The nuclear mutation frequencies obtained for antimycin A-treated cells as well as for rho^– and rho⁰ cells were ~2- to 3-fold higher compared to untreated control and wild-type cells, respectively. Blockage of oxidative phosphorylation by antimycin A treatment led to increased intracellular levels of reactive oxygen species (ROS). In contrast, inactivation of mitochondrial activity (rho^– and rho⁰) led to decreased intracellular levels of ROS. We also demonstrate that in rho⁰ cells the REV1, REV3 and REV7 gene products, all implicated in error-prone translesion DNA synthesis (TLS), mediate mutagenesis in the nuclear genome. However, TLS was not involved in nuclear DNA mutagenesis caused by inhibition of mitochondrial function by antimycin A. Together, our data suggest that mitochondrial dysfunction is mutagenic and multiple pathways are involved in this nuclear mutator phenotype.     

Ionizing radiation can activate the insertion of mitochondrial DNA fragments in the nuclear genome

In analytical review is considered the possibility of the insertion of mitochondrial DNA (mtDNA) fragments into the nuclear genome of cells, exposed ionizing radiation (IR). Many studies show that integration fragment mtDNA in nuclear genome, as well as its fastening as NUMT-pseudogenes, proceed at ancient periods of the evolutions not only, but also at more late periods. The number of the investigations shows that under influence endogenous reactive oxygen species, chemical agent, UV-light and IR mtDNA is damaged with greater frequency, than nucleus DNA. Furthermore, the repair systems in mitochondria are low efficiency. In irradiated by IR cells mtDNA fragments can transition from the mitochondria to the cytoplasm. The binding of mtDNA fragment to a complex with proteins provides them the protection from nuclease destroying. Possibly, at such safe condition they and are carried to nucleus. At inductions of DNA double-strand breaks (under the action of IR and activated their reparation) mtDNA fragments may be inserted to nuclear genome. Such integration of mtDNA to nuclear genome, with shaping NUMT-pseudogenes de novo, may be proceed in irradiated cells in the course of the reparations DNA double-strand breaks by the nonhomologous end-joining pathway. These insertions of mtDNA can cardinally change the structure of nuclear genomes in area of their introduction and render the essential influence upon the realization of genetic information. Available information in literature also allows to suppose that integration mtDNA in nuclear genome can proceed and at raised genomic instability observed in cells at post radiation period. It in equal extent pertains and to malignant cells with raised by instability mitochondrial and nuclear genomes. As the most efficient agent, initiating insertion fragment mtDNA in nuclear genome, is considered ionizing radiation.