Persistence of human mitochondrial DNA throughout the development to the blastocyst of mouse zygotes microinjected with human mitochondria

The conditions for transfer of human mitochondria into fertilised mouse ova were elaborated. Species-specific primers were designed to discriminate human mitochondrial DNA (mtDNA) and the endogenous mtDNA in the preimplantation embryos. Human mitochondria isolated from the HepG2 cell line were microinjected into murine zygotes, and the latter cultured for 96 h to the blastocyst stage. The polymerase chain reaction allowed the detection of human mtDNA at every stage of embryo cleavage. In some cases a clear disparity in distribution of human mtDNA among blastomeres was evident.     

Optical isolation of individual mitochondria ofPhysarum polycephalum for PCR analysis

Summary We attempted to amplify a specific region of mitochondrial DNA (mtDNA) using the polymerase chain reaction (PCR) from fewer than ten mitochondria isolated individually by microdissection or use of an optical tweezer. We selected preliminarily isolated mitochondria fromPhysarum polycephalum as the model materials and tried to amplify the mtDNA region corresponding to the specific mitochondrial plasmid of this true slime mould. For separation of a few mitochondria from the mitochondrial population, we initially used a destruction method in which excluded mitochondria were disrupted by a UV laser. However, mtDNA was still amplified, although weakly, from mitochondria that had been destroyed by the UV laser. Therefore, we used an optical tweezer to trap individual mitochondria and separate them from the others. The required number of mitochondria were separated from the mitochondrial suspension through a narrow canal of isolation buffer and used directly for PCR amplification. The results showed that the mtDNA could be amplified from at least 9 mitochondria trapped by the optical tweezer.Abbreviations DAPI 4,6-diamidino-2-phenylindole - EDTA ethylenediaminetetraacetic acid - mtDNA mitochondrial DNA - PCR polymerase chain reaction     

Partial purification and characterization of mitochondrial DNA polymerase from Plasmodium falciparum

Mitochondria of chloroquine-resistant Plasmodium falciparum (K1 strain) were isolated from mature trophozoites by differential centrifugation. The mitochondrial marker enzyme cytochrome c reductase was employed to monitor the steps of mitochondria isolation. Partial purification of DNA polymerase from P. falciparum mitochondria was performed using fast protein liquid chromatography (FPLC). DNA polymerase of P. falciparum mitochondria was characterized as a gamma-like DNA polymerase based on its sensitivity to the inhibitors aphidicolin, N-ethylmaleimide and 9-beta-D-arabinofuranosyladenine-5'-triphosphate. In contrast, the enzyme was found to be strongly resistant to 2',3'-dideoxythymidine-5'-triphosphate (IC(50)>400 microM) and differed in this aspect from the human homologue, possibly indicating structural differences between human and P. falciparum DNA polymerase gamma. In addition, the DNA polymerase of parasite mitochondria was shown to be resistant (IC(50)>1 mM) to the nucleotide analogue (S)-1-[3-hydroxy-2-phosphonylmethoxypropyl]adenine diphosphate (HPMPApp).     

In vitro replication of human mitochondrial DNA: accurate initiation at the origin of light-strand synthesis

Synthesis of human light-strand mitochondrial DNA was accomplished in vitro using DNA primase, DNA polymerase, and other accessory proteins isolated from human mitochondria. Replication begins with the synthesis of primer RNA on a T-rich sequence in the origin stem-loop structure of the template DNA and absolutely requires ATP. A transition from RNA synthesis to DNA synthesis occurs near the base of the stem-loop structure and a potential recognition site for signaling that transition has been identified. The start sites of the in vitro products were mapped at the nucleotide level and were found to be in excellent agreement with those of in vivo nascent light-strand DNA. Isolated human mitochondrial enzymes recognize and utilize the bovine, but not the mouse, origin of light-strand replication.     

Long patch base excision repair in mammalian mitochondrial genomes

The mitochondrial genome is highly susceptible to damage by reactive oxygen species (ROS) generated endogenously as a byproduct of respiration. ROS-induced DNA lesions, including oxidized bases, abasic (AP) sites, and oxidized AP sites, cause DNA strand breaks and are repaired via the base excision repair (BER) pathway in both the nucleus and mitochondria. Repair of damaged bases and AP sites involving 1-nucleotide incorporation, named single nucleotide (SN)-BER, was observed with mitochondrial and nuclear extracts. During SN-BER, the 5'-phosphodeoxyribose (dRP) moiety, generated by AP-endonuclease (APE1), is removed by the lyase activity of DNA polymerase gamma (pol gamma) and polymerase beta in the mitochondria and nucleus, respectively. However, the repair of oxidized deoxyribose fragments at the 5' terminus after strand break would require 5'-exo/endonuclease activity that is provided by the flap endonuclease (FEN-1) in the nucleus, resulting in multinucleotide repair patch (long patch (LP)-BER). Here we show the presence of a 5'-exo/endonuclease in the mitochondrial extracts of mouse and human cells that is involved in the repair of a lyase-resistant AP site analog via multinucleotide incorporation, upstream and downstream to the lesion site. We conclude that LP-BER also occurs in the mitochondria requiring the 5'-exo/endonuclease and pol gamma with 3'-exonuclease activity. Although a FEN-1 antibody cross-reacting species was detected in the mitochondria, it was absent in the LP-BER-proficient APE1 immunocomplex isolated from the mitochondrial extract that contains APE1, pol gamma, and DNA ligase 3. The LP-BER activity was marginally affected in FEN-1-depleted mitochondrial extracts, further supporting the involvement of an unidentified 5'-exo/endonuclease in mitochondrial LP-BER.     

Studies on nuclear and mitochondrial DNA-replication in a temperature-sensitive mutant of Saccharomyces cerevisiae

Summary In a yeast mutant (198 D1) exhibiting temperature sensitive DNA replication, incubation at the restrictive temperature influences both nuclear and mitochondrial DNA synthesis but to different degrees, the mitochondrial DNA being less affected. DNA polymerase activities measurable in mitochondria free cell extracts as well as in the extract from isolated mitochondria are found to be unaffected at the restrictive temperature. The level of DNA polymerase in the cell extract is elevated in comparison to the wild type strain. Furthermore, the tight coupling of DNA replication to protein synthesis usually observed in yeast is partly lost in the mutant.This work is dedicated to Professor O. Hoffmann-Ostenhof on the occasion of his 60th birthday.     

Activation of mitochondrial DNA synthesis during loach embryogenesis

Mitochondria isolated from unfertilized loach (Misgurnus fossilis) eggs incorporate 3H-dTTP at a low rate (0,01 pmoles 3H-dTTP-mg of mitochondrial protein/1 hr incubation). After fertilization the rate of 3H-dTTP incorporation into DNA of mitochondria isolated from embryos of different developmental stages increases exponentially, doubling each 7 hours, and attains the maximum to 35 hour of development. This stage corresponds to the beginning of movement. DNA synthesis in mitochondria from unfertilized eggs resembles repair; as early as 6 hours after fertilization the labeling pattern of mt-DNA is of replicative type. This replicative type of labeling is observed throughout all early development. Activation of mt-DNA biosynthesis in the course of early development is not accompanied by any changes of DNA polymerase activity in mitochondrial extracts or in mitochondrial lysates.     

Identification of a beta-like DNA polymerase activity in bovine heart mitochondria

A new DNA polymerase activity, distinct from DNA polymerase gamma, has been identified in bovine heart mitochondria. First detected among proteins isolated in a complex with mitochondrial DNA, the DNA polymerase activity has been partially purified 47,000-fold. Enzyme activity separates from DNA polymerase gamma on several chromatographic columns and appears to copurify with a 38 +/- 2-kDa polypeptide. Unlike DNA polymerase gamma, this enzyme is relatively resistant to inhibition by N-ethylmaleimide and dideoxynucleotides, has moderately low monovalent and high divalent cation requirements, and possesses 20-fold-higher apparent K(m) values for deoxynucleotides. The enzyme polymerizes deoxynucleotides onto a primed template DNA in a relatively nonprocessive fashion and lacks a detectable 3' to 5' exonuclease activity. Many of these characteristics resemble a beta-like mitochondrial DNA polymerase previously identified in, and considered unique to, trypanosomes. We propose that the bovine and trypanosomal enzymes are related and represent a new class of ubiquitous mitochondrial DNA polymerases.     

Identity of DNA polymerase gamma from synaptosomal mitochondria and rat-brain nuclei

DNA polymerase gamma and mitochondrial DNA polymerase were isolated from brain nuclei and synaptosomes respectively. The presence of a single DNA polymerase in synaptosomal mitochondria was established by chromatography on DEAE-cellulose, phosphocellulose and DNA-cellulose, as well as by sedimentation analysis and isoelectric focusing. A great similarity between the purified nuclear DNA polymerase gamma and the mitochondrial enzyme was found by the following criteria: chromatographic behaviour in three column systems; essentially complete inhibition by N-ethyl-maleimide (2 mM); optimal requirements of Mn2+ (0.1 mM), Mg2+ (5 mM) and pH (8.0); template preferences, poly(A) - (dT)20-25 larger than activated DNA larger than poly(dA) - (dT)12-18; lack of activity on single-stranded polynucleotides and (dT)12-primed mRNA; molecular weight (180000), sedimentation (9.2 S) and isoelectric point (pI 5.4). We therefore conclude that brain nuclear DNA polymerase gamma and synaptosomal mitochondrial DNA polymerase are closely related and may even be identical.     

DNA polymerase β: A missing link of the base excision repair machinery in mammalian mitochondria

Mitochondrial genome integrity is fundamental to mammalian cell viability. Since mitochondrial DNA is constantly under attack from oxygen radicals released during ATP production, DNA repair is vital in removing oxidatively generated lesions in mitochondrial DNA, but the presence of a strong base excision repair system has not been demonstrated. Here, we addressed the presence of such a system in mammalian mitochondria involving the primary base lesion repair enzyme DNA polymerase (pol) β. Pol β was localized to mammalian mitochondria by electron microscopic-immunogold staining, immunofluorescence co-localization and biochemical experiments. Extracts from purified mitochondria exhibited base excision repair activity that was dependent on pol β. Mitochondria from pol β-deficient mouse fibroblasts had compromised DNA repair and showed elevated levels of superoxide radicals after hydrogen peroxide treatment. Mitochondria in pol β-deficient fibroblasts displayed altered morphology by electron microscopy. These results indicate that mammalian mitochondria contain an efficient base lesion repair system mediated in part by pol β and thus pol β plays a role in preserving mitochondrial genome stability.     

Mouse zygotes injected with mitochondria develop normally but the exogenous mitochondria are not detectable in the progeny

A microinjection procedure to introduce "paternal" mitochondria from a source other than spermatozoa into fertilized mouse eggs is described. When a mitochondrial suspension isolated from the testes or liver of Mus molossinus mice was microinjected into fertilized eggs of CD1 mice, the microinjected zygotes survived, developed normally, and offspring were produced. Mus molossinus mitochondrial DNA can be distinguished from CD1 mitochondrial DNA by Southern blot analyses using restriction enzymes such as Eco R1, Xba 1, or Spe 1. Although up to 120 viable mitochondria were injected, no exogenous mitochondrial DNA was detected in fetal samples or in the brain, liver, heart, testis, or ovary of the mature progeny. Under the experimental conditions used, similar results were obtained when mitochondria from the testes of New Zealand black mice or from testes of Syrian hamsters were microinjected into fertilized CD1 mouse eggs. Failure to detect the exogenous mitochondrial DNA under our assay conditions suggests that microinjected mitochondria from testis or liver did not selectively replicate during embryonic development. The "foreign" mitochondria appear to have the same fate during early embryogenesis as the mitochondria of the spermatozoon.     

RNA biosynthesis in mitochondria under conditions of prolonged inhibition of protein biosynthesis in rat liver cytoplasm]

When cytoplasmic protein synthesis is inhibited by cycloheximide (CHI) in vivo synthesis of water-soluble mitochondrial proteins and of mitochondrial RNA is decreased. These changes measured in isolated rat liver mitochondria are similar to those observed in vivo and correlate with the changes the synthesis of water-soluble proteins in mitochondria. When the cytoplasmic fraction (30,000 g-supernatant) had been added to the mitochondria showing decreased RNA synthesis, the RNA synthesis increased to the control level (the incubation conditions were favourable for the protein transport from microsomes to mitochondria). RNA synthesis in mitochondria was not stimulated by cytoplasmic fractions from the CHI-pretreated rats. After prolonged dialysis these fraction stimulated RNA synthesis even to a greater extent than cytoplasmic fractions from the untreated animals. Mitochondrial RNA polymerase activity (measured in mitochondrial extracts supplemented with exogenous DNA) was higher in extracts of mitochondria from livers of normal rats than in extracts of mitochondria from livers of animals injected with CHI.     

Isolation and characterization of a mitochondrial RNA polymerase from Drosophila melanogaster

A DNA-dependent RNA polymerase was solubilized from sucrose gradient isolated, DNase-treated mitochondria of Drosophila melanogaster. The isolated mitochondria were not detectably contaminated with nuclear DNA as shown by CsCl gradient centrifugation and polylysine Kieselguhr chromatography. The detergent-solubilized RNA polymerase was sensitive to rifampicin, resistant to alpha-amanitin, had an apparent molecular mass of about 60 kilodaltons, and displayed a tendency to aggregate, both in crude extracts or when purified. The mitochondrial RNA polymerase could be distinguished from nuclear RNA polymerases on the basis of size, salt optima, rifampicin sensitivity, and alpha-amanitin resistance.     

Proteins associated with mitochondrial DNA protect it against the action of X-rays and hydrogen peroxide

It has been suggested in a number of investigations that the high vulnerability of mitochondrial DNA to reactive oxygen species and other damaging agents is due to the absence in mitochondria of histones complexed with DNA. In the present study it was shown that DNA-binding proteins of mitochondrial nucleoids were able to shield mitochondrial DNA from X-ray radiation and hydrogen peroxide, as nuclear histones did. Mitochondria, mitochondrial nucleoid proteins, and histones were isolated from mouse liver cells. The degree of damage to or protection of mitochondrial DNA was assessed from the yield of its PCR amplification product. The in vitro experiments demonstrated that mouse mitochondrial DNA, when in complex with mitochondrial nucleoids or nuclear histones, was damaged much less by radiation and/or hydrogen peroxide than in the absence of these proteins and histones. No significant difference between mitochondrial nucleoid proteins and nuclear histones was revealed in their efficiency to protect mitochondrial DNA from the damaging effect of radiation and hydrogen peroxide. It is likely that the nucleoid proteins in the mitochondria shield mitochondrial DNA against the attack of reactive oxygen species, thus significantly decreasing the level of the oxidative damage to mitochondrial DNA.     

Subcellular localization of DNA polymerase gamma and changes in its activity in sea urchin embryos

1. Subcellular localization and changes in the activity of DNA polymerase gamma were examined in sea urchin eggs and embryos. 2. The enzyme was shown to be localized predominantly in mitochondria by differential and isopycnic centrifugation. 3. During embryogenesis, the enzyme activity per embryo remained constant until blastula stage, and thereafter increased. 4. Similarly mitochondrial DNA per embryo increased, indicating that mitochondrial DNA replication starts during embryogenesis. 5. The gamma-activity per mitochondrial DNA remained constant during embryogenesis. 6. These results suggest that mitochondria contain a constant amount of replicative enzyme (DNA polymerase gamma) regardless of mitochondrial DNA replication, which differs from the case of nuclear DNA replication.