Transferring isolated mitochondria into tissue culture cells

We have developed a new method for introducing large numbers of isolated mitochondria into tissue culture cells. Direct microinjection of mitochondria into typical mammalian cells has been found to be impractical due to the large size of mitochondria relative to microinjection needles. To circumvent this problem, we inject isolated mitochondria through appropriately sized microinjection needles into rodent oocytes or single-cell embryos, which are much larger than tissue culture cells, and then withdraw a ‘mitocytoplast’ cell fragment containing the injected mitochondria using a modified holding needle. These mitocytoplasts are then fused to recipient cells through viral-mediated membrane fusion and the injected mitochondria are transferred into the cytoplasm of the tissue culture cell. Since mouse oocytes contain large numbers of mouse mitochondria that repopulate recipient mouse cells along with the injected mitochondria, we used either gerbil single-cell embryos or rat oocytes to package injected mouse mitochondria. We found that the gerbil mitochondrial DNA (mtDNA) is not maintained in recipient rho0 mouse cells and that rat mtDNA initially replicated but was soon completely replaced by the injected mouse mtDNA, and so with both procedures mouse cells homoplasmic for the mouse mtDNA in the injected mitochondria were obtained.     

Deletion of mtDNA disrupts mitochondrial function and structure, but not biogenesis

The role of nuclear DNA (nDNA)-encoded proteins in the regulation of mitochondrial fission and fusion has been documented, yet the role of mitochondrial DNA (mtDNA) and encoded proteins in mitochondrial biogenesis remains unknown. Long-term treatment of a lymphoblastoid cell line Molt-4 with ethidium bromide generated mtDNA-deficient rho0 mutants. Depletion of mtDNA in rho0 cells produced functional and morphological changes in mitochondria without affecting the nuclear genome and encoded proteins. Indeed, the gene encoding subunit II of mitochondrial cytochrome c oxidase (COX II), a prototypical mitochondrial gene, was reduced in rho0 mutants blunting the activity of mitochondrial cytochrome coxidase. Yet, the amount of the nuclear beta-actin gene and the activity of citrate synthase, a mitochondrial matrix enzyme encoded by nDNA, remained unaffected in rho0 cells. Loss of mtDNA in rho0 cells was associated with significant distortion of mitochondrial structure, decreased electron density of the matrix and disorganized inner and outer membranes, resulting in the appearance of 'ghost-like' mitochondria. However, the number of mitochondria-like structures was not significantly different between mtDNA-deficient and parental cells. Thus, we conclude that cells lacking mtDNA still generate mitochondrial scaffolds, albeit with aberrant function.     

The presence of intact mitochondrial DNA in HeLa cell nuclei.

Restriction analysis of DNA labelled with [32P]dCTP in an in vitro replication system with isolated nuclei from early S phase cells showed preferential labelling of restriction fragments derived from mitochondrial DNA (mtDNA) by a replication machinery distinct from that responsible for bulk nuclear DNA replication. Use of restriction nucleases with one recognition site in mtDNA gave rise to 16.5 kbp long fragments corresponding to full-length linearized mtDNA, indicating the presence of intact mtDNA in the isolated cell nuclei. Incorporation of dNTPs into mtDNA was not restricted to the S phase of the cell cycle. We were unable to increase the labelling of mtDNA by the addition of purified mitochondria or mtDNA to the nuclear replication system. These and other results presented is evidenced that the presence of mtDNA in the isolated nuclei was not due to uptake during preparation, thus indicating its presence in the cell nucleus in vivo.     

Transmissible mitochondrial hypovirulence in a natural population of Cryphonectria parasitica

A cytoplasmically transmissible hypovirulence syndrome has been identified in virus-free strains of the chestnut blight fungus Cryphonectria parasitica isolated from healing cankers on American chestnut trees in southwestern Michigan. The syndrome is associated with symptoms of fungal senescence, including a progressive decline in the growth potential and abundance of conidia, and elevated levels of respiration through the cyanide-insensitive alternative oxidase pathway. Conidia from senescing mycelia exhibited varying degrees of senescence ranging from normal growth to death soon after germination. Cytoplasmic transmission of hypovirulence between mycelia occurred by hyphal contact and coincided with the transfer of a specific restriction fragment length polymorphism from the mitochondrial DNA (mtDNA) of the donor strains into the mtDNA of virulent recipients. The transmission of the senescence phenotype was observed not only among vegetatively compatible strains but also among incompatible strains. Hypovirulence was present in isolates from the same location with different nuclear genotypes as identified by DNA fingerprinting. This study confirms that mitochondrial hypovirulence can occur spontaneously and spread within a natural population of a phytopathogenic fungus.     

Mannitol 1-phosphate metabolism is required for sporulation in planta of the wheat pathogen Stagonospora nodorum

An expressed sequence tag encoding a putative mannitol 1-phosphate dehydrogenase (Mpd1) has been characterized from the fungal wheat pathogen Stagonospora nodorum. Mpd1 was disrupted by insertional mutagenesis, and the resulting mpd1 strains lacked all detectable NAD-linked mannitol 1-phosphate dehydrogenase activity (EC 1.1.1.17). The growth rates, sporulation, and spore viability of the mutant strains in vitro were not significantly different from the wild type. The viability of the mpd1 spores when subjected to heat stress was comparable to wild type. Characterization of the sugar alcohol content by nuclear magnetic resonance spectroscopy revealed that, when grown on glucose, the mutant strains contained significantly less mannitol, less arabitol, but more trehalose than the wild-type strains. The mannitol content of fructose-grown cultures was normal. No secreted mannitol could be detected in wild type or mutants. Pathogenicity assays revealed the disruption of Mpd1 did not affect lesion development, however the mutants were unable to sporulate. These results throw new light on the role of mannitol in fungal plant interactions, suggesting a role in metabolic and redox regulation during the critical process of sporulation on senescing leaf material.     

Fate of parental mitochondria in embryonic stem hybrid cells

In hybrid cells, not only are the nuclear genomes of parent cells fused, but their cytoplasm is as well. Mitochondrial DNA (mtDNA) is a convenient marker of cytoplasm that allows us to gain insight into the organization of hybrid-cell cytoplasm. We analyzed the parental mtDNA in hybrid cells resulting from the fusion of Mus musculus embryonic stem (ES) cells with splenocytes and fetal fibroblasts of DD/c mice or with splenocytes of M. caroli. Identification of parental mtDNA in hybrid cells was based on polymorphism among parental mtDNA for certain restriction endonucleases. We found that intra- and interspecific ES cell-splenocyte hybrid cells either entirely or partially lost mtDNA derived from a somatic partner, whereas ES cell-fibroblast hybrids retained mtDNA from both parents in similar ratios with a slight bias. The loss of somatic mitochondria by ES-splenocyte hybrids implies a nonrandom segregation of parental mitochondria, which was supported by a computer simulation of genetic drift. In contrast, ES cell-fibroblast hybrids show bilateral random segregation of the parental mitochondria judging from the analysis of mtDNA in single cells. Preferential segregation of somatic mitochondria does not depend on the differences in sequences of the parental mtDNA, but rather on the replicative state of parental cells.     

Role of polynucleotide kinase/phosphatase in mitochondrial DNA repair

Mutations in mitochondrial DNA (mtDNA) are implicated in a broad range of human diseases and in aging. Compared to nuclear DNA, mtDNA is more highly exposed to oxidative damage due to its proximity to the respiratory chain and the lack of protection afforded by chromatin-associated proteins. While repair of oxidative damage to the bases in mtDNA through the base excision repair pathway has been well studied, the repair of oxidatively induced strand breaks in mtDNA has been less thoroughly examined. Polynucleotide kinase/phosphatase (PNKP) processes strand-break termini to render them chemically compatible for the subsequent action of DNA polymerases and ligases. Here, we demonstrate that functionally active full-length PNKP is present in mitochondria as well as nuclei. Downregulation of PNKP results in an accumulation of strand breaks in mtDNA of hydrogen peroxide-treated cells. Full restoration of repair of the H(2)O(2)-induced strand breaks in mitochondria requires both the kinase and phosphatase activities of PNKP. We also demonstrate that PNKP contains a mitochondrial-targeting signal close to the C-terminus of the protein. We further show that PNKP associates with the mitochondrial protein mitofilin. Interaction with mitofilin may serve to translocate PNKP into mitochondria.     

The mitochondrial cycle of Arabidopsis shoot apical meristem and leaf primordium meristematic cells is defined by a perinuclear tentaculate/cage-like mitochondrion

Plant cells exhibit a high rate of mitochondrial DNA (mtDNA) recombination. This implies that before cytokinesis, the different mitochondrial compartments must fuse to allow for mtDNA intermixing. When and how the conditions for mtDNA intermixing are established are largely unknown. We have investigated the cell cycle-dependent changes in mitochondrial architecture in different Arabidopsis (Arabidopsis thaliana) cell types using confocal microscopy, conventional, and three-dimensional electron microscopy techniques. Whereas mitochondria of cells from most plant organs are always small and dispersed, shoot apical and leaf primordial meristematic cells contain small, discrete mitochondria in the cell periphery and one large, mitochondrial mass in the perinuclear region. Serial thin-section reconstructions of high-pressure-frozen shoot apical meristem cells demonstrate that during G1 through S phase, the large, central mitochondrion has a tentaculate morphology and wraps around one nuclear pole. In G2, both types of mitochondria double their volume, and the large mitochondrion extends around the nucleus to establish a second sheet-like domain at the opposite nuclear pole. During mitosis, approximately 60% of the smaller mitochondria fuse with the large mitochondrion, whose volume increases to 80% of the total mitochondrial volume, and reorganizes into a cage-like structure encompassing first the mitotic spindle and then the entire cytokinetic apparatus. During cytokinesis, the cage-like mitochondrion divides into two independent tentacular mitochondria from which new, small mitochondria arise by fission. These cell cycle-dependent changes in mitochondrial architecture explain how these meristematic cells can achieve a high rate of mtDNA recombination and ensure the even partitioning of mitochondria between daughter cells.     

Bromodeoxyuridine 5'-monophosphate incorporation into yeast nuclear and mitochondrial deoxyribonucleic acid.

Standard laboratory yeast strains can be enriched for thymidine 5'-monophosphate (TMP) uptake derivatives that generate only a low percentage of respiratory-deficient colonies (petites) under inhibition of TMP biosynthesis. Such mutants incorporated bromodeoxyuridine 5'-monophosphate (BrdUMP) into both nuclear and mitochondrial deoxyribonucleic acid (mtDNA); however, they showed a selectivity for TMP over BrdUMP incorporation. The preferential incorporation of [3H]TMP or BrdUMP into mtDNA was strain dependent. The density increments after growth in the presence of BrdUMP reached 50 mg/ml for nuclear DNA and 22 mg/ml for mtDNA in CsCl gradients. Density shifts corresponding to 4% bromouracil substitution were easily detected. Preliminary density transfer experiments confirm that mtDNA does not replicate in synchrony with nuclear DNA.     

Interaction theory of mammalian mitochondria.

We generated mice with deletion mutant mtDNA by its introduction from somatic cells into mouse zygotes. Expressions of disease phenotypes are limited to tissues expressing mitochondrial dysfunction. Considering that all these mice share the same nuclear background, these observations suggest that accumulation of the mutant mtDNA and resultant expressions of mitochondrial dysfunction are responsible for expression of disease phenotypes. On the other hand, mitochondrial dysfunction and expression of clinical abnormalities were not observed until the mutant mtDNA accumulated predominantly. This protection is due to the presence of extensive and continuous interaction between exogenous mitochondria from cybrids and recipient mitochondria from embryos. Thus, we would like to propose a new hypothesis on mitochondrial biogenesis, interaction theory of mitochondria: mammalian mitochondria exchange genetic contents, and thus lost the individuality and function as a single dynamic cellular unit.     

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.     

Expression of Rattus norvegicus mtDNA in Mus musculus cells results in multiple respiratory chain defects

The production of in vitro and in vivo models of mitochondrial DNA (mtDNA) defects is currently limited by a lack of characterized mouse cell mtDNA mutants that may be expected to model human mitochondrial diseases. Here we describe the creation of transmitochondrial mouse (Mus musculus) cells repopulated with mtDNA from different murid species (xenomitochondrial cybrids). The closely related Mus spretus mtDNA is readily maintained when introduced into M. musculus mtDNA-less (rho(0)) cells, and the resulting cybrids have normal oxidative phosphorylation (OXPHOS). When the more distantly related Rattus norvegicus mtDNA is transferred to the mouse nuclear background the mtDNA is replicated, transcribed, and translated efficiently. However, function of several OXPHOS complexes that depend on the coordinated assembly of nuclear and mtDNA-encoded proteins is impaired. Complex I activity in the Rattus xenocybrid was 46% of the control mean; complex III was 37%, and complex IV was 78%. These defects combined to restrict maximal respiration to 12-31% of the control and M. spretus xenocybrids, as measured polarographically using isolated cybrid mitochondria. These defects are distinct to those previously reported for human/primate xenocybrids. It should be possible to produce other mouse xenocybrid constructs with less severe OXPHOS phenotypes, to model human mtDNA diseases.     

Mitochondria are inherited from the MATa parent in crosses of the basidiomycete fungus Cryptococcus neoformans

Previous studies demonstrated that mitochondrial DNA (mtDNA) was uniparentally transmitted in laboratory crosses of the pathogenic yeast Cryptococcus neoformans. To begin understanding the mechanisms, this study examined the potential role of the mating-type locus on mtDNA inheritance in C. neoformans. Using existing isogenic strains (JEC20 and JEC21) that differed only at the mating-type locus and a clinical strain (CDC46) that possessed a mitochondrial genotype different from JEC20 and JEC21, we constructed strains that differed only in mating type and mitochondrial genotype. These strains were then crossed to produce hyphae and sexual spores. Among the 206 single spores analyzed from six crosses, all but one inherited mtDNA from the MATa parents. Analyses of mating-type alleles and mtDNA genotypes of natural hybrids from clinical and natural samples were consistent with the hypothesis that mtDNA is inherited from the MATa parent in C. neoformans. To distinguish two potential mechanisms, we obtained a pair of isogenic strains with different mating-type alleles, mtDNA types, and auxotrophic markers. Diploid cells from mating between these two strains were selected and 29 independent colonies were genotyped. These cells did not go through the hyphal stage or the meiotic process. All 29 colonies contained mtDNA from the MATa parent. Because no filamentation, meiosis, or spore formation was involved in generating these diploid cells, our results suggest a selective elimination of mtDNA from the MATalpha parent soon after mating. To our knowledge, this is the first demonstration that mating type controls mtDNA inheritance in fungi.     

The FANCM family Mph1 helicase localizes to the mitochondria and contributes to mtDNA stability

Mitochondria are membrane-bound organelles found in eukaryotic cells where they generate energy through the respiratory chain. They contain their own genome that encodes genes critical to the mitochondrial function, but most of their protein content is synthetized from nuclear encoded genes. Damages to the mtDNA can cause mutations and rearrangements with an impact on the respiratory functions of the cell. DNA repair factors are able to localize to mitochondria to restore mtDNA integrity and ensure its proper inheritance. We describe in this article the mitochondrial localization of the Mph1/FANCM helicase that serves critical roles in nuclear DNA repair processes. Mph1 localizes to mitochondria and its functions contribute to the mtDNA integrity under mtDNA damaging conditions.     

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.     

Uracil-DNA glycosylase-deficient yeast exhibit a mitochondrial mutator phenotype

Mutations in mitochondrial DNA (mtDNA) have been reported in cancer and are involved in the pathogenesis of many mitochondrial diseases. Uracil-DNA glycosylase, encoded by the UNG1 gene in Saccharomyces cerevisiae, repairs uracil in DNA formed due to deamination of cytosine. Our study demonstrates that inactivation of the UNG1 gene leads to at least a 3-fold increased frequency of mutations in mtDNA compared with the wild-type. Using a Ung1p–green fluorescent protein (GFP) fusion construct, we demonstrate that yeast yUng1–GFP protein localizes to both mitochondria and the nucleus, indicating that Ung1p must contain both a mitochondrial localization signal (MLS) and a nuclear localization signal. Our study reveals that the first 16 amino acids at the N-terminus contain the yUng1p MLS. Deletion of 16 amino acids resulted in the yUng1p–GFP fusion protein being transported to the nucleus. We also investigated the intracellular localization of human hUng1p–GFP in yeast. Our data indicate that hUng1p–GFP predominately localizes to the mitochondria. Further analysis identified the N-terminal 16 amino acids as important for localization of hUng1 protein into the mitochondria. Expression of both yeast and human UNG1 cDNA suppressed the frequency of mitochondrial mutation in UNG1-deficient cells. However, expression of yUNG1 in wild-type cells increased the frequency of mutations in mtDNA, suggesting that elevated expression of Ung1p is mutagenic. An increase in the frequency of mitochondrial mutants was also observed when hUNG1 site-directed mutants (Y147C and Y147S) were expressed in mitochondria. Our study suggests that deamination of cytosine is a frequent event in S.cerevisiae mitochondria and both yeast and human Ung1p repairs deaminated cytosine in mitochondria.     

Were inefficient mitochondrial haplogroups selected during migrations of modern humans? A test using modular kinetic analysis of coupling in mitochondria from cybrid cell lines

We introduce a general test of the bioenergetic importance of mtDNA (mitochondrial DNA) variants: modular kinetic analysis of oxidative phosphorylation in mitochondria from cybrid cells with constant nuclear DNA but different mtDNA. We have applied this test to the hypothesis [Ruiz-Pesini, Mishmar, Brandon, Procaccio and Wallace (2004) Science 303, 223-226] that particular mtDNA haplogroups (specific combinations of polymorphisms) that cause lowered coupling efficiency, leading to generation of less ATP and more heat, were positively selected during radiations of modern humans into colder climates. Contrary to the predictions of this hypothesis, mitochondria from Arctic haplogroups had similar or even greater coupling efficiency than mitochondria from tropical haplogroups.     

DNA base excision repair activities and pathway function in mitochondrial and cellular lysates from cells lacking mitochondrial DNA

Mitochondrial DNA (mtDNA) contains higher steady-state levels of oxidative damage and mutates at rates significantly greater than nuclear DNA. Oxidative lesions in mtDNA are removed by a base excision repair (BER) pathway. All mtDNA repair proteins are nuclear encoded and imported. Most mtDNA repair proteins so far discovered are either identical to nuclear DNA repair proteins or isoforms of nuclear proteins arising from differential splicing. Regulation of mitochondrial BER is therefore not expected to be independent of nuclear BER, though the extent to which mitochondrial BER is regulated with respect to mtDNA amount or damage is largely unknown. Here we have measured DNA BER activities in lysates of mitochondria isolated from human 143B TK^– osteosarcoma cells that had been depleted of mtDNA (ρ⁰) or not (wt). Despite the total absence of mtDNA in the ρ⁰ cells, a complete mitochondrial BER pathway was present, as demonstrated using an in vitro assay with synthetic oligonucleotides. Measurement of individual BER protein activities in mitochondrial lysates indicated that some BER activities are insensitive to the lack of mtDNA. Uracil and 8-oxoguanine DNA glycosylase activities were relatively insensitive to the absence of mtDNA, only about 25% reduced in ρ⁰ relative to wt cells. Apurinic/apyrimidinic (AP) endonuclease and polymerase γ activities were more affected, 65 and 45% lower, respectively, in ρ⁰ mitochondria. Overall BER activity in lysates was also about 65% reduced in ρ⁰ mitochondria. To identify the limiting deficiencies in BER of ρ⁰ mitochondria we supplemented the BER assay of mitochondrial lysates with pure uracil DNA glycosylase, AP endonuclease and/or the catalytic subunit of polymerase γ. BER activity was stimulated by addition of uracil DNA glycosylase and polymerase γ. However, no addition or combination of additions stimulated BER activity to wt levels. This suggests that an unknown activity, factor or interaction important in BER is deficient in ρ⁰ mitochondria. While nuclear BER protein levels and activities were generally not altered in ρ⁰ cells, AP endonuclease activity was substantially reduced in nuclear and in whole cell extracts. This appeared to be due to reduced endogenous reactive oxygen species (ROS) production in ρ⁰ cells, and not a general dysfunction of ρ⁰ cells, as exposure of cells to ROS rapidly stimulated increases in AP endonuclease activities and APE1 protein levels.