The absence of a pyrimidine dimer repair mechanism in mammalian mitochondria

Mammalian mitochondrial endonuclease activities specific for ultraviolet-irradiated DNA

Mitochondrial forms of uracil DNA glycosylase and UV endonuclease have been purified and characterized from the mouse plasmacytoma cell line, MPC-11. As in other cell types, the mitochondrial uracil DNA glycosylase has properties very similar to those of the nuclear enzyme, although in this case the mitochondrial activity was also distinguishable by extreme sensitivity to dilution. Three mitochondrial UV endonuclease activities are also similar to nuclear enzymes; however, the relative amounts of these enzyme activities in the mitochondria is significantly different from that in the nucleus. In particular, mitochondria contain a much higher proportion of an activity analogous to UV endonuclease III. Nuclear UV endonuclease III activity is absent from XP group D fibroblasts and XP group D lymphoblasts have reduced, but detectable levels of the mitochondrial form of this enzyme. This residual activity differs in its properties from the normal mitochondrial form of UV endonuclease III, however. The presence of these enzyme activities which function in base excision repair suggests that such DNA repair occurs in mitochondria. Alternatively, these enzymes might act to mark damaged mitochondrial genomes for subsequent degradation.

Interaction of drugs with extranuclear genetic elements and its consequences

Bacterial ancestry of mitochondria and plastids is now generally accepted. Both organelles contain their own DNA and transcription-translation apparatus of a prokaryotic type. Due to this fact these systems carry bacteria-like properties. Thus organellar DNA and ribosomes are essentially different from nuclear DNA and cytoplasmic ribosomes in physical as well as in functional respects. Due to the bacterial character of both types of organelles they are susceptible to various antibacterial chemicals. Inhibitors of bacterial protein synthesis inhibit mitochondrial (plastidial) biogenesis. Therefore the cellular content of mitochondria (plastids)-made proteins decreases during cytoplasmic turnover or cell division in the presence of these drugs. Such drug activity consequently leads to a reduced capacity for oxidative phosphorylation or photosynthesis. Organellar genomes are less stable and more sensitive to mutagenesis as compared to nuclear genome. It means also that genotoxic agents induce various disorders of mitochondrial (plastidial) functions. Impairments in the respiratory chain are associated with structural as well as functional abnormalities of mitochondria. These are clinically expressed mostly in tissues with a high demand for ATP: brain, heart, skeletal muscle, and retina. On the other hand, some antibacterial inhibitors of mitochondrial biogenesis (e.g., tetracyclines) inhibit selectively tumor cell proliferation. Therefore they may be considered for use in anticancer therapy. The article summarizes the response of mitochondria and plastids in various organisms to drugs and environmental xenobiotics. Various model organisms suitable for detection of xenobiotic effect on mitochondria (plastids) are presented as well as the possible consequences of such interaction.

Variation in salmonid mitochondrial DNA: evolutionary constraints and mechanisms of substitution

Sequence comparisons were made from 2214 bp of mitochondrial DNA cloned from six Pacific salmonid species. These sequences include the genes for ATPase subunit 6, cytochrome oxidase subunit 3, NADH dehydrogenase subunit 3, NADH dehydrogenase subunit 4L, tRNA(GLY), and tRNA(ARG). Variation is found at 338 silent and 12 nonsilent positions of protein coding genes and 10 positions in the two tRNA sequences. A single 3-bp length difference was also detected. In all pairwise comparisons the sequence divergence observed in the fragment was higher than that previously predicted by restriction enzyme analysis of the entire molecule. The inferred evolutionary relationship of these species is consistent between methods. The distribution of silent variation shows a complex pattern with greatly reduced variation at the junctions of genes. The variation in the tRNA sequences is concentrated in the DHU loop. The close relationship of these species and extensive sequence analyzed allows for an analysis of the spectrum of substitutions that includes the frequencies of all 12 possible substitutions. The observed spectrum of substitutions is related to potential pathways of spontaneous substitution. The salmonid sequences show an extremely high ratio of silent to replacement substitutions. In addition the amino acid sequences of the four proteins coded in this fragment show a consistently high level of identity with the Xenopus sequences. Taken together these data are consistent with a slower rate of amino acid substitution among the cold-blooded vertebrates when compared to mammals.

Mismatch-specific 3'----5' exonuclease associated with the mitochondrial DNA polymerase from Drosophila embryos

The mitochondrial DNA polymerase from Drosophila embryos lacks dNTP turnover activity. However, a potent 3'----5' exonuclease activity can be detected by a specific assay in which the exonuclease excises mispaired nucleotides at the 3' termini of primed synthetic and natural DNA templates. The excision of a mispaired nucleotide occurs at a significantly greater rate than excision of a correctly paired nucleotide and, under conditions of DNA synthesis, hydrolysis of a mispaired terminal nucleotide occurs prior to primer extension. The 3'----5' exonuclease copurifies quantitatively with DNA polymerase gamma and cosediments with the nearly homogeneous enzyme under native conditions. These results suggest that the 3'----5' exonuclease provides a proofreading function to enhance the fidelity of DNA synthesis during Drosophila mitochondrial DNA replication.

RNAs containing mitochondrial ND6 and COI sequences present an abnormal structure in chemically induced rat hepatomas

We have constructed a cDNA library prepared from an hepatoma cell line (HTC cells) and isolated a clone, pHT 13, which corresponds to mRNAs present at a much higher level in rat hepatomas than in normal hepatocytes. The sequence of the pHT 13 insert has been previously published (Nucleic Acids Res. 1988, 16,10935). This clone contains mitochondrial DNA sequences with an abnormal organization, since it includes part of the NADH dehydrogenase subunit 6 (ND6) and of the cytochrome oxidase subunit I (COI) genes separated by 230 bases instead of 9 kb in mitochondrial genome from normal hepatocytes. In this work we show (1) that RNAs homologous to this clone are present in hepatoma cells but not in normal hepatocytes, (2) that a 3 kb fragment of tumor mitochondrial DNA contains both the ND6 and the COI sequences. The abnormal structure of the DNA is confirmed by Southern blot analysis which shows that distinct types of mitochondrial DNAs are present in hepatoma cells.

A direct repeat is a hotspot for large-scale deletion of human mitochondrial DNA

Kearns-Sayre syndrome (KSS) and progressive external ophthalmoplegia (PEO) are related neuromuscular disorders characterized by ocular myopathy and ophthalmoplegia. Almost all patients with KSS and about half with PEO harbor large deletions in their mitochondrial genomes. The deletions differ in both size and location, except for one, 5 kilobases long, that is found in more than one-third of all patients examined. This common deletion was found to be flanked by a perfect 13-base pair direct repeat in the normal mitochondrial genome. This result suggests that homologous recombination deleting large regions of intervening mitochondrial DNA, which previously had been observed only in lower eukaryotes and plants, operates in mammalian mitochondrial genomes as well, and is at least one cause of the deletions found in these two related mitochondrial myopathies.

Origin and differentiation of human mitochondrial DNA

A recent study of mitochondrial DNA (mtDNA) polymorphism has generated much debate about modern human origins by proposing the existence of an "African Eve" living 200,000 years ago somewhere in Africa. In an attempt to synthesize information concerning human mtDNA genetic polymorphism, all available data on mtDNA RFLP have been gathered. A phylogeny of the mtDNA types found in 10 populations reveals that all types could have issued from a single common ancestral type. The distribution of shared types between continental groups indicates that caucasoid populations could be the closest to an ancestral population from which all other continental groups would have diverged. A partial phylogeny of the types found in five other populations also demonstrates that the myth of an African Eden was based on an incorrect "genealogical tree" of mtDNA types. Two measures of molecular diversity have been computed on all samples on the basis of mtDNA type frequencies, on one hand, and on the basis of the number of polymorphic sites in the samples, on the other. A large discrepancy is found between the two measures except in African populations; this suggests the existence of some differential selective mechanisms. The lapse of time necessary for creating the observed molecular diversity from an ancestral monomorphic population has been calculated and is found generally greater in Oriental and caucasoid populations. Implications concerning human mtDNA evolution are discussed.

Do mitochondrial DNA fragments promote cancer and aging?

Reactive oxygen species are important in carcinogenesis, diseases, and aging, probably through oxidative damage of DNA. Our understanding of this relationship at the molecular level is very sketchy. It has recently been found that in mitochondria oxidative DNA damage is particularly high and may not be repaired efficiently. I propose that oxidatively generated DNA fragments escape from mitochondria and become integrated into the nuclear genome. This may transform cells to a cancerous state. Time-dependent nuclear accumulation of mitochondrial DNA fragments may progressively change the nuclear information content and thereby cause aging. This proposal can be tested experimentally.

7-Methylguanine adducts in DNA are normally present at high levels and increase on aging: analysis by HPLC with electrochemical detection

The 7-methylguanine adduct in the DNA of rat liver is determined as an indicator of exposure to exogenous and endogenous methylating agents. A method for the analysis of 7-methylguanine adducts has been developed by combining the selectivity of separation of reversed-phase HPLC with the specificity and high sensitivity of electrochemical detection. The sensitivity of the method is about 10,000-fold that of optical methods and is sufficient to determine the endogenous background of DNA methylation. DNA from the liver of normal young rats (6 months old) contains 7-methylguanine at a level of 1 residue per 31,000 bases in mitochondrial DNA and 1 residue per 105,000 bases in nuclear DNA. These levels increase about 2.5-fold in old rats (24 months old). We attribute this strikingly high level of adducts to endogenous methylation, which could contribute to aging and cancer.

Normal oxidative damage to mitochondrial and nuclear DNA is extensive

Oxidative damage to DNA can be caused by excited oxygen species, which are produced by radiation or are by-products of aerobic metabolism. The oxidized base, 8-hydroxydeoxyguanosine (oh8dG), 1 of approximately 20 known radiation damage products, has been assayed in the DNA of rat liver. oh8dG is present at a level of 1 per 130,000 bases in nuclear DNA and 1 per 8000 bases in mtDNA. Mitochondria treated with various prooxidants have an increased level of oh8dG. The high level of oh8dG in mtDNA may be caused by the immense oxygen metabolism, relatively inefficient DNA repair, and the absence of histones in mitochondria. It may be responsible for the observed high mutation rate of mtDNA.

The preference of the mitochondrial endonuclease for a conserved sequence block in mitochondrial DNA is highly conserved during mammalian evolution

Endonuclease activity identified in crude preparations of rat and human heart mitochondria has each been partially purified and characterized. Both the rat and human activities purify as a single enzyme that closely resembles the endonuclease of bovine-heart mitochondria (Cummings, O.W. et. al. (1987) J. Biol. Chem. 262:2005-2015). All three enzymes, for example elute similarly during gel filtration and DNA-cellulose chromatography, and exhibit similar enzymatic properties. Although the nucleotide sequences of the mtDNAs indicate that there has occurred an unusual degree of divergence in the displacement-loop region during mammalian evolution, the nucleotide specificities of the mt endonucleases appear highly conserved and show a striking preference for an evolutionarily-conserved sequence tract that is located upstream from the heavy (H)-strand origin of DNA replication (OriH).

Purification and characterization of porcine liver DNA polymerase gamma: utilization of dUTP and dTTP during in vitro DNA synthesis

Porcine liver DNA polymerase gamma has been demonstrated to preferentially incorporate dTMP over dUMP during in vitro DNA synthesis. When polymerase activity was measured in standard reactions containing saturating levels of either dTTP or dUTP, the polymerization rate was slightly faster in the reaction containing dTTP. However, under conditions where both dTTP and dUTP competed, at an equal molar concentration, approximately 3-times more thymine residues were incorporated than uracil residues into DNA. Similarly, preferential incorporation of dTMP was observed on several substrates including poly (dA).oligo p(dT), poly (rA).oligo p(dT) and poly (dA-dT). The discrimination against dUMP incorporation was even more apparent with reduced levels of dUTP. These observations were consistent with the finding that the Km for DNA polymerase gamma was about 3-fold lower for dTTP (0.4 microM) than for dUTP (1.1 microM). On the other hand, the Vmax for these two reactions was very similar. Discrimination against dUMP incorporation was also observed during inhibition of polymerase gamma by dideoxyribonucleoside triphosphates. Dideoxythymidine triphosphate preferentially inhibited dUMP incorporation compared to that of dTMP, whereas ddATP, ddCTP and ddGTP inhibited both reactions equally.

Purification and properties of a single strand-specific endonuclease from mouse cell mitochondria

A nuclease was purified from mitochondria of the mouse plasmacytoma cell line, MCP-11 which acts on single-stranded DNA endonucleolytically and appears to have no activity upon native DNA. It degrades unordered RNA somewhat more effectively than it does DNA. The enzyme activity and the major detectable polypeptide migrate to a position corresponding to an Mr of 37,400 on denaturing polyacrylamide gels; in its native form the activity has an S value of 4.7, which corresponds to a molecular weight of roughly 73,000. The single-strand DNase activity has a pH optimum near 7.5, requires a divalent cation and is inhibited by EDTA, phosphate, KCl and NaCl. The enzyme is remarkably similar to fungal mitochondrial enzymes whose absence in various mutants correlates with defective DNA repair and recombination. It reacts weakly with antibody to a form of such an enzyme from Neurospora crassa.

The unusual varl gene of yeast mitochondrial DNA

The var1 gene specifies the only mitochondrial ribosomal protein known to be encoded by yeast mitochondrial DNA. The gene is unusual in that its base composition is nearly 90 percent adenine plus thymine. It and its expression product show a strain-dependent variation in size of up to 7 percent; this variation does not detectably interfere with function. Furthermore, var1 is an expandable gene that participates in a novel recombinational event resembling gene conversion whereby shorter alleles are preferentially converted to longer ones. The remarkable features of var1 indicate that it may have evolved by a mechanism analogous to exon shuffling, although no introns are actually present.

Nucleotide sequence preservation of human mitochondrial DNA

Recombinant DNA techniques have been used to quantitate the amount of nucleotide sequence divergence in the mitochondrial DNA population of individual normal humans. Mitochondrial DNA was isolated from the peripheral blood lymphocytes of five normal humans and cloned in M13 mp11; 49 kilobases of nucleotide sequence information was obtained from 248 independently isolated clones from the five normal donors. Both between- and within-individual differences were identified. Between-individual differences were identified in approximately 1/200 nucleotides. In contrast, only one within-individual difference was identified in 49 kilobases of nucleotide sequence information. This high degree of mitochondrial nucleotide sequence homogeneity in human somatic cells is in marked contrast to the rapid evolutionary divergence of human mitochondrial DNA and suggests the existence of mechanisms for the concerted preservation of mammalian mitochondrial DNA sequences in single organisms.

Effect of hypothyroidism on the biogenesis of free mitochondria in the cerebral hemispheres and in cerebellum of rat during postnatal development

The effect of propylthiouracil-induced neonatal hypothyroidism on some aspects of the biogenesis of free (non-synaptosomal) mitochondria in the cerebral hemispheres and in the cerebellum of developing rat has been studied. The results obtained show that in hypothyroid rats mitochondrial DNA synthesis is delayed, mitochondrial RNA synthesis is not affected and cytochrome aa3 content of mitochondria is lower than in controls. Furthermore ultrathin sections of 14- and 21-day old hypothyroid rat cerebella show mitochondria with an altered ultrastructural organization and large intracristal spaces.

Segregation of mitochondrial DNA in human somatic cell hybrids

The maintenance of mtDNA has been examined in human intraspecific hybrid cells constructed from the fusion of HEB7A, a HeLa tumor cell line carrying the mitochondrially coded chloramphenical (CAP) resistance mutation, and GM 2291, a limited lifespan human diploid fibroblast which is CAP sensitive. These two cells can be distinguished by a polymorphism in a site for the restriction endonuclease, HaeIII. Independently isolated clones of hybrid cells were characterized for their growth properties (either normal limited lifespan or transformed and "immortal"). Whole cell DNA preparations were made from each hybrid, digested with HaeIII, and the resultant fragments were detected by hybridization to 32P labelled mouse mtDNA as probe. Experiments with mixtures of HEB7A and GM 2291 DNA reveal that HEB7A mtDNA can be detected when it constitutes as little as 5% of the total cell mtDNA. The results indicate that the HEB7A mtDNA is lost from most hybrids, and when it does persist it is usually a minor component of total mtDNA. The addition of CAP at the time of fusion slightly increases the quantity of HEB7A mtDNA, but not enough to confer CAP resistance. Furthermore, five limited lifespan hybrids contained no detectable HEB7A mtDNA, while three transformed hybrids contained varying quantities of HEB7A mtDNA, suggesting that retention of this tumor form of mtDNA is associated with tumor growth behavior. These results suggest that cytoplasmic genetic incompatibility occurs in intraspecific hybrids.

Nature of DNA repair synthesis resistant to inhibitors of polymerase alpha in human cells

Arabinocytidine and aphidicolin are inhibitors of alpha-DNA polymerase that have been shown to affect both normal DNA replication and repair synthesis in mammalian cells. In contradiction to the prevalent hypothesis that these inhibitors merely slow the polymerization rate at incision sites near lesions, our results suggest that the repair synthesis resistant to inhibitors is mediated by a separate pathway. Repair synthesis in contact-inhibited human cells following UV irradiation was inhibited 75-80% by arabinocytidine or aphidicolin, and most of the repair patches were not ligated into parental DNA, as judged by an enzymatic assay. However, the patches were not demonstrably shorter than those in untreated cells. Even following low-UV doses at which no inhibition of repair synthesis by the inhibitors was observed, a majority of the patches were not ligated. DNA polymerase beta is implicated in this alternate pathway, both by the known specificity of the inhibitors and by evidence from their sensitivity to S1 nuclease that the patches arise from displacement synthesis. The unligated patches are not degraded in vivo and eventually become ligated into parental DNA, very slowly in the presence of inhibitors but much more rapidly following their removal. Thus, under conditions of alpha-polymerase inhibition, a limited number of normal length repair patches are made, apparently by displacement synthesis, leaving displaced strands that remain substantially undegraded.

Nucleotide sequence evidence for rapid genotypic shifts in the bovine mitochondrial DNA D-loop

Mitochondrial DNA (mtDNA) is unusual in its rapid rate of evolution and high level of intraspecies sequence variation. The latter is thought to be related to the strict maternal inheritance of mtDNA, which effectively isolates within a species mitochondrial gene pools that accumulate mutations and vary independently. A fundamental and as yet unexplained aspect of this process is how, in the face of somatic and germ-line mtDNA ploidy of 10(3) to 10(5) (refs 4, 5), individual variant mtDNA molecules resulting from mutational events can come to dominate the large intracellular mtDNA population so rapidly. To help answer this question, we have determined here the nucleotide sequence of all or part of the D-loop region in 14 maternally related Holstein cows. Four different D-loop sequences can be distinguished in the mtDNA of these animals. One explanation is that multiple mitochondrial genotypes existed in the maternal germ line and that expansion or segregation of one of these genotypes during oogenesis or early development led to the rapid genotypic shifts observed.

DNA synthesis in isolated mitochondria and mitochondrial extracts from wheat embryos

DNA synthesis was studied using purified wheat embryo mitochondria as well as mitochondrial lysates deprived of endogenous DNA. The optimal conditions for DNA synthesis are very similar in both systems: ATP stimulates dramatically mitochondrial DNA synthesis and magnesium is a better co-factor than manganese, contrary to what has been reported in animal mitochondrial systems. Wheat mitochondrial DNA synthesis is resistant to aphidicolin and strongly inhibited by dideoxythymidine triphosphate and ethidium bromide. Thus, the DNA polymerase involved in this system seems to be the same as that previously purified and characterized from wheat embryo mitochondria (Christopheet al., Plant Science Letters 21: 181, 1981). Two different approaches: restriction endonuclease digestion followed by electrophoresis, and autoradiography and cesium chloride equilibrium centrifugation of mitochondrial DNA, where BrdUTP has been incorporated instead of TTP, show that long stretches of the mitochondrial genome have been synthesized.

Size and frequency of gaps in newly synthesized DNA of xeroderma pigmentosum human cells irradiated with ultraviolet light

Native newly synthesized DNA from human cells (xeroderma pigmentosum type) irradiated with ultraviolet light releases short pieces of DNA (L-DNA) when incubated with the single-strand specific S1 nuclease. This is not observed in the case of unirradiated cells. Previous experiments had shown that the L-DNA resulted from the action of S1 nuclease upon gaps, i.e., single-stranded DNA discontinuities in larger pieces of double-stranded DNA. We verified that the duplex L-DNA, that arises from the inter-gap regions upon S1 nuclease treatment, has a size which approximates the distance between two pyrimidine dimers on the same strand; this has been observed at different fluences of ultraviolet-light and indicates that the gap is related to or opposite the dimer. A method was devised to measure the size of the gaps. A Poisson distribution analysis of the percentage of the L-DNA produced as a function of S1 nuclease concentration made this possible. 65% of the gaps corresponded to stretches of 1,250 nucleotides and 35% to stretches of 150 nucleotides. These parameters have been considered in the proposition of a model for DNA synthesis on a template containing pyrimidine dimers.

Comparative studies of chloroplastic and nuclear DNA repair abilities after ultraviolet irradiation of Euglena gracilis

Studies of nuclear and chloroplastic-DNA repair after ultraviolet irradiation of Euglena gracilis show that photoreactivation is very efficient at both the nuclear and chloroplastic level. Liquid-holding or split-dose experiments and treatment with caffeine reveal, furthermore, that dark-repair is very efficient in nuclear DNA but not in chloroplastic DNA (ctDNA). The possibility of a chloroplastic dark-repair of restricted efficiency is discussed. Determination of chloroplastic DNA content by reassociation kinetics indicates that an important degradation follows UV irradiation during liquid holding in the dark.

Structure of the replication fork in ultraviolet light-irradiated human cells

The DNA extracted from xeroderma pigmentosum human fibroblasts previously irradiated with 12.5 J/m2 of UV light and pulse-labeled for 45 min with radioactive and (or) heavy precursors, was used to determine the structural characteristics of the replication fork. Density equilibrium centrifugation experiments showed that a fork moved 6 micrometer in 45 min and bypassed 3 pyrimidine dimers in both strands. The same length was covered in 15-20 min in control cells. The delay in irradiated cells was apparently due to pyrimidine dimers acting as temporary blocks to the fork movement. Evidence for this interpretation comes from kinetics of incorporation of [3H]thymidine into DNA, which show that the time necessary to attain a new stable level of DNA synthesis in irradiated cells is equivalent to that required for the replication fork to cover the interdimer distance in one strand. On the other hand, the action of S1 nuclease on DNA synthesized soon after irradiation gives rise to a bimodal distribution in neutral sucrose gradients, one peak corresponding to 43 X 10(6) daltons and the other to 3 X 10(6) daltons. These two DNA species are generated by the attack of the S1 nuclease on single-stranded regions associated with the replication fork. A possible explanation for these results is given by a model according to which there is a delayed bypass of the dimer in the leading strand and the appearance of gaps opposite pyrimidine dimers in the lagging strand, as a direct consequence of the discontinuous mode of DNA replication. In terms of the model, the DNA of 43 X 10(6) daltons corresponds to the leading strand, linked to the unreplicated branch of the forks, whereas the piece of 3 X 10(6) daltons is the intergap DNA coming from the lagging strand. Pulse and chase experiments reveal that the low molecular weight DNA grows in a pattern that suggests that more than one gap may be formed per replication fork.

Functional roles of DNA polymerases beta and gamma

The physiological functions of DNA polymerases (deoxynucleosidetriphosphate:DNA deoxynucleotidyltransferase, EC 2.7.7.7) beta and gamma were investigated by using neuronal nuclei and synaptosomes isolated from rat brain. UV irradiation of neuronal nuclei from 60-day-old rats resulted in a 7- to 10-fold stimulation of DNA repair synthesis attributable to DNA polymerase beta which, at this developmental stage, is virtually the only DNA polymerase present in the nuclei. No repair synthesis could be elicited by treating the nuclei with N-methyl-N-nitrosourea, but this way probably due to the inability of brain tissues to excise alkylated bases from DNA. The role of DNA polymerase gamma was studied in synaptosomes by using a system mimicking in vivo mitochondrial DNA synthesis. By showing that, under these conditions, DNA replication occurs in mitochondria, and exploiting the fact that DNA polymerase gama is the only DNA polymerase present in mitochondria, evidence was obtained for a role of DNA polymerase gamma in mitochondrial DNA replication. Based on these results and on the wealth of literature on DNA polymerase alpha, we conclude that DNA polymerase alpha is mainly responsible for DNA replication in nuclei, DNA polymerase beta is involved in nuclear DNA repair, and DNA polymerase gamma is the mitochondrial replicating enzyme. However, minor roles for DNA polymerase alpha in DNA repair or for DNA polymerase beta in DNA replication cannot be excluded.

Rapid evolution of animal mitochondrial DNA

Mitochondrial DNA was purified from four species of higher primates (Guinea baboon, rhesus macaque, guenon, and human) and digested with 11 restriction endonucleases. A cleavage map was constructed for the mitochondrial DNA of each species. Comparison of the maps, aligned with respect to the origin and direction of DNA replication, revealed that the species differ from one another at most of the cleavage sites. The degree of divergence in nucleotide sequence at these sites was calculated from the fraction of cleavage sites shared by each pair of species. By plotting the degree of divergence in mitochondrial DNA against time of divergence, the rate of base substitution could be calculated from the initial slope of the curve. The value obtained, 0.02 substitutions per base pair per million years, was compared with the value for single-copy nuclear DNA. The rate of evolution of the mitochondrial genome appears to exceed that of the single-copy fraction of the nuclear genome by a factor of about 10. This high rate may be due, in part, to an elevated rate of mutation in mitochondrial DNA. Because of the high rate of evolution, mitochondrial DNA is likely to be an extremely useful molecule to employ for high-resolution analysis of the evolutionary process.

Excision repair of ultraviolet damage in mammalian cells. Evidence for two steps in the excision of pyrimidine dimers

The incidence of pyrimidine dimer formation and the kinetics of DNA repair in African green monkey kidney CV-1 cells after ultraviolet (UV) irradiation were studied by measuring survival, T4 endonuclease V-sensitive sites, the fraction of pyrimidine dimers in acid-insoluble DNA as determined by thin layer chromatography (TLC), and repair replication. CV-1 cells exhibit a survival curve with extrapolation number n = 7.8 and Do = 2.5 J/m2. Pyrimidine dimers were lost from acid-insoluble DNA more slowly than endonuclease-sensitive sites were lost from or new bases were incorporated into high molecular weight DNA during the course of repair. Growth of CV-1 cultures in [3H]thymidine or X-irradiation (2 or 10 krads) 24 h before UV irradiation had no effect on repair replication induced by 25 J/m2 of UV. These results suggest that pyrimidine dimer excision measurements by TLC are probably unaffected by radiation from high levels of incorporated radionuclides. The endonuclease-sensitive site and TLC measurements can be reconciled by the assumption that pyrimidine dimers are excised from high molecular weight DNA in acid-insoluble oligonucleotides that are slowly degraded to acid-soluble fragments.

Turnover-synthesis of chloroplast DNA in developing chloroplasts

The mechanism for the turnover-synthesis of chloroplast DNA in the absence of net synthesis during the chloroplast maturation in Euglena gracilis was determined. DNA synthesis was measured by incorporation of32Pi into chloroplast DNA. The density label, 15N, was incorporated to examine the mechanism of turnover-synthesis. The newly synthesized segments represent a replacement of segments in the DNA containing 1.5 X 10(3) to 6.1 X 10(3) nucleotides. Twenty-three fragments of chloroplast DNA, generated by digestion with the restriction endonuclease EcoRI, became labeled with 32Pi. Turnover-synthesis, therefore, replaces segments throughout the molecule of chloroplast DNA.

Photoreactivation and dark repair of ultraviolet light-induced pyrimidine dimers in chloroplast DNA

A UV-specific endonuclease was used to detect ultraviolet light-induced pyrimidine dimers in chloroplast DNA of Chlamydomonas reinhardi that was specifically labeled with tritiated thymidine. All of the dimers induced by 100 J/m2 of 254 nm light are removed by photoreaction. Wild-type cells exposed to 50 J/m2 of UF light removed over 80% of the dimers from chloroplast DNA after 24 h of incubation in growth medium in the dark. A UV- sensitive mutant, UVS1, defective in the excision of pyrimidine dimers from nuclear DNA is capable of removing pyrimidine dimers from chloroplast DNA nearly as well as wild-type, suggesting that nuclear and chloroplast DNA dark-repair systems are under separate genetic control.

Mitotic segregation of cytoplasmic determinants for chloramphenicol resistance in mammalian cells II: Fusions with human cell lines

Cytoplasmically inherited chloramphenicol (CAP) resistance in human cells has been used to study the interaction between sensitive and resistant mitochondria. Cybrids between two HeLa cells were stable for resistance, grew rapidly and cloned well in CAP, and were O2 tolerant. HeLa-HeLa hybrids were also stable up to 70 doublings in the absence of CAP. Cybrids between HeLa and WI-L2 cells were unstable for resistance for up to 40 doublings, grew slowly and cloned poorly in CAP, and were O2 sensitive (S phase). The growth rate then increased and the cells became stable for resistance, cloned well, and were not O2 sensitive (F phase). Doubling time for S but not F phase cells was proportional to CAP concentration, indicating that both kinds of mitochondria were present and functioning. The instability of CAP resistance in many interstrain but not in intrastrain mouse and human cybrids and hybrids is interpreted in relation to lower eukaryotes.

The effect of bleomycin on mitochondrial DNA

Covalently closed circular mitochondrial DNA (mt-DNA) from mouse fibroblasts (L-cells) forms a separate band from nicked circular or linear DNA molecules in ethidium bromide-cesium chloride byoyant density gradient analysis. The conversion of covalently closed circular mt-DNA to nicked circular or linear DNA may serve as a sensitive method of detecting DNA strand breaks induced by bleomycin (BLM). At a very high concentration BLM induces the conversion of closed circular mt-DNA to nicked circular or linear DNA, however even after 24 h of exposure to BLM at a high concentration a considerable amount of closed circular mt-DNA molecules remains intact.

A novel class of Saccharomyces cerevisiae mutants specifically UV-sensitive to "petite" induction

A mutant of Saccharomyces cerevisiae has been isolated which, though exhibiting a normal response to nuclear genetic damage by ultraviolet light (UV), is more sensitive than its wild type specifically in the production of the cytoplasmic (rho-) mutation by this agent. Some of the features of this mutation which has been designated uvsrho 5 are: i) The mutation is recessive, it exhibits a Mendelian, and hence presumably nuclear, pattern of segregation, but manifests its effects specifically and pleiotropically on mitochondrial functions. ii) Mutant cells resemble their wild type parents in a) growth characteristics on glucose; b) in their UV induced dose response to lethality or nuclear mutation and c) the ability of their mitochondrial genome, upon mating with appropriate testers, of transmitting and recombining various markers, albeit with enhanced efficiency. Similarly, d) they are able to modulate the expression of mitochondrial mutagenesis by ethidium bromide. Thus their mitochondrial DNA appears genetically as competent as that of the wild type. iii) Mutant cells differ from their wild type parents in a) growth characteristics on glycerol; b) susceptibility to induction of the mitochondrial (rho-) mutation by various mutagens, in that the rate of spontaneous mutation is slightly and that by UV is significantly enhanced, whild that by ethidium bromide is greatly diminished. Conversely, c) modulating influences resulting in the repair of initial damage are diminished fro UV and stimulated in the case of Berenil. iv) The amount of mitochondrial DNA per cell appears elevated in the mutant, relative to wild type, and its rate of degradation subsequent to a mutagenic exposure to either UV or ethidium bromide is diminished. v) A self-consistent scheme to account for this and all other information so far available for the induction and modulation of the (rho-) mutation is presented. In a previous study it was shown that some nuclear mutants of Saccharomyces cerevisiae, more sensitive to lethal damage induced by ultraviolet light (rad) than their parent wild type (RAD), also exhibit a concomitant modification in sensitivity to both nuclear and cytoplasmic genetic damage (Moustacchi, 1971). However, another class of rad mutants respond to the induction of the cytoplasmic "petite" also designated as rho- (or rho-) mutation by UV in a manner indistinguishable from that of the RAD strain. One possible interpretation of this last observation is that some of the steps in the expression of the UV damage on mitochondrial (mt)DNA may be governed by other nuclear and cytoplasmic genetic determinants, the products of which may then act specifically on mitochondrial lesions. If this assumption is correct, it should be possible to find mutants with a normal response to nuclear damage but specifically UV-sensitive towards induction of (rho-)...

Evidence for the lack of deoxyribonucleic acid dark-repair in Halobacterium cutirubrum

1. Halobacterium cutirubrum does not perform dark-repair of DNA either after u.v. irradiation or during normal growth. 2. Cultures irradiated with u.v. are readily photoreactivated, but do not recover viability in the dark. 3. No increase in the rate of DNA synthesis is observed in the surviving cells after u.v. irradiation. 4. At early times during normal semiconservative replication, newly incorporated thymidine is found only in the hybrid DNA. 5. It is suggested that these bacteria may be useful in the study of DNA replication and photoreactivation.