Mitochondrial Base Excision Repair Research Articles

Evidence That Msh1p Plays Multiple Roles in Mitochondrial Base Excision Repair

Mitochondrial DNA is thought to be especially prone to oxidative damage by reactive oxygen species generated through electron transport during cellular respiration. This damage is mitigated primarily by the base excision repair (BER) pathway, one of the few DNA repair pathways with confirmed activity on mitochondrial DNA. Through genetic epistasis analysis of the yeast Saccharomyces cerevisiae, we examined the genetic interaction between each of the BER proteins previously shown to localize to the mitochondria. In addition, we describe a series of genetic interactions between BER components and the MutS homolog MSH1, a respiration-essential gene. We show that, in addition to their variable effects on mitochondrial function, mutant msh1 alleles conferring partial function interact genetically at different points in mitochondrial BER. In addition to this separation of function, we also found that the role of Msh1p in BER is unlikely to be involved in the avoidance of large-scale deletions and rearrangements.

Msh1p counteracts oxidative lesion-induced instability of mtDNA and stimulates mitochondrial recombination in Saccharomyces cerevisiae

The proximity of the mitochondrial genome to the respiratory chain, a major source of ROS ( radical oxygen species), makes mtDNA more vulnerable to oxidative damage than nuclear DNA. Mitochondrial BER ( base excision repair) is generally considered to be the main pathway involved in the prevention of oxidative lesion-induced mutations in mtDNA. However, we previously demonstrated that the increased frequency of mitochondrial Oli r mutants in an ogg1Δ strain, lacking the activity of a crucial mtBER glycosylase, is reduced in the presence of plasmids encoding Msh1p, the mitochondrial homologue of the bacterial mismatch protein MutS. This finding suggested that Msh1p might be involved in the prevention of mitochondrial mutagenesis induced by oxidative stress. Here we show that a double mutant carrying the msh1-R813W allele, encoding a variant of the protein defective in the ATP hydrolysis activity, combined with deletion of SOD2, encoding the mitochondrial superoxide dismutase, displays a synergistic effect on the frequency of Oli r mutants, indicating that Msh1p prevents generation of oxidative lesion-induced mitochondrial mutations. We also show that double mutants carrying the msh1-R813W allele, combined with deletion of either OGG1 or APN1, the latter resulting in deficiency of the Apn1 endonuclease, exhibit a synergistic effect on the frequency of respiration-defective mutants having gross rearrangements of the mitochondrial genome. This suggests that Msh1p, Ogg1p and Apn1p play overlapping functions in maintaining the stability of mtDNA. In addition, we demonstrate, using a novel ARG8 m recombination assay, that a surplus of Msh1p results in enhanced mitochondrial recombination. Interestingly, the mutant forms of the protein, msh1p-R813W and msh1p-G776D, fail to stimulate recombination. We postulate that the Msh1p-enhanced homologous recombination may play an important role in the prevention of oxidative lesion-induced rearrangements of the mitochondrial genome.

DNA2 Resolves Expanding Flap in Mitochondrial Base Excision Repair

In a recent issue of Molecular Cell, Zheng et al. (2008) demonstrated that human DNA2, originally identified in yeast as a nuclear DNA replication and repair factor, functions exclusively in mammalian mitochondria in the recently discovered long-patch base excision repair pathway.

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.

Differential age-related changes in mitochondrial DNA repair activities in mouse brain regions

Aging in the brain is characterized by increased susceptibility to neuronal loss and functional decline, and mitochondrial DNA (mtDNA) mutations are thought to play an important role in these processes. Due to the proximity of mtDNA to the main sites of mitochondrial free radical generation, oxidative stress is a major source of DNA mutations in mitochondria. The base excision repair (BER) pathway removes oxidative lesions from mtDNA, thereby constituting an important mechanism to avoid accumulation of mtDNA mutations. The complexity of the brain implies that exposure and defence against oxidative stress varies among brain regions and hence some regions may be particularly prone to accumulation of mtDNA damages. In the current study we investigated the efficiency of the BER pathway throughout the murine lifespan in mitochondria from cortex and hippocampus, regions that are central in mammalian cognition, and which are severely affected during aging and in neurodegenerative diseases. A regional specific regulation of mitochondrial DNA repair activities was observed with aging. In cortical mitochondria, DNA glycosylase activities peaked at middle-age followed by a significant drop at old age. However, only minor changes were observed in hippocampal mitochondria during the whole lifespan of the animals. Furthermore, DNA glycosylase activities were lower in hippocampal than in cortical mitochondria. Mitochondrial AP endonuclease activity increased in old animals in both brain regions. Our data suggest an important regional specific regulation of mitochondrial BER during aging.

Mitochondrial DNA, base excision repair and neurodegeneration

Neurodegeneration is a growing public health concern because of the rapid increase in median and maximum life expectancy in the developed world. Mitochondrial dysfunction seems to play a critical role in neurodegeneration, likely owing to the high energy demand of the central nervous system and its sole reliance on oxidative metabolism for energy production. Loss of mitochondrial function has been clearly demonstrated in several neuropathologies, most notably those associated with age, like Alzheimer's, Parkinson's and Huntington's diseases. Among the common features observed in such conditions is the accumulation of oxidative DNA damage, in particular in the mitochondrial DNA, suggesting that mitochondrial DNA instability may play a causative role in the development of these diseases. In this review we examine the evidence for the accumulation of oxidative DNA damage in mitochondria, and its relationship with loss of mitochondrial function and cell death in neural tissues. Oxidative DNA damage is repaired mainly by the base excision repair pathway. Thus, we review the molecular events and enzymes involved in base excision repair in mitochondria, and explore the possible role of alterations in mitochondrial base excision repair activities in premature aging and age-associated neurodegenerative diseases.

Mitochondrial base excision repair of uracil and AP sites takes place by single-nucleotide insertion and long-patch DNA synthesis

Base excision repair (BER) corrects a variety of small base lesions in DNA. The UNG gene encodes both the nuclear (UNG2) and the mitochondrial (UNG1) forms of the human uracil-DNA glycosylase (UDG). We prepared mitochondrial extracts free of nuclear BER proteins from human cell lines. Using these extracts we show that UNG is the only detectable UDG in mitochondria, and mitochondrial BER (mtBER) of uracil and AP sites occur by both single-nucleotide insertion and long-patch repair DNA synthesis. Importantly, extracts of mitochondria carry out repair of modified AP sites which in nuclei occurs through long-patch BER. Such lesions may be rather prevalent in mitochondrial DNA because of its proximity to the electron transport chain, the primary site of production of reactive oxygen species. Furthermore, mitochondrial extracts remove 5′ protruding flaps from DNA which can be formed during long-patch BER, by a “flap endonuclease like” activity, although flap endonuclease (FEN1) is not present in mitochondria. In conclusion, combined short- and long-patch BER activities enable mitochondria to repair a broader range of lesions in mtDNA than previously known.

Mitochondrial DNA damage and impaired base excision repair during epileptogenesis

Oxidative stress and mitochondrial dysfunction are acute consequences of status epilepticus (SE). However, the role of mitochondrial oxidative stress and genomic instability during epileptogenesis remains unknown. Using the kainate animal model of temporal lobe epilepsy, we investigated oxidative mitochondrial DNA (mtDNA) damage and changes in the mitochondrial base excision repair pathway (mtBER) in the rat hippocampus for a period of 3 months after SE. Acute seizure activity caused a time-dependent increase in mitochondrial, but not nuclear 8-hydroxy-2-deoxyguanosine (8-OHdG/2dG) levels and a greater frequency of mtDNA lesions. This was accompanied by increased mitochondrial H 2O 2 production and a transient decrease in mtDNA repair capacity. The mtBER proteins 8-oxoguanine glycosylase (Ogg1) and DNA polymerase gamma (Pol γ) demonstrated elevated expression at mRNA and protein levels shortly after SE and this was followed by a gradual improvement in mtDNA repair capacity. Recurrent seizures associated with the chronic phase of epilepsy coincided with the accumulation of mtDNA damage, increased mitochondrial H 2O 2 levels, decreased expression of Ogg1 and Pol γ and impaired mtDNA repair capacity. Together, increased oxidative mtDNA damage, mitochondrial H 2O 2 production and alterations in the mtBER pathway provide evidence for mitochondrial oxidative stress in epilepsy and suggest that mitochondrial injury may contribute to epileptogenesis.

Identification and characterization of mitochondrial abasic (AP)-endonuclease in mammalian cells

Abasic (AP)-endonuclease (APE) is responsible for repair of AP sites, and single-strand DNA breaks with 3′ blocking groups that are generated either spontaneously or during repair of damaged or abnormal bases via the DNA base excision repair (BER) pathway in both nucleus and mitochondria. Mammalian cells express only one nuclear APE, 36 kDa APE1, which is essential for survival. Mammalian mitochondrial (mt) BER enzymes other than mtAPE have been characterized. In order to identify and characterize mtAPE, we purified the APE activity from beef liver mitochondria to near homogeneity, and showed that the mtAPE which has 3-fold higher specific activity relative to APE1 is derived from the latter with deletion of 33 N-terminal residues which contain the nuclear localization signal. The mtAPE-sized product could be generated by incubating 35S-labeled APE1 with crude mitochondrial extract, but not with cytosolic or nuclear extract, suggesting that cleavage of APE1 by a specific mitochondria-associated N-terminal peptidase is a prerequisite for mitochondrial import. The low abundance of mtAPE, particularly in cultured cells might be the reason for its earlier lack of detection by western analysis.

Mitochondrial DNA integrity is not dependent on DNA polymerase-β activity

Mutations in mitochondrial DNA (mtDNA) are involved in a variety of pathologies, including cancer and neurodegenerative diseases, as well as in aging. mtDNA mutations result predominantly from damage by reactive oxygen species (ROS) that is not repaired prior to replication. Repair of ROS-damaged bases occurs mainly via base excision repair (BER) in mitochondria and nuclei. In nuclear BER, the two penultimate steps are carried out by DNA polymerase-β (Polβ), which exhibits both 5′-deoxyribose-5-phosphate (5′-dRP) lyase and DNA polymerase activities. In mitochondria, DNA polymerase-γ (Polγ) is believed to be the sole polymerase and is therefore assumed to function in mitochondrial BER. However, a recent report suggested the presence of Polβ or a “Polβ-like” enzyme in bovine mitochondria. Consequently, in the present work, we tested the hypothesis that Polβ is present and functions in mammalian mitochondria. Initially we identified two DNA polymerase activities, one corresponding to Polγ and the other to Polβ, in mitochondrial preparations obtained by differential centrifugation and discontinuous sucrose density gradient centrifugation. However, upon further fractionation in linear Percoll gradients, we were able to separate Polβ from mitochondria and to show that intact mitochondria, identified by electron microscopy, lacked Polβ activity. In a functional test for the presence of Polβ function in mitochondria, we used a new assay for detection of random (i.e., non-clonal) mutations in single mtDNA molecules. We did not detect enhanced mutation frequency in mtDNA from Polβ null cells. In contrast, mtDNA from cells harboring mutations in the Polγ exonuclease domain that abolish proofreading displayed a ≥17-fold increase in mutation frequency. We conclude that Polβ is not an essential component of the machinery that maintains mtDNA integrity.

Localization of mitochondrial DNA base excision repair to an inner membrane-associated particulate fraction

Mitochondrial DNA (mtDNA) contains high levels of oxidative damage relative to nuclear DNA. A full, functional DNA base excision repair (BER) pathway is present in mitochondria, to repair oxidative DNA lesions. However, little is known about the organization of this pathway within mitochondria. Here, we provide evidence that the mitochondrial BER proteins are not freely soluble, but strongly associated with an inner membrane-containing particulate fraction. Uracil DNA glycosylase, oxoguanine DNA glycosylase and DNA polymerase γ activities all co-sedimented with this particulate fraction and were not dissociated from it by detergent (0.1% or 1.0% NP40) treatment. The particulate associations of these activities were not due to their binding mtDNA, which is itself associated with the inner membrane, as they also localized to the particulate fraction of mitochondria from 143B (TK−) ρ0 cells, which lack mtDNA. However, all of the BER activities were at least partially solubilized from the particulate fraction by treatment with 150–300 mM NaCl, suggesting that electrostatic interactions are involved in the association. The biological implications of the apparent immobilization of BER proteins are discussed.

Oxidative DNA Damage Causes Mitochondrial Genomic Instability in Saccharomyces cerevisiae

Mitochondria contain their own genome, the integrity of which is required for normal cellular energy metabolism. Reactive oxygen species (ROS) produced by normal mitochondrial respiration can damage cellular macromolecules, including mitochondrial DNA (mtDNA), and have been implicated in degenerative diseases, cancer, and aging. We developed strategies to elevate mitochondrial oxidative stress by exposure to antimycin and H(2)O(2) or utilizing mutants lacking mitochondrial superoxide dismutase (sod2Delta). Experiments were conducted with strains compromised in mitochondrial base excision repair (ntg1Delta) and oxidative damage resistance (pif1Delta) in order to delineate the relationship between these pathways. We observed enhanced ROS production, resulting in a direct increase in oxidative mtDNA damage and mutagenesis. Repair-deficient mutants exposed to oxidative stress conditions exhibited profound genomic instability. Elimination of Ntg1p and Pif1p resulted in a synergistic corruption of respiratory competency upon exposure to antimycin and H(2)O(2). Mitochondrial genomic integrity was substantially compromised in ntg1Delta pif1Delta sod2Delta strains, since these cells exhibit a total loss of mtDNA. A stable respiration-defective strain, possessing a normal complement of mtDNA damage resistance pathways, exhibited a complete loss of mtDNA upon exposure to antimycin and H(2)O(2). This loss was preventable by Sod2p overexpression. These results provide direct evidence that oxidative mtDNA damage can be a major contributor to mitochondrial genomic instability and demonstrate cooperation of Ntg1p and Pif1p to resist the introduction of lesions into the mitochondrial genome.

P53 functions in the incorporation step in DNA base excision repair in mouse liver mitochondria.

The tumor suppressor p53 protein stimulates nuclear base excision repair (BER) in vitro. In response to certain cellular stresses, p53 translocates to mitochondria, where it can trigger an apoptotic response. However, a potential role for p53 in modulating mitochondrial DNA repair has not yet been examined. In this study, we show that p53 also modulates mitochondrial BER. Uracil-initiated BER incorporation, which measures flux through the entire BER pathway, was lower in mitochondrial extracts from nonstressed p53 knockout mice than in wild type. The addition of recombinant p53 complemented the BER incorporation in p53 knockout extracts and stimulated BER in wt extracts. The activities of three major mitochondrial DNA glycosylases were similar in extracts from wild-type and knockout animals. Likewise, AP endonuclease activity was unaffected by the absence of p53. Gel shift experiments with recombinant p53 demonstrated that p53 did not bind to the uracil-containing substrate used in the repair assay. Polymerase gamma gap-filing activity was less efficient in p53 knockout extracts, but it was complemented with the addition of recombinant p53. Thus, we conclude that p53 may participate in mtBER by stimulating the repair synthesis incorporation step.

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 (rho(0)) or not (wt). Despite the total absence of mtDNA in the rho(0) 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 rho(0) relative to wt cells. Apurinic/apyrimidinic (AP) endonuclease and polymerase gamma activities were more affected, 65 and 45% lower, respectively, in rho(0) mitochondria. Overall BER activity in lysates was also about 65% reduced in rho(0) mitochondria. To identify the limiting deficiencies in BER of rho(0) mitochondria we supplemented the BER assay of mitochondrial lysates with pure uracil DNA glycosylase, AP endonuclease and/or the catalytic subunit of polymerase gamma. BER activity was stimulated by addition of uracil DNA glycosylase and polymerase gamma. 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 rho(0) mitochondria. While nuclear BER protein levels and activities were generally not altered in rho(0) 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 rho(0) cells, and not a general dysfunction of rho(0) cells, as exposure of cells to ROS rapidly stimulated increases in AP endonuclease activities and APE1 protein levels.

Upregulation of mitochondrial base-excision repair capability within rat brain after brief ischemia.

The mechanism by which brief episodes of cerebral ischemia confer protection (tolerance) against subsequent prolonged ischemic challenges remains unclear, but may involve upregulation of cell injury repair capability. The mitochondrion is a key site for the regulation of cell death pathways, and damage to mitochondrial genes has been linked to a number of neurologic diseases and aging. Therefore, the authors examined the response of the DNA base excision repair (BER) pathway in rat brain mitochondria after either brief (tolerance-inducing) or prolonged (injury-producing) focal cerebral ischemia. Brief (30-minute) middle cerebral artery occlusion (MCAO) induced mild oxidative mitochondrial DNA damage and initiated a prolonged (up to 72-hour) activation above control levels of the principal enzymes of the mitochondrial BER pathway, including uracil DNA glycosylase, apurinic/apyrimidinic (AP) endonuclease, DNA polymerase-gamma, and DNA ligase. In contrast, prolonged (100-minute MCAO) ischemia induced more substantial mitochondrial oxidative DNA damage whereas elevation of BER activity was transient (approximately 1 hour), declining to less than control levels over the course of 4 to 72 hours. These data reveal the differences in BER capacity after brief or prolonged ischemia, which may contribute to the neuron's ability to resist subsequent ischemic insults.

Conditional Targeting of the DNA Repair Enzyme hOGG1 into Mitochondria

Oxidative damage to mitochondrial DNA (mtDNA) has been suggested to be a key factor in the etiologies of many diseases and in the normal process of aging. Although the presence of a repair system to remove this damage has been demonstrated, the mechanisms involved in this repair have not been well defined. In an effort to better understand the physiological role of recombinant 8-oxoguanine DNA glycosylase/apurinic lyase (OGG1) in mtDNA repair, we constructed an expression vector containing the gene for OGG1 downstream of the mitochondrial localization sequence from manganese-superoxide dismutase. This gene construct was placed under the control of a tetracycline-regulated promoter. Transfected cells that conditionally expressed OGG1 in the absence of the tetracycline analogue doxycycline and targeted this recombinant protein to mitochondria were generated. Western blots of mitochondrial extracts from vector- and OGG1-transfected clones with and without doxycycline revealed that removal of doxycycline for 4 days caused an approximate 8-fold increase in the amount of OGG1 protein in mitochondria. Enzyme activity assays and DNA repair studies showed that the doxycycline-dependent recombinant OGG1 is functional. Functional studies revealed that cells containing recombinant OGG1 were more proficient at repairing oxidative damage in their mtDNA, and this increased repair led to increased cellular survival following oxidative stress.

Mitochondrial repair of 8-oxoguanine and changes with aging

Reactive oxygen species (ROS) are formed in all living organisms as a by-product of normal metabolism (endogenous sources) and as a consequence of exposure to environmental compounds (exogenous sources). Endogenous ROS are largely formed during oxidative phosphorylation in the mitochondria and, therefore, mitochondrial DNA (mtDNA) is at particularly high risk of ROS-induced damage. Mitochondria are essential for cell viability, and oxidative damage to mtDNA has been implicated as a causative factor in a wide variety of degenerative diseases, and in cancer and aging. One of the most common oxidative DNA lesions is 7,8-dihydro-8-oxoguanine (8-oxoG), which can introduce G/C to T/A transversions after DNA replication. Oxidative DNA base lesions, including 8-oxoG, are repaired primarily by the base excision repair (BER) pathway. While we know much about how this pathway functions in processing the nuclear DNA lesions, little is yet known about BER in mitochondria. We have used a number of different approaches to explore the mechanisms of DNA damage processing in the mtDNA. We have been able to demonstrate that mammalian mitochondria efficiently remove 8-oxoG from their genome, and that the efficiency of 8-oxoG incision increases with age in rats and mice. Yet 8-oxoG accumulates in mtDNA during aging. Changes in mitochondrial function with age have been observed in several organisms and accumulation of DNA lesions in mtDNA with age may be an underlying cause for numerous age-associated diseases including cancer.

Maintenance of mitochondrial DNA integrity: repair and degradation.

Mitochondria have their own genome, which is essential for proper oxidative phosphorylation and hence for a large part of ATP production in a cell. Although mitochondrial DNA-less (rho(0)) cells can survive under certain conditions, the integrity of the mitochondrial genome is critical for the survival of multicellular organisms. Mitochondrial DNA (mtDNA) is damaged more than nuclear DNA because mitochondria produce a large amount of reactive oxygen species and tend to accumulate toxic xenobiotics. Therefore, there is keen interest in mechanisms that maintain the integrity of mtDNA. DNA repair may play an important role. The repair of mtDNA has been investigated less intensely than nuclear DNA repair because, for a long time, it was thought that mitochondria lacked DNA repair systems. In fact, DNA damage can be repaired in mitochondria. Base-excision repair in mitochondria is well established. The enzymes responsible for mtDNA repair have been identified and are encoded by the same genes as their nuclear counterparts. Mitochondrion-targeting sequences are generated through alternative splicing of mRNAs, alternative use of transcription initiation sites, or alternative use of translation initiation sites. In addition to DNA repair, the degradation of damaged mtDNA may be tolerated because there are multiple copies of mtDNA molecules in a cell.

Age-dependent decline of DNA repair activity for oxidative lesions in rat brain mitochondria.

Endogenous oxidative damage to brain mitochondrial DNA and mitochondrial dysfunction are contributing factors in aging and in the pathogenesis of a number of neurodegenerative diseases. In this study, we characterized the regulation of base-excision-repair (BER) activity, the predominant repair mechanism for oxidative DNA lesions, in brain mitochondria as the function of age. Mitochondrial protein extracts were prepared from rat cerebral cortices at the ages of embryonic day 17 (E17) or postnatal 1-, 2-, and 3-weeks, or 5- and 30-months. The total BER activity and the activity of essential BER enzymes were examined in mitochondria using in vitro DNA repair assay employing specific repair substrates. Mitochondrial BER activity showed marked age-dependent declines in the brain. The levels of overall BER activity were highest at E17, gradually decreased thereafter, and reached to the lowest at the age of 30-month ( approximately 80% reduction). The decline of overall BER activity with age was attributed to the decreased expression of repair enzymes such as 8-OHdG glycosylase and DNA polymerase-gamma and, consequently, the reduced activity at the steps of lesion-base incision, DNA repair synthesis and DNA ligation in the BER pathway. These results strongly suggest that the decline in BER activity may be an important mechanism contributing to the age-dependent accumulation of oxidative DNA lesions in brain mitochondria.

Mitochondrial DNA ligase III function is independent of Xrcc1.

Hamster EM9 cells, which lack Xrcc1 protein, have reduced levels of DNA ligase III and are defective in nuclear base excision repair. The Xrcc1 protein stabilizes DNA ligase III and may even play a direct role in catalyzing base excision repair. Since DNA ligase III is also thought to function in mitochondrial base excision repair, it seemed likely that mitochondrial DNA ligase III function would also be dependent upon Xrcc1. However, several lines of evidence indicate that this is not the case. First, western blot analysis failed to detect Xrcc1 protein in mitochondrial extracts. Second, DNA ligase III levels present in mitochondrial protein extracts from EM9 cells were indistinguishable from those seen in similar extracts from wild-type (AA8) cells. Third, the mitochondrial DNA content of both cell lines was identical. Fourth, EM9 cells displayed no defect in their ability to repair spontaneous mitochondrial DNA damage. Fifth, while EM9 cells were far more sensitive to the cytotoxic effects of ionizing radiation due to a defect in nuclear DNA repair, there was no apparent difference in the ability of EM9 and AA8 cells to restore their mitochondrial DNA to pre-irradiation levels. Thus, mitochondrial DNA ligase III function is independent of the Xrcc1 protein.