Mutagenicity and DNA repair of glycidamide-induced adducts in mammalian cells

Glycidamide (GA)-induced mutagenesis in mammalian cells is not very well understood. Here, we investigated mutagenicity and DNA repair of GA-induced adducts utilizing Chinese hamster cell lines deficient in base excision repair (BER), nucleotide excision repair (NER) or homologous recombination (HR) in comparison to parent wild-type cells. We used the DRAG assay in order to map pathways involved in the repair of GA-induced DNA lesions. This assay utilizes the principle that a DNA repair deficient cell line is expected to be affected in growth and/or survival more than a repair proficient cell. A significant induction of mutations by GA was detected in the hprt locus of wild-type cells but not in BER deficient cells. Cells deficient in HR or BER were three or five times, respectively, more sensitive to GA in terms of growth inhibition than were wild-type cells. The results obtained on the rate of incisions in BER and NER suggest that lesions induced by GA are repaired by short patch BER rather than long patch BER or NER. Furthermore, a large proportion of the GA-induced lesions gave rise to strand breaks that are repaired by a mechanism not involving PARP. It is suggested that these strand breaks, which might be the results from alkylation of the backbone phosphate, are misrepaired by HR during replication thereby leading to a clastogenic rather than a mutagenic pathway. The type of lesion responsible for the mutagenic effect of GA cannot be concluded from the results presented in this study.     

Mutagenicity and DNA repair of glycidamide-induced adducts in mammalian cells

Glycidamide (GA)-induced mutagenesis in mammalian cells is not very well understood. Here, we investigated mutagenicity and DNA repair of GA-induced adducts utilizing Chinese hamster cell lines deficient in base excision repair (BER), nucleotide excision repair (NER) or homologous recombination (HR) in comparison to parent wild-type cells. We used the DRAG assay in order to map pathways involved in the repair of GA-induced DNA lesions. This assay utilizes the principle that a DNA repair deficient cell line is expected to be affected in growth and/or survival more than a repair proficient cell.A significant induction of mutations by GA was detected in the hprt locus of wild-type cells but not in BER deficient cells. Cells deficient in HR or BER were three or five times, respectively, more sensitive to GA in terms of growth inhibition than were wild-type cells. The results obtained on the rate of incisions in BER and NER suggest that lesions induced by GA are repaired by short patch BER rather than long patch BER or NER. Furthermore, a large proportion of the GA-induced lesions gave rise to strand breaks that are repaired by a mechanism not involving PARP. It is suggested that these strand breaks, which might be the results from alkylation of the backbone phosphate, are misrepaired by HR during replication thereby leading to a clastogenic rather than a mutagenic pathway. The type of lesion responsible for the mutagenic effect of GA cannot be concluded from the results presented in this study.     

Repair of DNA alkylation adducts in mammalian cells

Carcinogenic alkylating agents, including nitrosamines, are able to alkylate DNA at various sites. This review presents evidence of the high degree of specificity in the type of DNA damage induced by various N-nitroso compounds and in the DNA repair processes among tissues or cells of different species. The O6-alkylguanine DNA alkyltransferase activity in various human and rodent tissues is discussed as well as the detection of O6-methylguanine in human DNA, using monoclonal antibodies and radioimmunoassay. The relevance of these findings to the mechanisms of cancer induction by nitrosamines is discussed.     

Arsenite induces oxidative DNA adducts and DNA-protein cross-links in mammalian cells.

Arsenic is generally recognized as a nonmutagenic carcinogen because sodium arsenite induces DNA damage only at very high concentrations. In this study we demonstrate that arsenite concentrations above 0.25 microM induce DNA strand breaks in both human leukemia cells and Chinese hamster ovary cells. Therefore, DNA damage may be involved in arsenic-induced carcinogenesis. Formamidopyrimidine-DNA glycosylase and proteinase K greatly increased DNA strand breaks in arsenite-treated cells, providing evidence that a large portion of arsenite-induced DNA strand breaks come from excision of oxidative DNA adducts and DNA-protein cross-links. Because DNA strand breaks appear only temporarily during excision repair, the level of detectable DNA strand breaks will be low at any given time point. For this reason many previous studies have only detected low levels of DNA strand breaks. We also show that catalase, and inhibitors of calcium, nitric oxide synthase, superoxide dismutase, and myeloperoxidase, could modulate arsenite-induced DNA damage. We conclude that arsenite induces DNA adducts through calcium-mediated production of peroxynitrite, hypochlorous acid, and hydroxyl radicals.     

DNA repair mechanisms in mammalian germ cells

Mammalian germ cells encounter several types of DNA damage. This damage is almost completely repaired in a short?period of time to provide the maintenance of genomic integrity. The main repair mechanisms operating in mammalian germline cells are: nucleotide excision repair (NER), base excision repair (BER), mismatch repair (MMR), DNA double strand break repair (DSBR), and post replication repair (PRR). Currently, there are relatively few publications that summarize basic information and new findings?on DNA repair mechanisms used in mammalian germ cells. In the present article, we review the studies that discuss repair mechanisms operating in the female and male germ cells. We then survey some of the recent discoveries made in this field.     

DNA interstrand crosslinks repair in mammalian cells

We studied the formation of double strand breaks (DSBs) as intermediates in the repair of DNA interstrand crosslinks (ICLs) by homologous recombination (HR). The plasmid EGFP-N1 was crosslinked with trioxsalen to give one ICL per plasmid on average. HeLa cells were transfected with the crosslinked plasmids and the ICL repair was monitored by following the restoration of the GFP expression. It was accompanied by gamma-H2AX foci formation suggesting that DSBs were formed during the process. However, the same amount of gamma-H2AX foci was observed when cells were transfected with native plasmid, which indicated that gamma-H2AX foci appearance could not be used to determine the amount of DSBs connected with the ICL repair in this system. For this reason we further monitored the DSB formation by determining the amount of linearized plasmids, since having one crosslink per plasmid on average, any ICL-driven DSB formation would lead to plasmid linearization. Native and crosslinked plasmids were incubated in repair-competent cell-free extracts from G1 and S phase HeLa cells. Although a considerable part of the ICLs was repaired, no linearization of the plasmids was observed in the extracts, which was interpreted that DSBs were not formed as intermediates in the process of ICL repair. In another set of experiments HR-proficient HeLa and HR-deficient irs3 cells were transfected with native and crosslinked plasmids, and 6 h and 12 h later the plasmid DNA was isolated and analyzed by electrophoresis. The same amount of linear plasmid molecules was observed in both cell lines, regardless of whether they were transfected with native or crosslinked pEGFP-N1, which further confirmed that DSB formation was not an obligatory step in the process of ICL repair by HR.     

DNA interstrand crosslink repair in mammalian cells

DNA damage by agents crosslinking the strands presents a formidable challenge to the cell to repair for survival and to repair accurately for maintenance of genetic information. It appears that repair of DNA crosslinks occurs in a path involving double strand breaks (DSBs) in the DNA. Mammalian cells have multiple systems involved in the repair response to such damage, including the Fanconi anemia pathway that appears to be directly involved, although the mechanisms and site of action remain elusive. A particular finding relating to deficiency of the Fanconi anemia pathway is the observation of chromosomal radial formations after ICL damage. The basis of formation of such chromosomal aberrations is unknown although they appear secondarily to DSBs. Here we review the processes involved in response to DNA interstrand crosslinks which might lead to radial formation and the role of the nucleotide excision repair gene, ERCC1, which is required for a normal response, not just to DNA crosslinks, but also for DSBs at collapsed replication forks caused by substrate depletion. J. Cell. Physiol. 220: 569–573, 2009. © 2009 Wiley‐Liss, Inc.     

DNA homologous recombination repair in mammalian cells

DNA double-strand breaks (DSBs) are the most serious DNA damage. Due to a great variety of factors causing DSBs, the efficacy of their repair is crucial for the cell's functioning and prevents DNA fragmentation, chromosomal translocation and deletion. In mammalian cells DSBs can be repaired by non-homologous end joining (NHEJ), homologous recombination (HRR) and single strand annealing (SSA). HRR can be divided into the first and second phase. The first phase is initiated by sensor proteins belonging to the MRN complex, that activate the ATM protein which target HRR proteins to obtain the second response phase--repair. HRR is precise because it utilizes a non-damaged homologous DNA fragment as a template. The key players of HRR in mammalian cells are MRN, RPA, Rad51 and its paralogs, Rad52 and Rad54.     

Base excision repair of DNA in mammalian cells

Base excision repair (BER) of DNA corrects a number of spontaneous and environmentally induced genotoxic or miscoding base lesions in a process initiated by DNA glycosylases. An AP endonuclease cleaves at the 5' side of the abasic site and the repair process is subsequently completed via either short patch repair or long patch repair, which largely require different proteins. As one example, the UNG gene encodes both nuclear (UNG2) and mitochondrial (UNG1) uracil DNA glycosylase and prevents accumulation of uracil in the genome. BER is likely to have a major role in preserving the integrity of DNA during evolution and may prevent cancer.     

DNA double strand break repair in mammalian cells

Human cells can process DNA double-strand breaks (DSBs) by either homology directed or non-homologous repair pathways. Defects in components of DSB repair pathways are associated with a predisposition to cancer. The products of the BRCA1 and BRCA2 genes, which normally confer protection against breast cancer, are involved in homology-directed DSB repair. Defects in another homology-directed pathway, single-strand annealing, are associated with genome instability and cancer predisposition in the Nijmegen breakage syndrome and a radiation-sensitive ataxia-telangiectasia-like syndrome. Many DSB repair proteins also participate in the signaling pathways which underlie the cell's response to DSBs.     

A yeast DNA repair gene partially complements defective excision repair in mammalian cells.

The RAD10 gene of Saccharomyces cerevisiae is required for nucleotide excision repair of DNA. Expression of RAD10 mRNA and Rad10 protein was demonstrated in Chinese hamster ovary (CHO) cells containing amplified copies of the gene, and RAD10 mRNA was also detected in stable transfectants without gene amplification. Following transfection with the RAD10 gene, three independently isolated excision repair-defective CHO cell lines from the same genetic complementation group (complementation group 2) showed partial complementation of sensitivity to killing by UV radiation and to the DNA cross-linking agent mitomycin C. These results were not observed when RAD10 was introduced into excision repair-defective CHO cell lines from other genetic complementation groups, nor when the yeast RAD3 gene was expressed in cells from genetic complementation group 2. Enhanced UV resistance in cells carrying the RAD10 gene was accompanied by partial reactivation of the plasmid-borne chloramphenicol acetyltransferase (cat) gene following its inactivation by UV radiation. The phenotype of CHO cells from genetic complementation group 2 is also specifically complemented by the human ERCC1 gene, and the ERCC1 and RAD10 genes have similar amino acid sequences. The present experiments therefore indicate that the structural homology between the yeast Rad10 and human Ercc1 polypeptides is reflected at a functional level, and suggest that nucleotide excision repair proteins are conserved in eukaryotes.     

Interference of DNA sequence divergence with precise recombinational DNA repair in mammalian cells.

Studies done in prokaryotes and eukaryotes have indicated that DNA sequence divergence decreases the frequency of homologous recombination. To determine which step(s) of homologous recombination is sensitive to DNA sequence divergence in mammalian cells we have used an assay that does not rely on the recovery of functional products. The assay is based on the acquisition by homologous recombination of endogenous LINE-1 sequences by exogenous LINE-1 sequences. In parallel experiments, we introduced into mouse cells two gapped exogenous LINE-1 sequences, one from the mouse, L1Md-A2, and the other from the rat, L1Rn-3. Although L1Rn-3 is on average less than 85% homologous to the LINE-1 elements of the mouse, the frequency of homologous recombination with endogenous LINE-1 elements obtained with L1Rn-3 was the same as the one obtained with L1Md-A2 which is on average 95% homologous to the LINE-1 elements of the mouse. The endogenous LINE-1 sequences rescued by L1Rn-3 were 8-18% divergent from L1Rn-3 sequences, whereas those rescued by L1Md-A2 were 2-5% divergent from L1Md-A2 sequences. The gap which had been introduced into the exogenous LINE-1 sequences had been precisely repaired in 50% of the recombinants obtained with L1Md-A2. None of the L1Rn-3 recombinants showed precise gap repair.(ABSTRACT TRUNCATED AT 250 WORDS)     

Long-patch DNA repair synthesis during base excision repair in mammalian cells

The base excision repair (BER) process removes base damage such as oxidation, alkylation or abasic sites. Two BER sub-pathways have been characterized using in vitro methods, and have been classified according to the length of the repair patch as either 'short-patch' BER (one nucleotide) or 'long-patch' BER (LP-BER; more than one nucleotide). To investigate the occurrence of LP-BER in vivo, we developed an assay using a plasmid containing a single modified base in the transcribed strand of the enhanced green fluorescent protein (EGFP) gene and a stop codon, based on a single-nucleotide mismatch, at varying distances on the 3' side of the lesion. The reversion of the stop codon occurs after DNA repair synthesis and restores EGFP expression after transfection of mismatch-repair-deficient cells. Repair patches longer than one nucleotide were observed for 55-80% or 80-100% of the plasmids with a mean length of 2-6 or 6-12 nucleotides for 8-oxo-7,8-dihydroguanine or a synthetic abasic site, respectively. These data show the existence of LP-BER in vivo, and emphasize the effect of the type of BER substrate lesion on both the yield and the extent of the LP-BER sub-pathway.     

Mitochondrial DNA repair of oxidative damage in mammalian cells

Nuclear and mitochondrial DNA are constantly being exposed to damaging agents, from endogenous and exogenous sources. In particular, reactive oxygen species (ROS) are formed at high levels as by-products of the normal metabolism. Upon oxidative attack of DNA many DNA lesions are formed and oxidized bases are generated with high frequency. Mitochondrial DNA has been shown to accumulate high levels of 8-hydroxy-2'-deoxyguanosine, the product of hydroxylation of guanine at carbon 8, which is a mutagenic lesion. Most of these small base modifications are repaired by the base excision repair (BER) pathway. Despite the initial concept that mitochondria lack DNA repair, experimental evidences now show that mitochondria are very proficient in BER of oxidative DNA damage, and proteins necessary for this pathway have been isolated from mammalian mitochondria. Here, we examine the BER pathway with an emphasis on mtDNA repair. The molecular mechanisms involved in the formation and removal of oxidative damage from mitochondria are discussed. The pivotal role of the OGG1 glycosylase in removal of oxidized guanines from mtDNA will also be examined. Lastly, changes in mtDNA repair during the aging process and possible biological implications are discussed.