Mechanisms of human cell protection associated with genetic polymorphism

Systems ensuring protection of human cells against endogenous and exogenous mutagenic factors are considered in terms of genetic polymorphism. Some protection mechanisms are described, including those connected with capturing free radicals, biotransformation of xenobiotics, excision repair of DNA damage (excision of nitrous bases, nucleotides, mismatch repair). A special section is devoted to some issues of using antimutagens in context of genetic polymorphism. The problem of adaptive response is discussed, providing evidence for independence (in some cases) of DNA repair systems and the formation of adaptive response. Some results of the author obtained many years ago but still relevant are presented.__________Translated from Genetika, Vol. 41, No. 4, 2005, pp. 520–535.Original Russian Text Copyright © 2005 by Zasukhina.     

Adaptive response to gamma radiation in mammalian cells proficient and deficient in components of nucleotide excision repair

Cells preconditioned with low doses of low-linear energy transfer (LET) ionizing radiation become more resistant to later challenges of radiation. The mechanism(s) by which cells adaptively respond to radiation remains unclear, although it has been suggested that DNA repair induced by low doses of radiation increases cellular radioresistance. Recent gene expression profiles have consistently indicated that proteins involved in the nucleotide excision repair pathway are up-regulated after exposure to ionizing radiation. Here we test the role of the nucleotide excision repair pathway for adaptive response to gamma radiation in vitro. Wild-type CHO cells exhibited both greater survival and fewer HPRT mutations when preconditioned with a low dose of gamma rays before exposure to a later challenging dose. Cells mutated for ERCC1, ERCC3, ERCC4 or ERCC5 did not express either adaptive response to radiation; cells mutated for ERCC2 expressed a survival adaptive response but no mutation adaptive response. These results suggest that some components of the nucleotide excision repair pathway are required for phenotypic low-dose induction of resistance to gamma radiation in mammalian cells.     

Lymphocyte DNA adducts and polymorphism in the DNA repair enzyme XPD

The effect of genetic polymorphism of DNA repair enzyme on the DNA adduct levels was evaluated in this study. We explored the relationship between polymorphism in the nucleotide excision repair enzyme XPD and DNA adduct levels in lymphocytes. Lymphocyte DNA adducts were measured by a ³²     

Lymphocyte DNA adducts and polymorphism in the DNA repair enzyme XPD

The effect of genetic polymorphism of DNA repair enzyme on the DNA adduct levels was evaluated in this study. We explored the relationship between polymorphism in the nucleotide excision repair enzyme XPD and DNA adduct levels in lymphocytes. Lymphocyte DNA adducts were measured by a ³²     

Alternative pathways for the in vivo repair of O6-alkylguanine and O4-alkylthymine in Escherichia coli: the adaptive response and nucleotide excision repair.

The in vivo removal of three different O-alkylated bases from DNA was measured in Escherichia coli. Using monoclonal antibodies specific for O6-methylguanine, O6-ethylguanine and O4-ethylthymine we have monitored the removal of these lesions from six different strains to assess the relative contributions of the adaptive response and of nucleotide excision repair. During the first hour after DNA alkylation, O6-methylguanine, O6-ethylguanine and O4-ethylthymine lesions were repaired almost exclusively by nucleotide excision, except when the adaptive response was being constitutively expressed. In wild-type E. coli the adaptive response began to contribute to O6-methylguanine repair about one hour after alkylation, the time required for the full induction of the ada DNA methyltransferase. In contrast, the adaptive response did not play such a large role in the repair of O6-ethylguanine and O4-ethylthymine in wild-type E. coli, presumably because DNA ethylation damage is a poor inducer of the adaptive response; possible reasons for this poor induction are discussed. The repair of all three O-alkylated lesions was virtually absent in ada- uvr- bacteria suggesting that no alternative pathway is available for their repair, at least during the first two hours after alkylation. When the repair of O-alkylated bases was compromised by an ada- or by a uvr- mutation, the bacteria became more sensitive to alkylation induced killing and mutation.     

Role of base excision repair DNA glycosylases in hereditary and infectious human diseases

DNA glycosylases are enzymes that initiate base excision repair, which removes damaged bases from cell DNA. Recent data demonstrate that some genetic variants of two human DNA glycosylases, MUTYH and OGG1, are associated with an increased risk of cancer. In addition, various DNA glycosylases are involved in protection from some neurodegenerative diseases, immune disorders, and virus infections. On the other hand, DNA glycosylases of pathogenic microorganisms help them to evade the host defense mechanisms. Thus, DNA glycosylases are considered to be both potential therapeutic agents and drug targets.     

Expression of Escherichia coli dam gene in Bacillus subtilis provokes DNA damage response: N6-methyladenine is removed by two repair pathways.

The dam gene of Escherichia coli encodes a DNA methyltransferase that methylates the N6 position of adenine in the sequence GATC. It was stably expressed from a shuttle vector in a repair- and recombination-proficient strain of Bacillus subtilis. In this strain the majority of plasmid DNA molecules was modified at dam sites whereas most chromosomal DNA remained unmethylated during exponential growth. During stationary phase the amount of unmethylated DNA increased, suggesting that methylated bases were being removed. An ultraviolet damage repair-deficient mutant (uvrB) contained highly methylated chromosomal and plasmid DNA. High levels of Dam methylation were detrimental to growth and viability of this mutant strain and some features of the SOS response were also induced. A mutant defective in the synthesis of adaptive DNA alkyltransferases and induction of the adaptive response (ada) also showed high methylation and properties similar to that of the dam gene expressing uvrB strain. When protein extracts from B. subtilis expressing the Dam methyltransferase or treated with N-methyl-N'-nitro-N-nitroso-guanidine were incubated with [3H]-labelled Dam methylated DNA, the methyl label was bound to two proteins of 14 and 9 kD. Some free N6-methyladenine was also detected in the supernatant of the incubation mixture. We propose that N6-methyladenine residues are excised by proteins involved in both excision (uvrB) and the adaptive response (ada) DNA repair pathways in B. subtilis.     

Cellular heterogeneity in DNA alkylation repair increases population genetic plasticity

DNA repair mechanisms fulfil a dual role, as they are essential for cell survival and genome maintenance. Here, we studied how cells regulate the interplay between DNA repair and mutation. We focused on the adaptive response that increases the resistance of Escherichia coli cells to DNA alkylation damage. Combination of single-molecule imaging and microfluidic-based single-cell microscopy showed that noise in the gene activation timing of the master regulator Ada is accurately propagated to generate a distinct subpopulation of cells in which all proteins of the adaptive response are essentially absent. Whereas genetic deletion of these proteins causes extreme sensitivity to alkylation stress, a temporary lack of expression is tolerated and increases genetic plasticity of the whole population. We demonstrated this by monitoring the dynamics of nascent DNA mismatches during alkylation stress as well as the frequency of fixed mutations that are generated by the distinct subpopulations of the adaptive response. We propose that stochastic modulation of DNA repair capacity by the adaptive response creates a viable hypermutable subpopulation of cells that acts as a source of genetic diversity in a clonal population.     

Analysis of the polymorphisms XRCC1Arg194Trp and XRCC1Arg399Gln in gliomas

XRCC genes (X-ray cross-complementing group) were discovered mainly for their roles in protecting mammalian cells against damage caused by ionizing radiation. Studies determined that these genes are important in the genetic stability of DNA. Although the loss of some of these genes does not necessarily confer high levels of sensitivity to radiation, they have been found to represent important components of various pathways of DNA repair. To ensure the integrity of the genome, a complex system of DNA repair was developed. Base excision repair is the first defense mechanism of cells against DNA damage and a major event in preventing mutagenesis. Repair genes may play an important role in maintaining genomic stability through different pathways that are mediated by base excision. In the present study, we examined XRCC1Arg194Trp and XRCC1Arg399Gln polymorphism using PCR-RFLP in 80 astrocytoma and glioblastoma samples. Patients who had the allele Trp of the XRCC1Arg194Trp polymorphism had an increased risk of tumor development (OR = 8.80; confidence interval at 95% (95%CI) = 4.37-17.70; P < 0.001), as did the allele Gln of XRCC1Arg399Gln (OR = 1.01; 95%CI = 0.53-1.93; P = 0.971). Comparison of overall survival of patients did not show significant differences. We suggest that XRCC1Arg194Trp and XRCC1Arg399Gln polymorphisms are involved in susceptibility for developing astrocytomas and glioblastomas.     

How does a cell repair damaged DNA?

DNA in living cells is constantly subjected to different chemical and physical factors of the environment and to cell metabolites. Some changes altering DNA structure occur spontaneously. This raises the potential danger of harmful mutations that could be transmitted to offspring. To avoid the danger of mutations and changing genetic information, a cell is capable to switch on multiple mechanisms of DNA repair that remove damage and restore native structure. In many cases, removal of the same damage may involve several alternative pathways; this is very important for DNA repair under the most unfavorable conditions. This review summarizes data about all known mechanisms of eukaryotic DNA repair including excision repair (base excision repair and nucleotide excision repair), mismatch repair, repair of double-strand breaks, and cross-link repair. Special attention is given to the regulation of excision repair by different proteins—proliferating cell nuclear antigen (PCNA), p53, and proteasome. The review also highlights problem of bypassing irremovable lesions in DNA.Translated from Biokhimiya, Vol. 70, No. 3, 2005, pp. 341–359.Original Russian Text Copyright © 2005 by Sharova.     

After sun reversal of DNA damage: enhancing skin repair

UV-induced DNA damage has been directly linked to skin cancer, and DNA repair is an important protection against this neoplasm. This is illustrated by the genetic disease xeroderma pigmentosum wherein a serious defect in DNA repair of cyclobutane pyrimidine dimers dramatically increases the rate of skin cancer. In other instances in which skin cancer rates are elevated, deficits in DNA repair may also be one of the causal factors. For example, solid organ transplant patients have elevated rates of skin cancer that are correlated with the dose and length of exposure to immunosuppressive drugs (predominantly cyclosporine A (CsA) and ascomycin (FK506)-related tacrolimus). We have found that treatment of cultured epidermal cells with CsA or ascomycin inhibits their removal of DNA damage by about 20% at 24 h. In a further example, people with a polymorphism in the DNA repair gene 8-oxo-guanine glycosylase (OGG1) have an increased risk of skin cancer. We have found that the cells with this variant polymorphism have an increased sensitivity of about 20% to a broad range of cytotoxic agents. The DNA deficits caused by immunosuppressive drugs or the OGG1 polymorphism can be overcome by the delivery of DNA repair enzymes in liposomes. The data suggests that deficits in DNA repair, even if they are not as severe as in the case of XP, may contribute to increased rates of cancer, and that topical therapy with DNA repair enzymes may be a promising avenue for after-sun protection.     

Polymorphisms in DNA repair and environmental interactions

The repair of damage to DNA is critical to the survival of a cell. However, not all organisms nor all individuals express a similar response to challenges to their genetic material. Numerous polymorphisms in genes involved in DNA repair have been found in individuals with DNA repair-related disease as well as in the general population. Studies of these variants are critical in understanding the response of the cell to DNA damage. In some cases, these changes predispose the carrier to a greatly increased risk of cancer. In other cases, the effects are subtler and depend on interactions between the alleles of several genes, or with environmental factors. Consequently, the health effects of exposure to genotoxic or carcinogenic compounds or agents can depend on the variations in these genes. This review will highlight some of the effects that variants, found in many of the genes involved in human DNA repair pathways, have on the response to damage, and their role in susceptibility of the cell and organism to environmental genotoxins. This review will concentrate on the mismatch repair, nucleotide repair, base excision repair, strand break repair, and direct alkyl repair pathways.     

适应性突变的遗传学特征

基于大肠杆菌FC40菌株的研究结果表明,适应性突变依赖RecBCD重组途径的酶,要求SOS反应的部分基因功能,lac+回复突变序列都是在单核苷酸短重复序列处的一个碱基缺失。有证据表明有的适应性突变来自一个或多个暂时性的超突变的细胞亚群,它们的基因组发生大量的突变,转座子高频丢失。产生这种暂时性的超突变的增变子可能是因为细胞的MMR活性暂时不足,或是因错误翻译产生丧失了校读活性的DNA聚合酶III。其他一些研究系统虽然得到了一些同FC40菌株不一致的结论,但所有实验证据都表明,在饥饿等环境胁迫因子作用下,非生长或缓慢生长的细胞可以产生突变,这种突变具有生长依赖的自发突变所不同的一些遗传学特征。 Abstract:The research based on the Escherichia coli FC40 showed that adaptive mutations required the enzymes of RecBCD recombination pathway and some unknown proteins of SOS response,and the mutation spectrum of lac+ revertants is single-base deletions in the small mononucleotide repeats.Some evidence showed that the revertants with adaptive mutations partly come from one (or some) subset of transient hypermutable subpopulation of cells,in which high frequently losing of transposons and genome-wide mutations were observed.It was suggested that this kind of transient hypermutability may be due to the transient deficient activity of mismatch repair (MMR) system,or a defective epsilon unit of DNA polymerase III generated by mistranslation.Although other systems demonstrated some different mechanisms from FC40,all research works suggested that,adaptive mutations occurred in nondividing or nongrowing cells under environmental stresses,for example,starvation,displayed different genetic features from growth-dependent spontaneous mutation.     

Congenital DNA repair deficiency results in protection against renal ischemia reperfusion injury in mice

Cockayne syndrome and other segmental progerias with inborn defects in DNA repair mechanisms are thought to be due in part to hypersensitivity to endogenous oxidative DNA damage. The accelerated aging-like symptoms of this disorder include dysmyelination within the central nervous system, progressive sensineuronal hearing loss and retinal degeneration. We tested the effects of congenital nucleotide excision DNA repair deficiency on acute oxidative stress sensitivity in vivo . Surprisingly, we found mouse models of Cockayne syndrome less susceptible than wild type animals to surgically induced renal ischemia reperfusion injury, a multifactorial injury mediated in part by oxidative damage. Renal failure-related mortality was significantly reduced in Csb^−/– mice, kidney function was improved and proliferation was significantly higher in the regenerative phase following ischemic injury. Protection from ischemic damage correlated with improved baseline glucose tolerance and insulin sensitivity and a reduced inflammatory response following injury. Protection was further associated with genetic ablation of a different Cockayne syndrome-associated gene, Csa . Our data provide the first functional in vivo evidence that congenital DNA repair deficiency can induce protection from acute stress in at least one organ. This suggests that while specific types of unrepaired endogenous DNA damage may lead to detrimental effects in certain tissues, they may at the same time elicit beneficial adaptive changes in others and thus contribute to the tissue specificity of disease symptoms.     

The Fanconi anaemia components UBE2T and FANCM are functionally linked to nucleotide excision repair

The many proteins that function in the Fanconi anaemia (FA) monoubiquitylation pathway initiate replicative DNA crosslink repair. However, it is not clear whether individual FA genes participate in DNA repair pathways other than homologous recombination and translesion bypass. Here we show that avian DT40 cell knockouts of two integral FA genes--UBE2T and FANCM are unexpectedly sensitive to UV-induced DNA damage. Comprehensive genetic dissection experiments indicate that both of these FA genes collaborate to promote nucleotide excision repair rather than translesion bypass to protect cells form UV genotoxicity. Furthermore, UBE2T deficiency impacts on the efficient removal of the UV-induced photolesion cyclobutane pyrimidine dimer. Therefore, this work reveals that the FA pathway shares two components with nucleotide excision repair, intimating not only crosstalk between the two major repair pathways, but also potentially identifying a UBE2T-mediated ubiquitin-signalling response pathway that contributes to nucleotide excision repair.     

Mitomycin C-induced mutagenesis

The mutagenic effect of mitomycin C (MC) has been shown in the S phase of Crepic capillaris cells. The repair ability of MC-induced DNA lesions proves exceedingly high, due to post-replicative and excision repair processes. In the experiments with MC-pretreatment of Crepic capillaris cells, nonmutagenic concentration of 1 microgram/ml provides inducible repair system--"adaptive response", which considerably decreases the levels of mutagenesis induced by MC at concentrations of 10, 20 and 40 micrograms/ml. Under adaptive response, the action of methyltransferase is possible.     

Topical thymidine dinucleotide application protects against UVB-induced skin cancer in mice with DNA repair gene (Ercc1)-deficient skin

Topical application of thymidine dinucleotides (pTpT) provides some protection against the effects of UV on the skin, however, many details of the protective mechanism have yet to be elucidated. We have used mice with an epidermis-specific knockout for the nucleotide excision repair gene, Ercc1, to investigate the mechanisms of protection. pTpT offered no protection against the pronounced UV-induced short-term erythema and skin thickening responses that are characteristic of DNA repair-deficient skin. It also had no effect on UV-induced apoptosis in Ercc1-deficient cultured keratinocytes. However, in these short-term experiments in both skin and keratinocyte culture pTpT did cause a slight reduction in proliferation. pTpT application during a chronic UV irradiation protocol provided some protection from UVB-induced skin carcinogenesis in epidermis-specific Ercc1 knockout mice. The median tumour free survival time was increased in the pTpT-treated group and treated animals had fewer tumours. In addition, pTpT-treated animals developed fewer large inwardly growing skin lesions than untreated animals. Furthermore, the proliferation response was reduced in chronically irradiated, non-lesional pTpT-treated skin. We conclude that cancer protection by pTpT in our mice is not modulated by an upregulation of DNA repair, as protection appears to be independent of a functional nucleotide excision repair pathway. We hypothesise instead that protection by pTpT is due to a reduction in epidermal proliferation.