Heavy Metal Exposure Influences Double Strand Break DNA Repair Outcomes

Heavy metals such as cadmium, arsenic and nickel are classified as carcinogens. Although the precise mechanism of carcinogenesis is undefined, heavy metal exposure can contribute to genetic damage by inducing double strand breaks (DSBs) as well as inhibiting critical proteins from different DNA repair pathways. Here we take advantage of two previously published culture assay systems developed to address mechanistic aspects of DNA repair to evaluate the effects of heavy metal exposures on competing DNA repair outcomes. Our results demonstrate that exposure to heavy metals significantly alters how cells repair double strand breaks. The effects observed are both specific to the particular metal and dose dependent. Low doses of NiCl₂ favored resolution of DSBs through homologous recombination (HR) and single strand annealing (SSA), which were inhibited by higher NiCl₂ doses. In contrast, cells exposed to arsenic trioxide preferentially repaired using the “error prone” non-homologous end joining (alt-NHEJ) while inhibiting repair by HR. In addition, we determined that low doses of nickel and cadmium contributed to an increase in mutagenic recombination-mediated by Alu elements, the most numerous family of repetitive elements in humans. Sequence verification confirmed that the majority of the genetic deletions were the result of Alu-mediated non-allelic recombination events that predominantly arose from repair by SSA. All heavy metals showed a shift in the outcomes of alt-NHEJ repair with a significant increase of non-templated sequence insertions at the DSB repair site. Our data suggest that exposure to heavy metals will alter the choice of DNA repair pathway changing the genetic outcome of DSBs repair.     

Role of active oxygen species in metal-induced DNA strand breakage in human diploid fibroblasts

The ability of 6 metal salts to induce DNA damage in human diploid fibroblasts was examined. Cadmium, magnesium, manganese, chromium(VI), zinc and selenite were all shown to induce DNA strand breaks as measured by two independent assays. DNA strand breaks were repaired within 2-4 h after removal of metal and this repair appeared not to be sensitive to "long-patch" repair inhibitors. With the exception of selenite, metal-induced DNA damage appeared to be mediated via the formation of active oxygen species since oxygen scavengers when administered simultaneously with the metal, antagonized strand break formation. Selenite-induced DNA damage (as previously reported) was dependent on the formation of a selenite-glutathione conjugant and was not affected by oxygen radical scavengers. Scavenger treatment did not enhance cloning ability of metal-treated cells suggesting that DNA strand breaks may not be important in metal-induced cytotoxicity.     

ELECTRON MICROSCOPY OF DNA MOLECULES "STAINED" WITH HEAVY METAL SALTS

Single DNA molecules can be rendered visible in the electron microscope by "staining" with water-soluble salts of heavy metals. The best results were obtained with lanthanum nitrate, uranyl acetate, and lead perchlorate. The molecules appear as filaments approximately 20 A wide. Their length was not determined, but it could be shown that it varied with the molecular weight of the DNA used. The same heavy metal salts will preferentially "stain" the nucleic acid in a protein-DNA complex. Evidence is provided for the possibility of a partial separation of a double-stranded molecule into single strands on adsorption to the supporting film.     

Characterization of DNA lesions produced by HgCl2 in cell culture systems

HgCl2 is extremely cytotoxic to Chinese hamster ovary (CHO) cells in culture since a 1-h exposure to a 75- microM concentration of this compound reduced cell plating efficiency to 0 and cell growth was completely inhibited at 7.5 microM . The level of HgCl2 toxicity depended upon the culture incubation medium and has previously been shown to be inversely proportional to the extracellular concentration of metal chelating amino acids such as cysteine. Thus, HgCl2 toxicity in a minimal salts/glucose maintenance medium was about 10-fold greater than the toxicity in McCoy's culture medium. The HgCl2 toxicity in the latter medium was 3-fold greater than that in alpha-MEM which contains more of the metal chelating amino acids. When cells were exposed to HgCl2 there was a rapid and pronounced induction of single strand breaks in the DNA at time intervals and concentrations that paralleled the cellular toxicity. The DNA damage was shown to be true single strand breaks and not alkaline sensitive sites or double strand breaks by a variety of techniques. Consistent with the toxicity of HgCl2, the DNA damage under an equivalent exposure situation was more pronounced in the salts/glucose than in the McCoy's medium and more striking in the latter medium than in alpha-MEM. Most of the single strand breaks occurred within 1 h of exposure to the metal. We believe that the DNA damage caused by HgCl2 leads to cell death because the DNA single strand breaks are not readily repaired. DNA repair activity measured by CsCl density gradient techniques was elevated above the untreated levels at HgCl2 concentrations that produced little measurable binding of the metal to DNA or few single strand breaks assessed by the alkaline elution procedure. DNA repair activity decreased at HgCl2 concentrations that produced measurable DNA binding and single strand breaks. These irreversible interactions of HgCl2 with DNA may be responsible for its cytotoxic action in cells.     

Cadmium inhibits human DNA mismatch repair in vivo

The heavy metal cadmium (Cd) is a human carcinogen that inhibits DNA repair activities. We show that DNA mismatch repair (MMR)-mediated cell cycle arrest after alkylation damage is suppressed by exposure to Cd and that this effect is reversed by preincubation with excess of zinc (Zn). We show that Cd-mediated inactivation of MMR activity is not caused by disruption of complex formation between the MMR proteins hEXO1-hMutS alpha and hEXO1-hMutL alpha nor does Cd inhibit 5'-exonuclease activity of hEXO1 in vitro. Thus, our studies show that exposure of human cells to Cd suppresses MMR activity, a repair activity known to play an important role in colon cancer and that this effect can be reversed by Zn treatment.     

A comparative investigation of DNA strand breaks, sister chromatid exchanges and K-ras gene mutations induced by cadmium salts in cultured human cells

Cadmium (Cd) is a toxic heavy metal of continuing occupational and environmental concern with a wide variety of adverse effects. Several studies have shown that cadmium produces DNA strand breaks, DNA-protein cross-links, oxidative DNA damage, chromosomal aberrations, dysregulation of gene expression resulting in enhanced proliferation, depressed apoptosis and/or altered DNA repair. This study was undertaken to investigate the ability of cadmium chloride (CdCl(2)) and cadmium sulphate (CdSO(4)) to induce point mutations in codon 12 of the K-ras protooncogene assessed by polymerase chain reaction-single strand conformation polymorphisms (PCR-SSCP) and RFLP-enriched PCR methods. Also their genotoxic effects were analyzed by the comet assay and sister chromatid exchanges test. The human lung fibroblast cell line MRC-5 was used for the experiments. Sister chromatid exchanges assay (SCEs) frequencies were significantly increased in cells exposed to cadmium salts in relation to controls (p<0.001). Despite the slow increment observed in the three comet parameters considered when cells were treated with cadmium chloride, significant differences between groups were only found in the variable comet moment (CM) (p<0.005). On the other hand, when cells were exposed to cadmium sulphate, the Kruskal-Wallis test showed highly significant differences between groups for migration, tail moment and comet moment parameters (p<0.001). Nevertheless, a null or weak point mutation induction in K-ras protooncogene was detected using polymerase chain reaction-low ionic strength-single strand conformation polymorphisms (PCR-LIS-SSCP) and RFLP-enriched PCR methods when cells were treated with cadmium salts. Thus, inorganic cadmium produces genotoxicity in human lung fibroblast MRC-5 cells, in the absence of significant point mutation of the K-ras gene.     

Inhibition by metals of X-ray and ultraviolet-induced DNA repair in human cells

A number of metals have been shown to be involved in the etiology of animal and human neoplasms. The molecular mechanisms have not yet been determined, but the observed plethora of genetic effects observed following treatment of mammalian cells with metals clearly indicates the possibility that metals can exert their effects at least partially at the level of DNA metabolism. Several studies have suggested that metal treatment may inhibit normal DNA repair processes in procaryotic and eucaryotic cells but a systematic study of this question has not previously been conducted. The present study surveyed the ability of 15 metal salts to interfere with repair of X-ray or UV-induced DNA damage in HeLa cells. Hg⁺⁺, As⁺⁺⁺, Cu⁺⁺, Ni⁺⁺, Co⁺⁺, and Cd⁺⁺ were shown to inhibit the excision of pyrimidine dimers from DNA and to do so in a dose-dependent fashion. Inhibition of repair by only Ni⁺⁺ and Co⁺⁺ resulted in the accumulation of long-lived DNA strand breaks suggestive of a block in the gap-filling stage of repair. Ability to inhibit repair was not correlated with cytotoxicity. X-ray repair was sensitive to Hg⁺⁺, Ni⁺⁺, As⁺⁺⁺, Ga⁺⁺, Zn⁺⁺, and Mo(VI). All inhibitory metals inhibited closure of single strand DNA breaks. Ga⁺⁺ appeared, in addition, to inhibit a later step involving chromatin reconstitution. These findings support the notion that interference of DNA repair processes may be a consequence of exposure of mammalian cells to certain metals. This may be a factor in the etiology of metal-associated carcinogenesis.     

Glutathione level of Desulfovibrio desulfuricans IMV K-6 under the influence of heavy metal salts

Glutathione is the metal stress protector and changes of its level in the sulfate-reducing bacteria cells under the influence of heavy metal salts have not been studied yet. CdCl2, Pb(NO3)2, CuCl2, and ZnCl2 influence on the total glutathione level in cell-free extracts of sulfate-reducing bacteria Desulfovibrio desulfuricans IMV K-6 was studied. The research has been carried out using Ellman, Lowry methods, statistical processing of the results. It was shown that the glutathione level depends on the heavy metal salts concentration in the medium. The total glutathione level was the highest under the influence of Pb(NO3)2. Other salts were also toxic to bacteria because glutathione level increased in bacterial cells after addition of these salts to the medium. On the basis of the results of our work the range of heavy metal salts influence on D. desulfuricans IMV K-6 cells glutathione level has been formed for the first time: Pb(NO3)2 > CuCl2 > CdCl2 > ZnCl2.     

Genetic toxicology of ethylenediaminetetraacetic acid (EDTA)

EDTA and its salts have a number of applications in medicine and pharmacy. EDTA is used to remove calcium from the human body, and serves as an anticoagulant and as a detoxicant after poisoning by heavy metals. It is often used in analytical chemistry for complexometric titrations and many other purposes. Because the compound is of rather low toxicity, it is used as a food additive to bind metal ions. EDTA affects the inhibition of DNA synthesis in primary cultures of mammalian cells. This may be due to impairment of enzymes involved in DNA replication. Some early studies have shown that EDTA leads to morphological changes of chromatin and chromosome structure in plant and animal cells. These alterations consist of dispersion or swelling of chromosomes or a loss of interphase chromatin structure. For several test systems, a low chromosome-breaking activity of EDTA has been reported. A weak activity in the induction of gene mutations has also been observed. It is well established that EDTA influences chromosome breakage by mutagenic agents. In particular, when applied in combination with chemical mutagens, EDTA enhances mutagen-induced aberration frequencies. Furthermore, the chelating agent is able to increase the incidence of meiotic crossing-over. This has been demonstrated for many gene loci in Drosophila melanogaster, Chlamydomonas reinhardi, Neurospora crassa and Zea mays. EDTA interferes with DNA repair processes that take place after exposure to mutagens. In E. coli or Micrococcus radiodurans as well as in Chinese hamster cells, the fast repair component detectable after treatment with ionizing radiation or bleomycin is inhibited by EDTA. In plant cells exposed to gamma-rays, EDTA inhibits unscheduled DNA synthesis. The mechanism by which EDTA causes these effects remains poorly understood. The sequestering of metal ions by the chelating agent is obviously responsible for functional and structural alterations of the genetic material. Although EDTA produces a whole set of genetic effects it seems to be a harmless compound to man as far as genotoxicity is concerned. The data presently at hand, however, are not sufficient for a reliable risk assessment.     

Characterization of stress induced by copper and zinc on cucumber (Cucumis sativus L.) seedlings by means of molecular and population parameters

Contamination of plants with heavy metals could result in damage in DNA, such as mutations and cross-links with proteins. These altered DNA profiles may become visible in changes such as the appearance of a new band, or loss of an existing band, in the random amplified polymorphic DNA (RAPD) assay. In this study, various concentrations of copper and zinc salts were applied to cucumber seedlings during germination. Results displayed abnormalities in germination and also changes in root elongation, dry weight and total soluble protein level. All treatment concentrations (40, 80, 160, 240, 320, and 640mg/L) used in the study caused a decrease/delay in germination of the cucumbers to different extents. Inhibition or activation of root elongation was considered to be the first effect of metal toxicity in the tested plants. Application of the metal salts and the combined solutions on cucumber (Cucumis sativus L.) seedlings revealed similar consequences for total soluble protein level, dry weight and ultimately in inhibitory rates as well. The data obtained from RAPD band-profiles and genomic template stability (GTS) showed results that were consistent with the population parameters. In this regard, we conclude that molecular marker assays can be applied in combination with population parameters to measure genotoxic effects of heavy metals on plants.     

Selective metal binding to Cys-78 within endonuclease V causes an inhibition of catalytic activities without altering nontarget and target DNA binding

T4 endonuclease V is a pyrimidine dimer-specific DNA repair enzyme which has been previously shown not to require metal ions for either of its two catalytic activities or its DNA binding function by virtue of its ability to function in the presence of metal-chelating agents. However, we have investigated whether the single cysteine within the enzyme was able to bind metal salts and influence the various activities of this repair enzyme. A series of metals (Hg2+, Ag+, Cu+) were shown to inactivate both endonuclease Vs pyrimidine dimer-specific DNA glycosylase activity and the subsequent apurinic nicking activity. The binding of metal to endonuclease V did not interfere with nontarget DNA scanning or pyrimidine dimer-specific binding. The Cys-78 codon within the endonuclease V gene was changed by oligonucleotide site-directed mutagenesis to Thr-78 and Ser-78 in order to determine whether the native cysteine was directly involved in the enzyme's DNA catalytic activities and whether the cysteine was primarily responsible for the metal binding. The mutant enzymes were able to confer enhanced ultraviolet light (UV) resistance to DNA repair-deficient Escherichia coli at levels equal to that conferred by the wild type enzyme. The C78T mutant enzyme was purified to homogeneity and shown to be catalytically active on pyrimidine dimer-containing DNA. The catalytic activities of the C78T mutant enzyme were demonstrated to be unaffected by the addition of Hg2+ or Ag+ at concentrations 1000-fold greater than that required to inhibit the wild type enzyme. These data suggest that the cysteine is not required for enzyme activity but that the binding of certain metals to that amino acid block DNA incision by either preventing a conformational change in the enzyme after it has bound to a pyrimidine dimer or sterically interfering with the active site residue's accessibility to the pyrimidine dimer.     

Heavy metal ions affect the activity of DNA glycosylases of the Fpg family

Prokaryotic enzymes formamidopyrimidine-DNA glycosylase (Fpg) and endonuclease VIII (Nei) and their eukaryotic homologs NEIL1, NEIL2, and NEIL3 define the Fpg family of DNA glycosylases, which initiate the process of repair of oxidized DNA bases. The repair of oxidative DNA lesions is known to be impaired in vivo in the presence of ions of some heavy metals. We have studied the effect of salts of several alkaline earth and transition metals on the activity of Fpg-family DNA glycosylases in the reaction of excision of 5,6-dihydrouracil, a typical DNA oxidation product. The reaction catalyzed by NEIL1 was characterized by values K _m = 150 nM and k _cat = 1.2 min⁻¹, which were in the range of these constants for excision of other damaged bases by this enzyme. NEIL1 was inhibited by Al³⁺, Ni²⁺, Co²⁺, Cd²⁺, Cu²⁺, Zn²⁺, and Fe²⁺ in Tris-HCl buffer and by Cd²⁺, Zn²⁺, Cu²⁺, and Fe²⁺ in potassium phosphate buffer. Fpg and Nei, the prokaryotic homologs of NEIL1, were inhibited by the same metal ions as NEIL1. The values of I₅₀ for NEIL1 inhibition were 7 μM for Cd²⁺, 16 μM for Zn²⁺, and 400 μM for Cu²⁺. The inhibition of NEIL1 by Cd²⁺, Zn²⁺, and Cu²⁺ was at least partly due to the formation of metal-DNA complexes. In the case of Cd²⁺ and Cu²⁺, which preferentially bind to DNA bases rather than phosphates, the presence of metal ions caused the enzyme to lose the ability for preferential binding to damaged DNA. Therefore, the inhibition of NEIL1 activity in removal of oxidative lesions by heavy metal ions may be a reason for their comutagenicity under oxidative stress.     

Oxidative Damage to DNA and Deoxyribose by β-Lactam Antibiotics in the Presence of Iron and Copper Salts

β-lactam antibiotics in the presence of certain metal ions damage deoxyribose and DNA with the release of thiobarbituric acid-reactive material. This damage can be substantially prevented by catalase, metal chelators and some scavengers of the hydroxyl radical. Ferric salts in the presence of certain β-lactam antibiotics were effective in degrading deoxyribose but they did not appear to damage DNA. In contrast copper salts and p-lactam antibiotics were extremely effective in damaging both DNA and deoxyribose.     

Current aspects in metal genotoxicity

While carcinogenic metal ions are mostly non-mutagenic in bacteria, different types of cellular damage have been observed in mammalian cells, which may account for their carcinogenic potential. Two modes of action seem to be predominant: the induction of oxidative DNA damage, best established for chromium compounds, and the interaction with DNA repair processes, leading to an enhancement of genotoxicity in combination with a variety of DNA damaging agents. In the case of Cd(II), Ni(II), Co(II), Pb(II) and As(III), DNA repair processes are disturbed at low, non-cytotoxic concentrations of the respective metal compounds. Even though different steps in DNA repair are affected by the diverse metals, one common mechanism might be the competition with essential metal ions.     

Advances in Cotton Tolerance to Heavy Metal Stress and Applications to Remediate Heavy Metal-Contaminated Farmland Soil

Heavy metal-contaminated soil is one of the major environmental pollution problems of agricultural production and human health in the world. Remediation of heavy metals in soil is one of the most popular research subjects. Different remediation strategies have been reported to remove heavy metals from contaminated soil, among which phytoremediation is the most important one. Compared with other major crops, cotton shows the strongest and most widespread resistance to abiotic stresses, such as heavy metals. Although heavy metal stress adversely affects the growth and development of cotton, cotton possesses a set of sophisticated stress-resistance strategies. As the main product of cotton is nonedible fibers, which have a large biomass and strong heavy metal absorption and enrichment capacities, cotton is an ideal crop to restore heavy metal-contaminated soils and has unique advantages in terms of both ecological and economic benefits, with great application prospects. In this review, based on domestic and foreign research results in recent years, the effects of heavy metals on cotton growth and product quality were analyzed, the heavy metal absorption, accumulation, translocation and enrichment characteristics of cotton plants were summarized, and the adaptation and tolerance mechanisms of cotton to heavy metals were explored. Furthermore, the view that cotton is an effective crop to remediate heavy metal pollution in farmland soil has been proposed, and popularization and application suggestions for planting cotton to repair heavy metal pollution have been put forward to provide a reference for the comprehensive evaluation of the economic feasibility of cotton to repair heavy metal pollution in farmland soil.     

Sodium dodecyl sulfate-gel electrophoresis: staining of polypeptides using heavy metal salts

Water-soluble salts of several heavy metals were examined for their ability to stain polypeptides resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Brief gel exposure (5 min or less) to cobaltous acetate or chlorides of copper, nickel, and zinc produced negatively stained protein patterns that were qualitatively indistinguishable from those of parallel gels stained with Coomassie blue R-250. Protein patterns could be visualized less than 1 min after treatment of gels with zinc chloride; the threshold of detection was estimated at about 10-12 ng protein on standard-size slab gels. Test samples including human erythrocyte membranes, sialoglycoprotein (glycophorin) extracts, and commercial molecular weight protein standards were used to establish the scope of these stains. Protein patterns visualized by the heavy metal salts were compared and contrasted with profiles seen with three widely used silver stains. Proteins from gels treated with copper or zinc chloride could be easily recovered by simple diffusion; this makes feasible both analytical and preparative electrophoretic applications of the staining procedure. A mechanism is proposed to explain the observed protein staining by heavy metal salts.     

The transmembranous passes of K+ in brain cortex under radiation and chemical influences and their modification with natural adaptogen

An investigation of the influence of chronic low-intensity irradiation with 0.25 Gr dose and of a mixture of heavy metal salts both apart and together, as well as when correcting with a natural adaptogen such as Spirulina platensis, on passive and active transport of potassium and the work efficiency of Na,K-pump in slices of brain cortex was the problem of this study. As a biological model for in vivo researches on molecular-cellular level the thin layers of a rat brain cortex were used. It was shown that both radiation and chemical factors cause reliable changes of passive membrane permeability and operation of Na,K-pump, whose function is the maintenance of the certain gradient of potassium ions on the plasmatic membrane, the normalization of ion homeostasis, the stabilization of membranous potential. The analysis of calculated indexes of passive and of active ion transport show that at modification of X-rays influence with a mixture of heavy metal salts exactly the last makes the main contribution to efficiency decrease of energy-dependent transport of potassium. The natural adaptogen spirulina renders a better effect in the case of toxic action of the mixture of heavy metal salts, enlarging not only active transport of potassium ions, but its efficiency as well.