Genotoxicity biomarkers in Mytilus galloprovincialis: wild versus caged mussels

A biomonitoring programme of wild and caged mussels (Mytilus galloprovincialis) was carried out at four selected sites along the Ligurian coast: Cornigliano, Voltri, Zinola, and Sanremo (Italy). Mussels of a very narrow size range were left in situ for 30 days. Adult specimen of mussels from natural substrates were collected in the same areas. Animals from a mussel farm located in La Spezia were used as controls. Micronucleus frequency and DNA single strand breaks, evaluated by alkaline elution, were used as biomarkers of genotoxicity. Mussels were also analyzed for polycyclic aromatic hydrocarbons (PAH) and heavy metals (Hg and Cd). Different gradients of PAH and metal concentrations were detected in tissues of mussels from different samplings sites. A weak correlation was found between single strand breaks and PAH content while MN frequency correlated with Hg concentration (r = 0.28, P < 0.002). A clear distinction between the sites, allowing classification along a pollution gradient (Sanremo < Zinola < Voltri < Cornigliano) was demonstrated by the analysis of genotoxicity parameters. The obtained results suggested that the micronucleus assay compared with DNA damage determination by alkaline elution allow to better discriminate the selected sites. DNA damage expressed as constant of elution (k ml(-1) x 10(3)) ranges from 30 +/- 9.6 to 89.60 +/- 40.10, and micronuclei frequency from 1.78 +/- 1.04 to 24.4 +/- 12.9, in control animals and in mussels from the most polluted site, respectively. Wild mussels accumulated significant concentrations of chemicals and showed a higher induction of chromosomal damage than caged mussels, expressed as micronuclei frequency. Caged mussels showed higher level of DNA damage than wild mussels, probably as a result of recent exposure. DNA damage was higher in September than in May, as opposed to micronuclei frequency being higher in May than in September. Endogenous and exogenous factors, such as change of pollutant input levels or compositions, could be considered the cause of such variability.     

Interspecies differences in DNA single strand breaks caused by benzo(a)pyrene and marine environment

The presence of DNA single strand breaks in untreated specimens of selected species, mosquito fish Gambusia affinis, painted comber Serranus scriba, blue mussel Mytilus galloprovincialis, spiny crab Maja crispata and sea cucumber Holothuria tubulosa as well as in 10 microg/g benzo(a)pyrene (BaP) treated mosquito fish, blue mussel and spiny crab was measured, using alkaline filter elution. Interspecies differences in alkaline elution profiles were observed and attributed to different lengths of DNA from different sources and to differences in the number of strand breaks present during normal cellular events in different phyla. Spiny crab hemocytes are more sensitive to action of BaP then blue mussel hemocytes and mosquito fish hepatocytes that could be explained by differences in the rates of distinct metabolic reactions and DNA repair among the investigated species. In field study, DNA single strand breaks were measured in hepatocytes of painted comber and in hemocytes of blue mussel and spiny crab from natural population specimens collected at eight sampling sites along Istrian coast, Croatia. Spatial variations in DNA integrity for each species were detected and revealed for the first time that spiny crab is responsive to different environmental conditions. Interspecies variations in the DNA integrity due to environmental conditions, confirmed species specific susceptibility to genotoxicity of certain environment that in long-term may modify the structure of marine communities. The multi-species approach in designing biomonitoring studies was suggested.     

Fractionation of DNA from marine invertebrate (Maja crispata, Mytilus galloprovincialis) haemolymph by alkaline elution.

1. An alkaline elution procedure for the detection of DNA damage in marine invertebrate haemolymph has been developed. 2. Provided that three criteria are optimized, such as buffer composition, small filter pores (0.22 microns GVWP 025 00, Millipore), and optimal amounts of haemolymph applied, flow rates may be changed within the range of 0.2 ml/min to 0.05 ml/min without adverse back-pressure on the filter and without blocking filter pores. 3. Under optimal conditions, 70% of mussel haemolymph DNA, and 80% of crab haemolymph DNA will be retained on the filter after 6 hr of elution, indicating shorter DNA in mussel haemolymph. 4. The technique is applicable for testing the in vivo effects of different compounds on DNA in marine invertebrates, and to measurements of DNA damage in naturally exposed mussels. 5. This argues an important case for the use of alkaline elution technique for assessment of environmental genotoxicity, and especially for investigation of DNA damage in different marine organisms which cover a broad range in their DNA molecular weights.     

Alkaline elution of rat testicular DNA: detection of DNA cross-links after in vivo treatment with chemical mutagens

The alkaline elution technique was used to measure DNA damage in the rat testis after intraperitoneal injection of 3 chemicals known to cause heritable mutations in rodents. These 3 chemicals are triethylenemelamine (TEM), mitomycin C, and cyclophosphamide. All three of these chemicals produced DNA damage which was readily detectable by alkaline elution. Both TEM and mitomycin C produced DNA interstrand cross-links, although TEM was a more potent cross-linker on an equimolar basis than mitomycin C. Cyclophosphamide produced both DNA cross-links and DNA strand breaks. Alkaline elution in the absence of proteinase K indicated that some of the strand breaks appeared to be closely associated with protein. These studied indicate that the alkaline elution technique is capable of detecting DNA damage in mammalian germ cells produced by chemical mutagens. This technique may prove useful as a screening tool for identifying chemicals which cause heritable mutations in mammals.     

Induction of chromosomal damage by restriction endonuclease in CHO cells porated with streptolysin O.

A procedure is described for the poration of living CHO cells with the bacterial cytotoxin streptolysin O (SLO) which allows the introduction into cells of the restriction endonuclease Pvu II to mimic and model the effects of ionising radiation in causing chromosomal damage. The dependence of this clastogenic effect of Pvu II on SLO concentration was measured by assaying the formation of micronuclei in cytokinesis-blocked binucleate cells. The optimum concentration was found to be 0.045 U/ml. Using the micronucleus assay, the time-course of expression of chromosome damage was investigated and found to show a biphasic kinetic with time. Using a sampling time of 30 h, a dose-effect curve for micronucleus induction by Pvu II was generated. Using this optimized SLO treatment protocol, the frequency of metaphase chromosome damage was subsequently investigated and found to be also linearly related to Pvu II concentration and total aberrations were approximately double the frequency of micronuclei. The induction and repair kinetics of DNA double-strand breaks were investigated in CHO cells treated with SLO and Pvu II using the neutral filter elution technique at pH 9.6. The data presented show that SLO can be used as an alternative method for porating cells to allow the introduction of restriction endonucleases into cells.     

Butachlor is cytotoxic and clastogenic and induces apoptosis in mammalian cells

The ability of butachlor to induce cytotoxicity, clastogenicity and DNA damage was assessed using Chinese hamster ovary cells (CHO), Swiss mouse embryo fibroblasts (MEF) and human peripheral blood lymphocytes. A dose and time dependent loss of viability was evident upon treatment of CHO cells with butachlor. Cell killing to an extent of 50% was observed when cells were treated with 16.2 micrograms/ml of butachlor for 24 hr or with 11.5 micrograms/ml for 48 hr. The herbicide induced micronuclei significantly in cultured lymphocytes at 24 and 48 hr of treatment suggesting that it is clastogenic. To understand the mechanism of cell death caused by butachlor, its effect on DNA strand breaks was studied in MEF. A concomitant decrease in cell viability was observed with increase in DNA strand breaks. Agarose gel electrophoresis of DNA from herbicide treated CHO cells and cytochemical staining indicate the induction of apoptosis by butachlor.     

Marine molluscs and fish as biomarkers of pollution stress in littoral regions of the Red Sea, Mediterranean Sea and North Sea

The intensive development of industry and urban structures along the seashores of the world, as well as the immense increase in marine transportation and other activities, has resulted in the deposition of thousands of new chemicals and organic compounds, endangering the existence of organisms and ecosystems. The conventional single biomarker methods used in ecological assessment studies cannot provide an adequate base for environmental health assessment, management and sustainability planning. The present study uses a set of novel biochemical, physiological, cytogenetic and morphological methods to characterize the state of health of selected molluscs and fish along the shores of the German North Sea, as well as the Israeli Mediterranean and Red Sea. The methods include measurement of activity of multixenobiotic resistance-mediated transporter (MXRtr) and the system of active transport of organic anions (SATOA) as indicators of antixenobiotic defence; glutathione S-transferase (GST) activity as an indicator of biotransformation of xenobiotics; DNA unwinding as a marker of genotoxicity; micronucleus test for clastogenicity; levels of phagocytosis for immunotoxicity; cholinesterase (ChE) activity and level of catecholamines as indicators of neurotoxicity; permeability of external epithelia to anionic hydrophilic probe, intralysosomal accumulation of cationic amphiphilic probe and activity of non-specific esterases as indicators of cell/tissue viability. Complete histopathological examination was used for diagnostics of environmental pathology. The obtained data show that the activity of the defensive pumps, MXRtr and SATOA in the studied organisms was significantly higher in the surface epithelia of molluscs from a polluted site than that of the same species from control, unpolluted stations, providing clear evidence of response to stress. Enhanced frequency of DNA lesions (alkaline and acidic DNA unwinding) and micronucleus-containing cells was significantly higher in samples from polluted sites in comparison to those from the clean sites that exhibited genotoxic and clastogenic activity of the pollutants. In all the studied molluscs a negative correlation was found between the MXRtr levels of activity and the frequency of micronucleus-containing hemocytes. The expression of this was in accordance with the level of pollution. The complete histopathological examination demonstrates significantly higher frequencies of pathological alterations in organs of animals from polluted sites. A strong negative correlation was found between the frequency of these alterations and MXRtr activity in the same specimens. In addition to these parameters, a decrease in the viability was noted in molluscs from the polluted sites, but ChE activities remained similar at most sites. The methods applied in our study unmasked numerous early cryptic responses and negative alterations of health in populations of marine biota sampled from the polluted sites. This demonstrates that genotoxic, clastogenic and pathogenic xenobiotics are present and act in the studied sites and this knowledge can provide a reliable base for consideration for sustainable development. Received: 2 March 1999 / Received in revised form: 2 August 1999 / Accepted: 3 August 1999     

Application of alkaline elution, Fast Micromethod and flow cytometry in detection of marine contamination.

DNA damage is an inescapable aspect of life in the biosphere. The presented investigations were an attempt to examine the response of a DNA damage as a biomarker of environmental quality in the mussels Mytilus galloprovincialis sampled at differently contaminated areas of Istrian coast, Northern Adriatic. The investigations were performed in order to get information about the genotoxic risk for marine organisms exposed to mixed environmental pollution, as well as the information about the presence of unknown mixture of genotoxic contaminants in the marine environment. Types of DNA damage detected are alkali-labile sites and single-strand breaks measured by Fast Micromethod, interstrand cross-links and DNA protein cross-links by alkaline filter elution and cell cycle disturbation by flow cytometry. The applicability of all three methods for marine quality control is discussed.     

Bleomycin-induced DNA-strand damage in isolated male germ cells

DNA strand damage in isolated male germ cells (MGC) was evaluated after in vitro exposure to bleomycin (BLM), a known genotoxin. The alkaline elution technique was used to determine DNA-strand breaks. Concentration-dependent strand damage was established following exposure to bleomycin for 1 h at 37 degrees C. Exposure at 0 degrees C resulted in an increase in the frequency of strand breaks as compared to those observed at 37 degrees C. Pretreatment of cells with deferoxamine (DM), an iron-selective chelating agent, abolished the DNA damage induced by bleomycin. Isolated male germ cells responded in a predictable and reproducible manner thus supporting their use in mechanistic studies of genotoxicity.     

Genotoxicity of human milk extracts and detection of DNA damage in exfoliated cells recovered from breast milk

Genotoxic agents of environmental or dietary origin may play a role in breast cancer initiation. The ability of extracts of human milk to cause mutations in S. typhimurium TA1538 and YG1019 and to induce micronuclei and DNA strand breaks in MCL-5 cells was investigated. Twenty samples from different donors were analysed and of these, 6 were adjudged to produce a positive mutagenic response in one or both bacterial strains. The same samples also induced significant micronucleus formation in MCL-5 cells. In the comet assay, 13/20 samples caused DNA strand breaks in MCL-5 cells. Viable exfoliated breast cells were recovered from fresh milk samples and the ability of milk extracts to cause DNA damage in these cells was demonstrated. The results show that human milk can contain components capable of causing genotoxic damage in test systems and in human breast cells, events that may be significant in the initiation of breast cancer.     

DNA cross-links in human leucocytes treated with vinyl acetate and acetaldehyde in vitro

Human leucocytes were incubated in the presence of vinyl acetate or acetaldehyde (10-20 mM) for 4 h at 37 degrees C in vitro. DNA damage was analysed by alkaline elution. None of the compounds induced a detectable increase in the frequency of DNA strand breaks. Cells exposed to 5 Gy of X-ray immediately after treatment and before alkaline elution showed a clear, dose-dependent retardation of the elution rate in comparison with X-irradiated control cells. These results demonstrate that both vinyl acetate and acetaldehyde induce DNA cross-links in human cells.     

Detection of DNA damage and repair by alkaline elution using human lymphocytes

The repair of DNA alkylation damage in human cells is poorly understood. We have adapted the alkaline elution technique for use with human peripheral blood lymphocytes in culture. We have also established conditions necessary for short-term culture of human lymphocytes. Lymphocyte growth which can be maintained for up to 30 days is dependent upon irradiated TK6 feeder cells and T-cell growth factor (crude TCGF). The amount of damage induced by a given concentration of methyl methane-sulfonate (MMS) is dependent upon cell number per ml of growth medium. The DNA damage measured, in lymphocytes, by alkaline elution is a composite of single strand breaks and alkali-labile lesions. Repair of this damage after appropriate recovery periods is also detectable. The irradiated feeder TK6 cells do not contribute to the number of strand breaks detected or the amount of recovery after treatment. This method offers a quick and reproducible means of detecting DNA damage and repair in human T-lymphocytes.     

DNA repair in lymphocytes from patients with secondary leukemia as measured by strand rejoining and unscheduled DNA synthesis

The ability to repair damage to DNA was compared in 2 groups of patients having undergone treatment for leukemia, one of which developed secondary leukemia (SL), and the other without signs of secondary malignancy (treated controls). Both were related to normal controls. DNA repair was assessed in isolated peripheral lymphocytes from the patients by measuring the rejoining of strand breaks following alkylation damage to the lymphocytes or by measuring unscheduled DNA synthesis. Day-to-day variability in the assays was considerable, but findings were that 5 out of 7 SL patients had repair deficiencies as measured by their ability to rejoin strand breaks, and 5 out of 7 had increased unscheduled DNA synthesis compared to treated and normal controls. All patients with SL and 4 out of 8 treated controls had inherent strand breaks in their DNA as compared to the normal controls when measured by alkaline elution.     

Alkaline step elution analysis of gamma-ray induced DNA strand breaks and repair in diploid yeast

Gamma-ray induction of DNA strand breaks and their repair was analysed in the diploid yeast strain D7 (Saccharomyces cerevisiae) by means of the alkaline step elution technique. A dose-dependent increase of DNA strand breakage was observed in the dose range 25-2000 Gy corresponding to 100 and 0.01 per cent survival. When, after exposure to gamma-irradiation, the cells were incubated for 2 h in liquid growth medium, the elution profiles reached the pattern of unirradiated controls, thus indicating the restoration of cellular DNA due to repair. The alkaline step elution analysis is found to be a useful and reproducible technique for studying the induction of DNA strand breaks and repair in yeast. In comparison with other current methods, such as alkaline sucrose gradients and DNA unwinding, this method appears to be more rapid, versatile and easier to handle.     

Genotoxic damage in field-collected three-spined sticklebacks (Gasterosteus aculeatus L.): a suitable biomonitoring tool?

Three-spined sticklebacks (Gasterosteus aculeatus L.) were collected during different sampling trails from three locations in Northern Germany, which differ in the amount of sewage-treatment effluent that they receive. Due to natural population developments, the size of the specimens caught decreased significantly from April to August. The fish were examined for DNA damage in their blood cells by means of the comet (single-cell gel electrophoresis, SCGE) assay and the micronucleus test (MT). The suitability of stickleback erythrocytes as indicators for genotoxic substances in water was assessed. The median level of strand breakage ranged from 5.23 to 9.67%, and decreased significantly from April to August. The difference between the locations was marginally significant. The amount of micronuclei was more variable (ranging from 0.40 to 4.35%), but appears to better reflect the pollution state of the sampling location. Significant differences between the locations were found. The relatively strong micronucleus induction found in this study may be related to the fish species selected. Contrary to the SCGE results, a significant increase in the number of micronuclei from April to August was observed. A significant negative correlation between strand breakage and micronuclei was found for the sticklebacks from the most polluted location and for the pooled data of all locations. The length of the fish was positively correlated with results of the SCGE and negatively with those of the MT, whereby males show a clearer relation between size and the amount of genotoxic damage. The test results are predominantly affected by seasonal impacts. This study indicates that the outcome of the SCGE and MT applied to sticklebacks is determined by multiple factors, which need to be identified first before these tests can be applied routinely. Because of the profound negative correlation between SCGE and MT results, we recommend to apply both tests for the evaluation of the genotoxic potential of surface waters.     

Radiosensitization of Chinese hamster V79 cells by bromodeoxyuridine substitution of thymidine: enhancement of radiation-induced toxicity and DNA strand break production by monofilar and bifilar substitution

Bromodeoxyuridine (BrdU) competes with thymidine (TdR) for incorporation into DNA of exponentially growing V79-171 cells. Such cells show an enhancement of the radiation response as determined by clonogenic survival and DNA damage measured by filter elution techniques after doses up to 15 Gy. The degree of radiosensitization for both survival and rates of alkaline and neutral elution are dependent on percentage BrdU substitution and independent of whether BrdU is in one strand only (monofilar) or both strands (bifilar) of the DNA duplex: e.g., for 16% BrdU substitution distributed either monofilarly or partially bifilarly, there is an enhancement factor for Do of 1.55. At this percentage substitution, the enhancement factor for the rate of alkaline elution is 1.75 and that for the rate of neutral elution is 1.54. The greater the percentage BrdU substitution, the larger was the enhancement ratio for survival and radiation-induced strand breaks in both monofilarly and bifilarly substituted cells. The increase in cell radiosensitivity caused by BrdU substitution shows a better correlation with the increase in radiation-induced double-strand breaks than with the increase in radiation-induced single-strand breaks.     

Chromosomal malsegregation and micronucleus induction in vitro by the DNA topoisomerase II inhibitor fisetin

The plant flavonol fisetin is a common dietary component that has a variety of established biological effects, one of which is the inhibition of the enzyme DNA topoisomerase II (topo II). Compounds that inhibit topo II can exert genotoxic effects such as DNA double strand breaks, which can lead to the induction of kinetochore- or CREST-negative micronuclei. Despite reports that fisetin is an effective topoisomerase II inhibitor, its genotoxic effects have not yet been well characterized. Genotoxicity testing of fisetin was conducted in TK6 and HL60 cell lines and the cells were analyzed for malsegregating chromosomes as well as for the induction of micronuclei. Using the cytokinesis-blocked CREST micronucleus assay to discriminate between micronuclei formed from chromosomal breakage (CREST-negative) and chromosomal loss (CREST-positive), a statistically significant increase in CREST-positive micronuclei was seen for all doses tested in both cell lines. CREST-negative micronuclei, however, were significantly increased at the higher test concentrations in the TK6 cell line. These data indicate that at low concentrations fisetin is primarily exerting its genotoxic effects through chromosomal loss and that the induction of DNA breaks is a secondary effect occurring at higher doses. To confirm these results, the ability of fisetin to inhibit human topoisomerase II-alpha was verified in an isolated enzyme system as was its ability to interfere with chromosome segregation during the anaphase and telophase periods of the cell cycle. Fisetin was confirmed to be an effective topo II inhibitor. In addition, significant increases in the number of mis-segregating chromosomes were observed in fisetin-treated cells from both cell lines. We conclude that fisetin is an aneugen at low concentrations capable of interfering with proper chromosomal segregation and that it is also an effective topo II inhibitor, which exerts clastogenic effects at higher concentrations.     

The effect of thymine starvation on chromosomal structure of Escherichia coli JG-151

Labelled DNA extracted from control and thymine starved cells was qualitatively characterized with respect to sedimentation properties in alkaline sucrose gradients. DNA isolated from cells undergoing loss of division ability demonstrated decreasing sedimentation velocity. Sedimentation profiles of DNA extracted from cells which were starved for thymine under conditions which allowed spontaneous recovery of division ability to occur, demonstrated an increase in DNA sedimentation velocity toward normal control value. It appears that while thymine starvation can result in single strand breaks, this damage is not irreversible, for under certain conditions rejoining of the breaks can occur.     

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.     

The induction of chromosomal damage in rat hepatocytes and lymphocytes II. Alkylation damage and repair of rat-liver DNA after diethylnitrosamine,dimethylnitrosamine and ethyl methanesulphonate in relation to clastogenic effects

Rat-liver DNA alkylation by diethylnitrosamine (DEN), dimethylnitrosamine (DMN) and ethyl methanesulphonate (EMS) was studied in an attempt to relate chromosome-damaging effects of these agents (the formation of micronuclei in hepatocytes; see preceding paper) to specific alkylation patterns. No correlation was observed between the induction of micronuclei and liver DNA N-alkylation, measured as 3- and 7-alkyl-purines. O⁶-Alkylguanine is probably not involved in micronucleus induction because it is lost from DNA too rapidly to explain the much more persistent clastogenic effects. In contrast, both the initial amounts of alkylphosphotriesters and the persistencies of these products roughly paralleled the respective effects on micronucleus induction. The possible involvement of alkylphosphotriesters or other O-alkylation products of comparable stabilities is discussed. Results with DMN suggest that part of the primary DNA methylation damage is converted into a secondary (DNA) lesion and that both the primary and secondary lesion(s) contribute to the process of micronucleus formation.