Chemical data of contaminants in water and sediments from the Doce River four years after the mining dam collapse disaster.

Chemical datasets describing the occurrence of both inorganic and organic contaminants along the Doce River Basin (DRB) could provide a better understanding of the potential impacts of a major mining dam collapse disaster combined to additional chronic sources of contamination. This data article presents datasets of main contaminants detected in the water and sediments sampled four years after the mining dam collapse in the DRB. A summary table of data obtained in the literature is also provided to allow a comparison of the variation of chemicals before, right after in 2015/2016 and after the event (current data). In addition, there are also provided physical-chemical parameters of water and sediments of different sampling sites, which could support the investigation of chemicals distribution. For this purpose, triplicate samples of water and sediment were obtained in 8 sampling sites along the DRB during wet and dry seasons of 2019, totalizing 48 samples of each environmental matrix. The sampling sites were strategically selected according to their different main sources of pollution along the river. Concentrations of trace elements and organic contaminants (polycyclic aromatic hydrocarbons, and pyrethroids) were determined in samples of water and sediments by inductively coupled plasma mass spectrometry (ICP-MS) and gas chromatography - mass spectrometry GC-MS, respectively. Main data obtained in the literature consisted in published reports from environmental agencies (IGAM) and private companies (RENOVA) as well as journal articles. The datasets provided may be useful to the stakeholders, which include scientific community, authorities and public agencies, and private companies interested to understand the impacts of the contaminants introduced along the River Basin four years after the environmental disaster.

SkinExplorer: a new high-tech platform to interact inside the skin by immersive virtual 3D cutaneous environment.

BACKGROUND: The confocal laser scanning microscope allows performing acquisition of several histological sections with precise visual morphological landmarks and their reconstruction. A powerful and modern confocal microscope enables to quickly reconstruct virtual 3D models. OBJECTIVE: The main goal was to develop a new platform to reconstruct complex mosaic serial data, interact with it in an immersive 3D environment, and give to the observers a feeling of 'presence' inside the skin. METHOD: We have developed novel methods that transform the data into alternative representation, well-suited to explore cutaneous structures in detail and to observe fields of data from different points of view. This new way of data reconstruction in volume requires optimization of intensities, automatic matching algorithms and depth alignment. RESULTS AND CONCLUSION: The new platform - SkinExplorer evolves as a 3D exploration prototype. This technology provides an immersive virtual environment to explore cutaneous microstructures. Several serial histological sections can be matched by stacks, aligned in depth by sections and merged together to be visualized as a whole. All these time-consuming steps have been dramatically speed-up using rapid image processing. The advantages of using virtual reality technologies such as the ones used in the SkinExplorer platform are automatic matching, precise alignment, better data perception, lower memory requirement, and higher quantity of simultaneously displayed data. This platform can render volumetric data and isosurfaces, separately or both at the same time. Lighting and depth perception are enhanced using 'Sphere Mapping', 'Ambient Occlusion', and 'Halo' methods when displaying iso-surfacic volume models with high complexity depth. The assets of the platform are to interpret complex three-dimensional data, to observe and explore 3D virtual models, and to show effects of cosmetic treatments.

Dehydroepiandrosterone and neurotrophins favor axonal growth in a sensory neuron-keratinocyte coculture model.

We have previously shown that axonal growth from a subset of sensory neurons was promoted by keratinocytes when the two cell types were co-cultured in a low calcium medium. This phenomenon involves the production of one or several diffusible factors. Here we show that the neuritogenic effect of keratinocytes was significantly reduced in the case of rat primary sensory dorsal root ganglion (DRG) neurons, or completely suppressed in the case of the sensory neuron cell line ND7-23, when the activity of neurotrophin receptors (Trk receptors) was blocked with K252a. This trophic effect apparently involved the activation of tyrosine kinase receptors A and B (TrkA and TrkB) expressed by subpopulations of small- to medium-sized DRG neurons, or only of TrkA receptors in the case of ND7-23 neurons. A residual neurite growth promoting effect of keratinocytes persisted in a fraction of DRG neurons after Trk receptor blockade. This effect was mimicked by the steroid dehydroepiandrosterone (DHEA) but not by other steroids such as pregnenolone, progesterone or 17beta-estradiol. The use of pharmacological agents which inhibit different steps of steroidogenesis indicated that DHEA was probably synthesized from cholesterol in keratinocytes. Our results strongly suggest that DHEA might act as a neurotrophic signal derived from keratinocytes to promote axonal outgrowth from a subpopulation of sensory neurons.

Effect of acyl donor chain length and substitutions pattern on the enzymatic acylation of flavonoids.

Rutin and esculin were enzymatically acylated with different aliphatic acids as acyl donors (fatty acids, dicarboxylic acids and omega-substituted fatty acids) by an immobilized lipase from Candida antarctica. The effect of the water content and the acyl donors pattern on the flavonoid initial acylation rate and conversion yield were investigated. The obtained results indicated that the water content of the medium has a strong effect on the performance of these reactions. The best conversion yields were reached when the water content was kept lower than 200 ppm. At low water content of the medium, these syntheses are influenced by carbon chain length and substitution pattern of the acyl donors. Higher conversion yields of esculin and rutin (>70%) were obtained with aliphatic acids having high carbon chain length (>12). Moreover, it has been found that the amine and thiol groups on omega-substituted fatty acid chain were unfavourable to these reactions. The 1H NMR and 13C NMR analyses of some synthesized esters (esculin and rutin palmitate) show that only monoesters were produced and that the esterification takes place on the primary OH of glucose moiety of the esculin and on the secondary 4"'-OH of the rhamnose residue of rutin.

Mutagenesis by O(6)-methyl-, O(6)-ethyl-, and O(6)-benzylguanine and O(4)-methylthymine in human cells: effects of O(6)-alkylguanine-DNA alkyltransferase and mismatch repair.

Double-stranded and gapped shuttle vectors were used to study mutagenesis in human cells by O(6)-methyl (m(6)G)-, O(6)-ethyl (e(6)G)-, and O(6)-benzylguanine (b(6)G), and O(4)-methylthymine (m(4)T) when these bases were incorporated site-specifically in the ATG initiation codon of a lacZ' gene. Vectors were transfected into either human kidney cells (293) or colon tumor cells (SO) or into mismatch repair defective human colon tumor cells (H6 and LoVo). Cellular O(6)-alkylguanine-DNA alkyltransferase (alkyltransferase) was optionally inactivated by treating cells with O(6)-benzylguanine prior to transfection. In alkyltransferase competent cells, the mutagenicity of all the modified bases was substantially higher in gapped plasmids than in double-stranded plasmids. Alkyltransferase inactivation increased mutagenesis by the three O(6)-substituted guanines in both double-stranded and gapped plasmids but did not affect m(4)T mutagenesis. In the absence of alkyltransferase, mutagenesis by m(6)G and to a lesser extent e(6)G in double-stranded vectors was higher in the mismatch repair defective H6 and LoVo cells than in SO or 293 cells indicating that e(6)G as well as m(6)G were subject to mismatch repair processing in these cells. The level of mutagenesis by m(4)T and b(6)G was not affected by mismatch repair status. When incorporated in gapped plasmids and in the absence of alkyltransferase, the order of mutagenicity for the modified bases was m(4)T > e(6)G congruent with m(6)G > b(6)G. The O(6)-substituted guanines primarily produced G-->A transitions while m(4)T primarily produced T-->C transitions. However, m(4)T also produced a significant number of T-->A transversion mutations in addition to T-->C transitions in mismatch repair deficient LoVo cells.

Glycation during human dermal intrinsic and actinic ageing: an in vivo and in vitro model study.

BACKGROUND: Non-enzymatic glycation occurring in normal human skin plays an important part in ageing. OBJECTIVES To visualize and quantify, in human subjects, the extent of glycation during human dermal intrinsic and actinic ageing, and to develop a reliable reproducible in vitro model for evaluating the efficacy of potential inhibitors of glycation. METHODS: By immunohistochemistry using a monoclonal antibody recognizing carboxymethyl lysine, an advanced glycation end-product (AGE) (first objective), and by incubating dead de-epidermized dermis (DED) with glucose to simulate ageing-induced glycation in a human dermal equivalent model (second objective). RESULTS: We found that glycation of the dermis generally arises after 35 years, then increases rapidly with intrinsic ageing. We also noticed an enhancement of glycation by solar irradiation that occurred via glycation of the elastic fibre network or solar elastosis tissue. In the model, production of AGEs appeared in a time-dependent way, mimicking glycation observed in vivo during chronological ageing. Irradiation of DED before incubation with glucose strongly enhanced induction of AGEs, corresponding to the effect of solar irradiation on AGEs observed in vivo. CONCLUSIONS: These results confirm a marked increase of AGEs during intrinsic ageing in normal human skin and also suggest that glycation is enhanced in photoaged skin.

Inactivation of human O(6)-alkylguanine-DNA alkyltransferase by modified oligodeoxyribonucleotides containing O(6)-benzylguanine.

Inactivation of the DNA repair protein O(6)-alkylguanine-DNA alkyltransferase (AGT) enhances tumor cell killing by therapeutic alkylating agents. O(6)-Benzylguanine (b(6)G) can inactivate AGT and is currently in clinical trials to enhance therapy. Short oligodeoxyribonucleotides containing b(6)G are much more effective inactivators, but their use for therapeutic purposes is likely to be compromised by metabolic instability. We have therefore examined the ability to inactivate AGT of an 11-mer oligodeoxyribonucleotide containing b(6)G (11-mpBG) when modified with terminal methylphosphonate linkages to protect it from nucleases. This modification did not reduce the ability to serve as a substrate/inactivator for AGT, and 11-mpBG had an ED(50) value of 1.3 nM, more than 300-fold lower than that for b(6)G. A similar oligodeoxyribonucleotide containing O(6)-methylguanine (m(6)G) was also found to be a good substrate (ED(50) value of 10 nM), but the benzylated form was repaired more rapidly and preferentially. When added to HT29 cell cultures, 5 microM 11-mpBG was able to cause a prolonged inactivation of cellular AGT for at least 72 h and to greatly sensitize the cells to killing by 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU). The 11-mpMG was ineffective at up to 20 microM, suggesting that the benzyl group allows better uptake into the cell. However, even with 11-mpBG, the 1000-fold decrease in potency toward AGT in HT29 cells compared to that toward the protein in vitro suggests that uptake may be a limiting factor. These results suggest that oligodeoxyribonucleotides such as 11-mpBG may prove to be useful drugs for potentiation of alkylating agent chemotherapy if uptake can be improved.

A histological study of human wrinkle structures: comparison between sun-exposed areas of the face, with or without wrinkles, and sun-protected areas.

Wrinkles are a major topic in dermocosmetology; the purpose of this work has been to go deeper into the knowledge of cutaneous damage underlying these modifications of skin surface. Up to now, the number of published works about the histological structure of wrinkles is not very large. Therefore to complete the findings, we studied 46 subjects of both sexes, between 57 and 98-year-old, enabling us to obtain 157 skin biopsies of wrinkles (face) and sun-protected areas (abdomen). We used different histological techniques involving histochemistry, immunohistochemistry, electron microscopy and quantification by image analysis in addition to classic standard techniques. This study has allowed us to confirm published structural modifications of wrinkles, but also to display many other original alterations. The increased thinning of the epidermis atrophied with age is confirmed by the study of desmoplakins outlining the cellular contours of keratinocytes. Such a thinning is accompanied by a decrease in several markers of epidermal differentiation at the bottom of the wrinkles: filaggrin, keratohyalin granules and transglutaminase I, disturbing desquamation and the capacity of the horny layer to retain water. The dermoepidermal junction is modified by a decrease of collagen IV and VII, which, combined with fewer and fewer oxytalan fibres under wrinkles, weakens this interface. The deposition of abnormal elastotic tissue in the dermis, with an interruption of these deposits under wrinkles and an atrophy of dermal collagen more pronounced under wrinkles, boosts the magnitude and depth of wrinkles. The composition of the other dermal constituents is also altered with, more particularly, a marked decrease of chondroitin sulphates in the papillary dermis under wrinkles, combined with an asymmetrical variation of glycosaminoglycans on both edges of wrinkles. The atrophy of the hypodermis, also more marked under wrinkles, with a thickening of fibrous lines, also makes the depth of wrinkles more pronounced. Wrinkle formation appears at the same time as numerous modifications in different cutaneous structures, which may be mutually amplified. Such a study by pointing out altered elements in skin physiology, makes the development of specific treatments possible in order to mitigate this unwelcome cutaneous deterioration.

Reaction of O6-benzylguanine-resistant mutants of human O6-alkylguanine-DNA alkyltransferase with O6-benzylguanine in oligodeoxyribonucleotides.

Inactivation of the human DNA repair protein, O6-alkylguanine-DNA alkyltransferase (AGT), by O6-benzylguanine renders tumor cells susceptible to killing by alkylating agents. AGT mutants resistant to O6-benzylguanine can be made by converting Pro140 to an alanine (P140A) or Gly156 to an alanine (G156A). These mutations had a much smaller effect on the reaction with O6-benzylguanine when it was incorporated into a short single-stranded oligodeoxyribonucleotide. Such oligodeoxyribonucleotides could form the basis for the design of improved AGT inhibitors. AGT and mutants P140A and G156A preferentially reacted with O6-benzylguanine when incubated with a mixture of two 16-mer oligodeoxyribonucleotides, one containing O6-benzylguanine and the other, O6-methylguanine. When the 6 amino acids located in positions 159-164 in AGT were replaced by the equivalent sequence from the Escherichia coli Ada-C protein (mutant AGT/6ada) the preference for benzyl repair was eliminated. Further mutation incorporating the P140A change into AGT/6ada giving mutant P140A/6ada led to a protein that resembled Ada-C in preference for the repair of methyl groups, but P140A/6ada did not differ from P140A in reaction with the free base O6-benzylguanine. Changes in the AGT active site pocket can therefore affect the preference for repair of O6-benzyl or -methyl groups when present in an oligodeoxyribonucleotide without altering the reaction with free O6-benzylguanine.

Comparison of mutagenesis by O6-methyl- and O6-ethylguanine and O4-methylthymine in Escherichia coli using double-stranded and gapped plasmids.

To compare mutagenesis by O6-methylguanine (m6G), O4-methylthymine (m4T) and O6-ethylguanine (e6G), and assess their genotoxicity in Escherichia coli, double-stranded and gapped plasmids were constructed containing a single m6G, e6G or m4T in the initiation codon (ATG) of a lacZ' gene. Modified base induced mutations were scored by the loss of lacZ' activity on X-gal-containing media resulting in formation of white or sectored (mutant) rather than blue (non-mutant) colonies. Genotoxicity experiments with gapped plasmids containing the modified bases indicated that m4T produced a greater number of bacterial colonies than m6G or e6G. m4T was more mutagenic (45% mutant colonies) than m6G (6%) or e6G (11%) in repair competent (w.t.) E. coli when incorporated in double-stranded plasmids. In gapped plasmids, m4T produced 99% mutant colonies (as was observed previously for e6G) in both w.t. E. coli or E. coli deficient in both O6-alkylguanine-DNA alkyltransferases as well as methylation-directed mismatch repair (ada(-)-ogt(-)-mutS[-]). m6G in gapped plasmids produced 62% mutant colonies in w.t. E. coli, but this percentage increased to 94% in the ada(-)-ogt(-)-mutS(-) strain. In double-stranded plasmids both m4T and m6G produced very similar distributions of mutant and non-mutant colonies in the ada(-)-ogt(-)-mutS(-) strain. These observations led to the conclusion that differences in the mutagenicity of m6G and m4T in w.t. E. coli were a result of preferential repair of m6G compared to m4T by alkyltransferase and mismatch repair mechanisms, and did not reflect differences in their respective coding efficiency or their inherent obstructiveness to DNA synthesis as was observed with e6G. The combination of alkyltransferase and mismatch repair was concluded to be primarily responsible for the apparent genotoxicity of m6G compared to m4T in double-stranded plasmids.

Repair of O6-benzylguanine by the Escherichia coli Ada and Ogt and the human O6-alkylguanine-DNA alkyltransferases.

O6-Methylguanine is removed from DNA via the transfer of the methyl group to a cysteine acceptor site present in the DNA repair protein O6-alkylguanine-DNA alkyltransferase. The human alkyltransferase is inactivated by the free base O6-benzylguanine, raising the possibility that substantially larger alkyl groups could also be accepted as substrates. However, the Escherichia coli alkyltransferase, Ada-C, is not inactivated by O6-benzylguanine. The Ada-C protein was rendered capable of reaction by the incorporation of two site-directed mutations converting Ala316 to a proline (A316P) and Trp336 to alanine (W336A) or glycine (W336G). These changes increase the space at the active site of the protein where Cys321 is buried and thus permit access of the O6-benzylguanine inhibitor. Reaction of the mutant A316P/W336A-Ada-C with O6-benzylguanine was greatly stimulated by the presence of DNA, providing strong support for the concept that binding of DNA to the Ada-C protein activates the protein. The Ada-C protein was able to repair O6-benzylguanine in a 16-mer oligodeoxyribonucleotide. However, the rate of repair was very slow, whereas the E. coli Ogt, the human alkyltransferase, and the mutant A316P/W336A-Ada-C alkyltransferases reacted very rapidly with this 16-mer substrate and preferentially repaired it when incubated with a mixture of the methylated and benzylated 16-mers. These results show that benzyl groups are better substrates than methyl groups for alkyltransferases provided that steric factors do not prevent binding of the substrate in the correct orientation for alkyl group transfer.

O6-ethylguanine and O6-benzylguanine incorporated site-specifically in codon 12 of the rat H-ras gene induce semi-targeted as well as targeted mutations in Rat4 cells.

To examine the miscoding properties of modified guanine residues bearing increasingly bulky O6-substituents, Rat4 cells, grown in the presence of O6-benzylguanine to deplete the DNA repair protein O6-alkylguanine-DNA alkyltransferase, were transfected with plasmids carrying H-ras genes in which O6-methyl, O6-ethyl- and O6-benzylguanine were substituted for the first, second or both the first and second guanine residues of codon 12 (GGA). DNA from isolated transformed colonies was amplified by PCR and directly sequenced by high-temperature manual and automated methods. The results show that O6-ethylguanine and O6-benzylguanine induced semi-targeted as well as targeted mutations, in contrast to O6-methylguanine, which induced only targeted mutations. When incorporated in place of the first guanine of H-ras codon 12, the targeted mutations induced by all these modified guanines were exclusively G-->A transitions. When incorporated at the second position of codon 12, O6-benzylguanine induced G-->A, G-->T and G-->C mutations. O6-Ethylguanine at the second position induced chiefly G-->A transitions, and O6-methylguanine induced G-->A transitions exclusively. Semi-targeted mutations were strictly G-->A at the base 3' to a position 1 adduct or 5' to a position 2 adduct. The mechanism for induction of targeted mutations probably involves decreasing preference to thymidine incorporation opposite an O6-modified guanine as the size of the O6-substituent increases, while the mechanism for non-targeted mutations may be related to abasic site formation or to translesion synthesis which might be made error-prone by obstructive DNA lesions in this context.

In vitro yeast (Saccharomyces cerevisiae) presqualene and squalene synthesis related to substrate and cofactor availability.

Squalene synthase catalyses the synthesis of squalene from trans-farnesyl diphosphate in 2 separate steps requiring NAD(P)H. The kinetics of this enzyme in different fractions extracted from a wild-type Saccharomyces cerevisiae were studied. Although this protein is known to be a membrane-bound enzyme, we have found a cytosolic squalene synthase activity besides the microsomal enzyme. A spectrophotometric enzyme assay, not involving isotopic labelling, was established. The relative synthesis of presqualene and squalene was evaluated by using different substrate and cofactor concentrations during the incubation. The involvement of a single catalytic site promoting the 2 reactions of squalene synthesis is suggested.

Plasmodium berghei: implication of intracellular glutathione and its related enzyme in chloroquine resistance in vivo.

Glutathione (GSH) plays a critical role in the detoxication and the protection of cells against oxidative stress. In the present study we examined the relationship between the intracellular GSH levels as well as glutathione S-transferase (GST), glutathione reductase (GR), and glutathione peroxidase (GPx) activities and how they relate to Plasmodium berghei resistance to chloroquine. Resistant strains (CQR30 and CQR60) were selected in vivo from a sensitive strain (NK65). Marked increases in GSH levels and GST activity within resistant parasites were observed, compared to sensitive parasites. On the other hand, GR and GPx activities were similar in sensitive and resistant parasites. Treatment with chloroquine did not influence the intracellular level of GSH, but it was found to significantly decrease GR activity. Intracellular depletion of GSH, by a nontoxic concentration of buthionine sulfoximine (BSO), significantly sensitized the resistant parasites to chloroquine. These results suggest that the P. berghei resistance results from altered GSH and GST levels and activity, respectively, which enable the detoxification of chloroquine in resistant parasites.

Mutagenesis in Escherichia coli by three O6-substituted guanines in double-stranded or gapped plasmids.

Plasmids were constructed with guanine (G) or O6-methyl- (m6G), O6-ethyl-(e6G), or O6-benzyl- (b6G) guanine in the initiation codon (ATG) of the lacZ' gene. Four deoxyuridine residues were incorporated near the modified guanine in the complementary strand. The deoxyuridine-containing plasmids exhibited similarly high transformation efficiencies in ung- Escherichia coli, although the frequency of mutations induced by m6G, e6G, and b6G residues was relatively low. Treatment of the plasmids with uracil-DNA glycosylase (UDG), to remove the uracil residues, or UDG and exonuclease III, to create a gap in the deoxyuridine-containing strand, reduced transformation efficiency for adduct-containing plasmids but did not affect transformation efficiency for control plasmids. However, the same treatments dramatically enhanced mutagenesis by m6G, e6G, and b6G. These results were consistent with blockage of replication by the modified guanines in double-stranded plasmids resulting in preferential replication of the complementary strand. Replication past the modified guanines was forced in the gapped plasmids. The frequency of modified guanine-induced mutations in gapped vectors was similar in strains of E. coli that were proficient in DNA polymerase III but deficient in either DNA polymerase I or II or both polymerase I and II suggesting either that polymerase III was primarily responsible for adduct bypass in all strains or that the probability of base misinsertion during bypass by either polymerase I or II was similar to that for polymerase III. Repair studies with gapped plasmids indicated that m6G was subject to repair by Ada methyltransferase and to postreplication processing by methylation-directed mismatch repair. Neither e6G nor b6G were similarly repaired.(ABSTRACT TRUNCATED AT 250 WORDS)

Mechanism of action of bisimidazoacridones, new drugs with potent, selective activity against colon cancer.

Antitumor bisimidazoacridones are bifunctional DNA binders which have recently been shown to selectively target human colon carcinoma cells in vitro and in vivo and appear to be excellent candidates for clinical development. We have studied the mechanism of action of one bisimidazoacridone, WMC26, which is 1,000-10,000 times more toxic to human colon carcinoma cells (HCT116) than to melanoma cells (SKMEL2) in vitro. Plasmid DNA exposed to WMC26 showed enhanced digestion by DNase I at A-T-rich sites, suggesting alterations in DNA conformation upon drug binding. These results led us to investigate whether WMC26 was selectively toxic due to a specific recognition of DNA bends by repair excinucleases, as has been demonstrated with the DNA bisintercalator, ditercalinium. Both prokaryotic and eukaryotic cells with intact repair capacity were shown to be selectively sensitive to WMC26, strongly indicating that excision repair plays a role in its toxicity. Confocal microscopy studies utilizing fluorescence of the WMC26 chromophore showed compound localization in the perinuclear cytoplasmic area, as had been previously noted for ditercalinium, indicating that cytoplasmic DNA could be the target. This irreversible accumulation of compound was gradually followed by vacuolization of the cytoplasm and cell death. Cell cycle analysis of both lines treated with WMC26 or with ditercalinium showed that, while the latter induced HCT116 growth arrest at G1-G0, WMC26 also blocked the cell cycle at G2-M; SKMEL2 cells did not undergo any changes in cell cycle as a result of either treatment. Our data show that WMC26 is 10-100 times more cytotoxic than ditercalinium in vitro. Like ditercalinium, WMC26 appears to exert its toxicity via cytoplasmic elements, through a mechanism involving excision repair processes. However, its highly selective cytotoxicity may stem from additional undefined targets in sensitive colon cancer cells.

Response of repair-competent and repair-deficient Escherichia coli to three O6-substituted guanines and involvement of methyl-directed mismatch repair in the processing of O6-methylguanine residues.

Plasmids containing a site-specifically incorporated O6-methyl- (m6G), O6-ethyl- (e6G), or O6-benzylguanine (b6G) within the ATG initiation codon of the lacZ' gene were used to transform Escherichia coli that were repair proficient or deficient in one or both of the E. coli O6-alkylguanine-DNA alkyltransferases, the uvr(ABC) excision repair system, the recA-mediated recombination system, or the methylation-directed mismatch repair system. Colonies were scored phenotypically for adduct-induced mutations. With plasmids containing either e6G or b6G, the frequency of adduct-induced mutation was low and independent of the repair proficiency of the strain transformed. Plasmids containing an m6G residue elicited similar responses in all but the mismatch repair-deficient strain. The generally low mutagenicity of all the O6-substituted guanines was interpreted as reflecting an adduct-induced arrest of replication of the modified strand while the unmodified complementary strand was replicated normally. Studies of the involvement of mismatch repair in m6G mutagenesis showed that m6G:T base pairs were more readily processed than m6G:C base pairs, indicating that mismatch repair involving m6G residues occurs after replication. These data support a model in which the E. coli methylation-directed mismatch repair system diverts plasmids containing promutagenic m6G:T base pairs into replication-arrested complexes providing another line of defense against O6-methylguanine mutagenicity in addition to O6-alkylguanine-DNA alkyltransferase repair and excision repair mechanisms.

The role of O6-alkylguanine-DNA alkyltransferase in protecting Rat4 cells against the mutagenic effects of O6-substituted guanine residues incorporated in codon 12 of the H-ras gene.

The role of rat O6-alkylguanine-DNA alkyltransferase (AGT) in modulating mutagenesis by O6-substituted guanines in the rat H-ras gene was examined. Rat4 cells were transfected with vectors carrying O6-methyl-, O6-ethyl- or O6-benzylguanine residues in place of the normal guanines at either the first, second, or both the first and second positions in codon 12 (GGA) of the H-ras coding sequence. The percentage of transformed colonies was determined for cells grown in normal medium or in medium containing O6-benzylguanine to completely deplete AGT. In parallel experiments with O6-methylguanine-containing vectors, the percentage of cellular DNA harboring codon 12 mutations was determined for normal cells and cells lacking AGT. A reasonable correspondence was observed between the percentage of mutated DNA and the percentage of transformed colonies produced in both types of cells. The results indicate that the contribution of AGT to the repair of O6-substituted guanine damage decreases as the O6 substituent is changed from methyl > ethyl > benzyl. Additionally, cellular AGT appears to repair an O6-methylguanine more readily at the first position of codon 12 than the second position. However, other repair mechanisms in these mammalian cells appear to play a major role in correcting low levels of O6-substituted guanine damage including O6-methylguanine damage.

A sectored colony assay for monitoring mutagenesis by specific carcinogen-DNA adducts in Escherichia coli.

To study the mutagenicity of various carcinogen-DNA adducts in Escherichia coli, a cassette plasmid was developed that permits positioning of specific carcinogen-modified bases within the ATG initiation codon of the lacZ' alpha-complementation gene. Adduct-induced mutations inactivate the gene and lead to formation of blue and white sectored colonies when transformants from an alpha-complementing version of E. coli strain AB1157 are grown on media containing 5-bromo-4-chloro-3-indolyl beta-D-galactoside. In the absence of mutation, blue colonies are produced. This system has been used to measure the mutagenicity of O6-methyl-, O6-ethyl-, and O6-benzyl-2'-deoxyguanosine residues incorporated in place of the normal 2'-deoxyguanosine of the ATG initiation codon. Although a low percentage of sectored colonies was produced in this repair-proficient strain, pretreatment of the bacteria with N-methyl-N'-nitro-N-nitrosoguanidine to disable DNA repair led to a dose-dependent increase in the percentage of sectored colonies. This percentage increased as a function of modified guanine in the order O6-benzyl- less than O6-methyl- less than O6-ethyl-2'-deoxy-guanosine. The only mutations detected at the site of incorporation of these O6-substituted guanines were G-to-A transitions. This sectored colony assay system permits convenient screening of large numbers of colonies and simplifies quantification of modified-base-induced mutations whether they be single-base changes, frameshifts, insertions, or deletions.