Searching for antigenotoxic properties of marine macroalgae dietary supplementation against endogenous and exogenous challenges.

The functional characterization of marine macroalgae toward their potential to strength genome protection is still scarce. Hence, the aim of this study was to assess the antigenotoxic potential of Ulva rigida, Fucus vesiculosus, and Gracilaria species in Drosophila melanogaster following dietary exposure and adopting the somatic mutation and recombination test (SMART). All macroalgae displayed a genoprotection activity, namely against an exogenous challenge (streptonigrin). The action against subtler endogenous pressures was also noted indicating that supplementation level is a critical factor. Gracilaria species provided ambivalent indications, since 10% of G. vermiculophylla inhibited the egg laying and/or larvae development, while 10% of G. gracilis promoted spontaneous genotoxicity. The effects of U. rigida were modulated (in intensity) by the growing conditions, demonstrating higher genoprotection against streptonigrin-induced damage when grown in an aquaculture-controlled system, while the effectiveness against spontaneous genotoxicity was more apparent in specimens grown under wild conditions. In contrast, F. vesiculosus did not produce significant differences in its potential under varying growing conditions. Overall, these findings shed some light on the macroalgae ability toward genome protection, contributing to the development of algaculture industry, and reinforcing the concept of functional food and its benefits.

The radiomimetic compound streptonigrin induces persistent telomere dysfunction in mammalian cells.

We analyzed the chromosomal aberrations involving telomeres in the progeny of mammalian cells exposed to the radiomimetic compound streptonigrin (SN) in order to determine if this antineoplastic drug induces long-term telomere instability. To this end, rat cells (ADIPO-P2 cell line, derived from adipose cells from Sprague-Dawley rat) were treated with a single concentration of SN (100ng/ml), and chromosomal aberrations were analyzed 18h and 10 and 15 days after treatment by using PNA-FISH with a pan-telomeric probe [Cy3-(CCCTAA)3] to detect (TTAGGG)n repeats. Cytogenetic analysis revealed a higher frequency of telomere dysfunction-related aberrations (additional telomeric FISH signals, extra-chromosomal telomeric FISH signals, and telomere FISH signal loss and duplications) in SN-exposed cultures vs. untreated cultures at every time points analyzed. The yield of SN-induced aberrations remained very similar at 18h, 10 days as well as 15 days after treatment. Thus, our data demonstrate that SN induces persistent telomere dysfunction in mammalian cells. Moreover, we found that the level of telomerase activity in SN-treated cells was significantly lower (up to 77%) than that of untreated control cells at each time points analyzed. This fact suggests that telomerase could be involved in SN-induced telomere dysfunction.

Streptonigrin induces delayed chromosomal instability involving interstitial telomeric sequences in Chinese hamster ovary cells.

We analyzed the induction of chromosomal aberrations in Chinese hamster ovary (CHO) cells exposed to the radiomimetic compound streptonigrin (SN), in order to determine whether interstitial telomeric sequences (ITSs) are involved in the long-term clastogenic effect of this antibiotic. CHO cells were treated with a single concentration of SN (100ng/ml), and the frequency of unstable chromosomal aberrations was determined at three times after treatment (18h, and 6 and 15 days) by using PNA-FISH with a pan-telomeric probe. Cytogenetic analysis revealed a higher frequency of aberrations at 18h and 6 days after treatment in SN-exposed cultures vs. untreated cultures. The percentage of damaged cells and the yield of SN-induced aberrations at 6 days after treatment increased on average twofold compared with the ones at 18h after treatment. Moreover, a significant decrease in the frequency of aberrations was observed in SN-exposed cells at 15 days after treatment, resulting in a frequency of aberrations significantly lower than the frequency of aberrations observed in the corresponding control cultures. These data indicate that SN induces delayed chromosomal instability in CHO cells, and that the in vitro clastogenic effect of this compound persists for at least 6 days but less than 15 days after treatment. In addition, we found that SN induces delayed ITSs instability, cytogenetically detectable as additional FISH signals and centromeric breaks involving dissociation of the telomeric signal 6 days after treatment. We propose that the delayed effect of SN on ITSs results from breakage of heterochromatic centromeric ITSs blocks and further insertion of these sequences at the sites of mono- or isochromatid breaks occurring at G2 or G1-S phases of the cell cycle, respectively, since most of the additional FISH signals were present as single or double dots, and located at interstitial sites of the involved chromosomes.

Synthesis, metabolism and in vitro cytotoxicity studies on novel lavendamycin antitumor agents.

A series of lavendamycin analogues with two, three or four substituents at the C-6, C-7 N, C-2', C-3' and C-11' positions were synthesized via short and efficient methods and evaluated as potential NAD(P)H:quinone oxidoreductase (NQO1)-directed antitumor agents. The compounds were prepared through Pictet-Spengler condensation of the desired 2-formylquinoline-5,8-diones with the required tryptophans followed by further needed transformations. Metabolism and toxicity studies demonstrated that the best substrates for NQO1 were also the most selectively toxic to NQO1-rich tumor cells compared to NQO1-deficient tumor cells.

Analysis of streptonigrin-induced incomplete chromosome elements and interstitial fragments in Chinese hamster cells using a telomeric PNA probe.

We investigated the induction of incomplete chromosome elements (ICEs; i.e., elements with a telomeric signal at only one terminal end) and interstitial fragments induced by the antibiotic streptonigrin (SN) in a Chinese hamster embryo (CHE) cell line using FISH with a telomeric peptide nucleic acid probe. CHE cells were treated with 0-250 ng/ml SN and chromosomal aberrations were analyzed in the first mitosis after treatment using the telomeric probe. Exposure of CHE cells to SN resulted in a linear concentration-related increase in all of the aberration types analyzed (P < 0.05) except ring chromosomes. Depending on the SN concentration employed, 33-68% of the metaphases contained one or more pairs of ICEs (an incomplete chromosome accompanied by a terminal fragment or two incomplete chromosomes accompanied by a compound fragment). Pooled data from all SN concentrations revealed that 77.8% of the acentric fragments were terminal fragments, 18.8% interstitial fragments, and 3.4% compound fragments. Furthermore, it was estimated that about 80% of excess acentric fragments induced by SN originated from incomplete exchanges or terminal deletions and 20% from complete exchanges (interstitial deletions). These results show that incomplete chromosomes and terminal fragments are the most frequent asymmetrical chromosomal aberrations induced by SN and indicate that true incompleteness is a very common event following exposure to SN.

Novel lavendamycin analogues as potent HIV-reverse transcriptase inhibitors: synthesis and evaluation of anti-reverse transcriptase activity of amide and ester analogues of lavendamycin.

Novel lavendamycins including two water soluble derivatives were synthesized via short and efficient methods. Pictet-Spengler condensation of 7-N-acylamino-2-formylquinoline-5,8-diones with tryptophans produced lavendamycin esters or amides 11-17. Lavendamycins 18-21 were obtained, respectively, by further transformations of 13-15 and 17. Several lavendamycins were found to be potent HIV reverse transcriptase inhibitors with very low toxicity in vitro and in vivo. Several compounds also acted either additively or synergistically to inhibit enzyme activity together with AZT-triphosphate.

Genotoxicity of streptonigrin: a review.

Streptonigrin (SN, CAS no. 3930-19-6) is an aminoquinone antitumor antibiotic isolated from cultures of Streptomyces flocculus. This compound is a member of a group of antitumor agents which possess the aminoquinone moiety and that includes also mitomycin C, porfiromycin, actinomycin, rifamycin and geldanamycin. Because of the potential use of SN in clinical chemotherapy, the study of its genotoxicity has considerable practical significance.SN inhibits the synthesis of DNA and RNA, causes DNA strand breaks after reduction with NADH, induces unscheduled DNA synthesis and DNA adducts and inhibits topoisomerase II. At the chromosome level, this antibiotic causes chromosome damage and increases the frequency of sister-chromatid exchanges.SN cleaves DNA in cell-free systems by a mechanism that involves complexing with metal ions and autoxidation of the quinone moiety to semiquinone in the presence of NADH with production of oxygen-derived reactive species. Recent evidence strongly suggests that the clastogenic action of this compound is partially mediated by free radicals. The present review aims at summarizing past and current knowledge concerning the genotoxic effects of SN.

Modulation of streptonigrin's clastogenic effects in CHO cells by the metal-chelating agent 1,10-phenanthroline.

The effect of the metal-chelating agent 1,10-phenanthroline (PNT) on the clastogenesis induced by streptonigrin (SN) in CHO cells was investigated. When CHO cells were exposed to SN, chromosomal aberrations (CAs) and sister-chromatid exchanges (SCEs) were formed in a dose-dependent manner (P < 0.05). When PNT was present in the culture medium, the production of CAs by SN was strongly inhibited (inhibition range = 54.9-80.8%). Similarly, the induction of SCEs by SN was significantly decreased by the addition of PNT to CHO cultures (P < 0.05), although the effect was minor. This finding suggests that intracellular transition metals are implicated in the clastogenesis by SN, and that the Fenton reaction (Fe(2+) + H2O2 --> OH* + OH(-) + Fe(3+)) may be responsible for the production of CAs by this compound. Moreover, the fact that PNT did not completely inhibit the induction of SCEs by SN suggests that this phenomenon might be attributable to a different mechanism, in which transition metals and free radicals play a minor role.

60 Hz magnetic fields do not enhance cell killing by genotoxic chemicals in Ataxia telangiectasia and normal lymphoblastoid cells.

Ataxia telangiectasia (AT) is an inherited autosomal recessive disease characterized by increased risk of cancer, immune deficiency, and neurodegeneration. Cells cultured from AT patients are highly sensitive to genotoxic agents and are deficient in cell cycle arrest after exposure to ionizing radiation. In consideration of their sensitivity to both ionizing and nonionizing radiation, AT cells may provide a sensitive model system to study the biological activity of other components of the electromagnetic spectrum. To characterize the effects of power-frequency (60 Hz) magnetic fields (MFs) in AT cells, we compared responses of AT and normal lymphoblast cells to sinusoidal MFs at 1.0 mT, either alone or in combination with the genotoxic agents mitomycin C or streptonigrin. The MF alone had no effect on cell growth or survival in a clonogenic assay in either AT or normal cells. The MF also had no effect on induction of cell death by mitomycin C or streptonigrin in either cell type. AT cells do not demonstrate differential sensitivity to MF exposure. These results do not support the hypothesis that MFs interact with genotoxic agents to induce adverse biological effects in either normal or genetically susceptible human cells.

The isolation and genetic analysis of V79-derived etoposide sensitive Chinese hamster cell mutants: two new complementation groups of etoposide sensitive mutants.

Using a replica plating microwell method, three Chinese hamster V79-derived cell lines, designated ETO1, ETO2 and ETO3, which exhibit hypersensitivity to the non-intercalating topoisomerase II inhibitor etoposide have been isolated. Mutant lines ETO2 and ETO3 are cross-sensitive to the topoisomerase II inhibitors adriamycin and streptonigrin; however, neither mutant is sensitive to the topoisomerase I inhibitor camptothecin, the bifunctional alkylating agent mitomycin C, nor hydrogen peroxide. In contrast, ETO1 is cross-sensitive to camptothecin but displays only slight sensitivity to adriamycin, streptonigrin and hydrogen peroxide, and is not sensitive to mitomycin C. It has been established through extensive cell fusion studies that all three mutants are genetically distinct, and that ETO2 and ETO3 genetically complement all other known etoposide-sensitive Chinese hamster cell mutants (i.e., irs1, XR-1, xrs1, V3, BLM2, ADR1, ADR3, ADR4 and ADR5) thus defining two new complementation groups of etoposide sensitive mutants. Interestingly, the hybrids created by the fusion irs2TOR (thioguanine and ouabain resistant)xETO1 and the reciprocal cross ETO1TORxirs2 both exhibited a response to camptothecin intermediate with respect to V79 and ETO1. It has been hypothesised that this partial complementation may be the result of intragenic complementation and that both ETO1 and irs2 result from mutations in the gene XRCC8. This study indicates that cellular responses to topoisomerase II inhibitors are complex and hypersensitivity may result from mutations in many different genes.

Mutagenicity and cytotoxicity of reactive oxygen and nitrogen species in the MN-11 murine tumor cell line.

There is increasing evidence that endogenously generated reactive oxygen (ROS) and reactive nitrogen (RNS) species at sites of inflammation and in tumors may be genotoxic. We have developed a murine tumor model (MN-11) in which mutations at the hypoxanthine phosphoribosyltransferase (HPRT) locus, arising both in vitro and in vivo, can be detected. In the present report, we describe an in vitro study of the ability of ROS and RNS to induce mutations in our model system. 137Cs radiation and radiomimetic drugs caused a dose-dependent increase in mutant frequency. At D0, radiation induced about 170 mutants per 10(5) viable cells, compared to 50 and 95 for streptonigrin and bleomycin, respectively. H2O2 induced a lower frequency of mutants, 20-30 per 10(5), for enzymatically generated or bolus, respectively. For the following treatments, mutant frequency at 50% survival is shown. Incubation with human granulocytes induced a low frequency of mutants (about 15 per 10(5)). RNS was tested using a series of NO-donating drugs. Spermine/NO. induced cytotoxicity but no mutants while S-nitroso-N-acetylpenicillamine induced a low level, 10 per 10(5). Both release nitrogen monoxide spontaneously, with a t1/2 < 3 h. Glyceryl trinitrate and sodium nitroprusside are two drugs that were slowly metabolized by MN-11 cells (> 12 h). Glyceryl trinitrate induced about 20 per 10(5) while nitroprusside induced 50 per 10(5). Our results indicate that RNS can readily induce mutations detectable in MN-11 cells. At equicytotoxic doses, the induced mutant frequency varied considerably for different drugs, suggesting that different states of nitrogen monoxide (such as NO+ or NO.) may be generated and these may vary in their mutagenic/cytotoxic potential.

Molecular analysis of Salmonella hisG428 ochre revertants for rapid characterization of mutational specificity.

The Salmonella typhimurium tester strains TA104 and TA102 were developed primarily to aid in the detection of oxidative mutagens and other agents that react preferentially with AT base pairs. Reversion of prototrophy of strains harboring the hisG428 ochre allele can occur by (i) any of seven single base substitutions or (ii) several tandem double base substitutions at the ochre codon, (iii) in-frame deletions removing all or part of the ochre codon or (iv) mutations at several distinct tRNA extragenic suppressor loci. We have used allele-specific oligonucleotide probes and DNA sequence analysis to characterize 625 revertants of strain TA104 (hisG428, rfa, DeltauvrB/pKM101) arising spontaneously or after treatment with methyl methane-sulfonate, glyoxal, streptonigrin or angelicin with UVA radiation. The reversion profiles obtained from these analyses distinguished readily each of the mutagen-treated populations from one another and from spontaneously derived revertants. Both GC and AT base pair-specific revertants were observed. Molecular analyses of S. typhimurium hisG428 revertants permitted rapid assessment of base pair substitution specificity of mutagens, especially the detection of AT base pair substitutions not recovered in strains carrying the complementary hisG46 allele.

Immunosuppressive activity of streptonigrin in vitro and in vivo.

The immune system is composed of various cells with distinct functions. Thus, highly selective immunomodulators are necessary for artificial regulation of immune reactions. We screened microbial products for such immunomodulators and we identified streptonigrin as a selective suppressor of B-cell proliferation induced by lipopolysaccharide. Streptonigrin directly suppressed the late phase of proliferation of B-cells. The inhibition of topoisomerase II was implicated as the mechanism of the B-cell-selective suppression. In cultured cell lines, however, streptonigrin preferentially suppressed the growth of an interleukin-3-dependent myeloid cell line rather than B-cell lines. In addition, the treatment with streptonigrin in vivo suppressed T-cells more significantly than B-cells and dramatically reduced the spleen weight. These results suggest that streptonigrin preferentially suppresses myeloid T-cell precursors in vivo.

Enhancement of chromosome aberrations by the combination of DNA substitution with halogenated deoxyuridine and streptonigrin treatments.

We treated CHO cells with streptonigrin (SN) alone, in combination with BrdUrd or IdUrd substitution, and with or without the addition of caffeine. The cells assessed for chromosome damage by SN were in the G2 period and the magnitude of the damage was expressed as monosubstituted chromatid breaks, bisubstituted chromatid breaks and boundary regions breaks (boundary regions indicate the point of exchange of mono- and bisubstituted chromatids). We found that the combination of BrdUrd or IdUrd substitution with SN treatments produced a remarkable increase in the frequency of breaks over the frequencies observed with the halogenated compound only. The effect was more evident with IdUrd than with BrdUrd, and more dramatic in bisubstituted than in monosubstituted chromatids. The frequency of boundary breaks in cells treated with BrdUrd plus SN was similar to the frequency of breaks in monosubstituted chromatids treated similarly. Conversely, the damage in boundary regions was almost similar to that in bisubstituted chromatids in cells challenged with IdUrd plus SN. The addition of caffeine to BrdUrd-substituted chromosomes gave rise to a marked enhancement of breakages with a gradient of chromatid damage that was: bisubstituted > monosubstituted > boundary regions. A further increase of chromatin breaks maintaining the gradient indicated above was obtained when the cells were treated with BrdUrd plus SN plus caffeine. We propose that BrdUrd and IdUrd substitution alone or in combination with caffeine treatments and with SN in its capacity to bind DNA, give rise to different chromatin structures capable of modulating the DNA damage induced along the chromatin fibril by the active oxygen species liberated by SN-DNA complexes.

The kinetics of chromosome and DNA damage by streptonigrin in CHO cells.

CHO cells were pulse-treated for 20 min with increasing doses of streptonigrin (SN). First division cells analyzed 18 h after the end of treatment showed a combination of chromosome and chromatid aberrations with a typical dose-response curve. The frequency of SCEs in second division cells (24 h harvesting time) also exhibited a positive correlation with the SN dose. A high incidence of chromatid aberrations was detected in second and third division metaphases. This indicates that SN has a persistent clastogenic action that lasts for at least three cell cycles after the end of treatment. The kinetics of DNA damage and repair was studied by the alkaline unwinding and single cell gel methods. It was found that a pulse treatment with SN elicited a triphasic response characterized by repair-damage-repair. It is proposed that SN forms stable complexes with the DNA. These complexes by a continuous cycling redox process would produce active oxygen species inducing direct damage to DNA.

Modulation of streptonigrin cytotoxicity by nitroxide SOD mimics.

Nitroxides are cell-permeable, stable radicals that react readily with paramagnetic species such as transition metals or short-lived free radicals, though not generally with diamagnetic molecules. Nitroxides can undergo one-electron selective redox reactions and thereby potentially modify the activity of cytotoxic drugs. Streptonigrin (SN) toxicity requires bioreduction to yield the semiquinone radical, and the toxicity is reportedly mediated by transition metals and oxygen-derived reactive species via redox-cycling of the semiquinone intermediate. The present study shows that (1) nitroxides protected isolated DNA and also aerated or hypoxic bacterial cells from SN toxicity; (2) H2O2 potentiated the hypoxic cytotoxicity of the drug but inhibited the damage to aerated cells; (3) pretreatment of cells with H2O2 conferred some protection, but not when the drug alone was preexposed to H2O2; and (4) desferrioxamine and 2,2-dipyridyl, though neither diethylenetriamino pentaacetate, exogenous catalase, or superoxide dismutase, decreased SN-induced cell killing. The mechanisms by which nitroxides protect from SN toxicity involve both a selective radical-radical reaction with SN semiquinone and the reoxidation of reduced cellular transition metal ions. On the other hand, H2O2 appears to exert two opposing effects: (1) facilitation of cell killing by the Fenton reaction and (2) lowering the cellular level of reducing equivalents, thus inhibiting the bioreductive activation of SN.

Physiological consequences of the S-layer of Aeromonas salmonicida in relation to growth, temperature, and outer membrane permeation.

S-layers are paracrystalline protein multimers that cover the entire cell surface of many bacterial species. The presence of an S-layer in Aeromonas salmonicida (also known as A-layer) predisposed this bacterium to apparently unrelated physiological consequences: inhibition of growth at 30 degrees C, enhanced cell filamentation at 37 degrees C, and enhanced uptake of the hydrophobic antibiotics streptonigrin and chloramphenicol. Growth inhibition or enhanced filamentation was not observed when the native A-layer was missing or its arrangement altered, as in Ca(2+)-limited or Ca(2+)- and Mg(2+)-limited cells, in A-layer-negative (A-) cells with an artificially reconstituted A-layer, or in mutants unable to correctly assemble this layer. A-layer-positive cells (A+) were far more sensitive to the intracellularly acting antibiotics streptonigrin and chloramphenicol than were A- cells, and streptonigrin-resistant mutants were predominantly A-. Hemin, a compound known to specifically bind to the A-layer, alleviated streptonigrin toxicity to A+, but not A-, cells. As well, Ca(2+)- and Mg(2+)-limited cells, or mutants harboring A-layer defects had a reduced sensitivity to streptonigrin, and A- cells with reconstituted A-layers remained resistant to streptonigrin and chloramphenicol. Thus, the presence of a native A-layer arrangement on the cell surface, and not the mere presence of A-layer protein subunits, predisposed A. salmonicida toward the aforementioned physiological consequences. The A-layer is suggested to specifically effect these consequences, in particular the permeation of streptonigrin or chloramphenicol, by a specific interaction of A-layer subunits with the outer membrane.

Relationships between thermotolerance, oxidative stress responses and induction of stress proteins in human tumour cell lines.

Thermotolerance, resistance to oxidative stress and induction of stress proteins were examined in a panel of 10 human tumour cell lines. An inverse relationship was indicated between intrinsic thermotolerance (cell survival after treatment at 43.5 degrees for 3 hr) and thermotolerance induced by pretreatment at 42.5 degrees for 30 min. Similar levels of induction of hsp 70 were found in cell lines with high or low levels of intrinsic thermotolerance; induction of other stress proteins could not be detected. Cell survival following treatment with H2O2 correlated with that following streptonigrin treatment (P < 0.05). Pretreatment with buthionine sulphoximine or diamide synergistically increased the toxicity of heat, H2O2 and streptonigrin whereas reduced glutathione had the reverse effect. No direct correlation was found, however, between tolerance to heat and to oxidative stress, and hsp 70 was not induced by the latter. The stress protein heme oxygenase, detected by immunoblotting with the monoclonal antibody HO, was induced by H2O2 in melanoma cell lines but not in HeLa. Cadmium and arsenite ions, however, readily induced heme oxygenase in HeLa, indicating that in these cells induction of heme oxygenase by oxidative stress involves a different mechanism. Overall, the results suggest that tolerance to heat or oxidative stress in these cell lines may not necessarily be associated with the induction of heat shock proteins or heme oxygenase but that cell survival after both types of stress depends to a certain extent on cellular sulphydryls.

Factors underlying variation in spontaneous and clastogen-induced sister chromatid exchanges and chromosome breakage frequencies.

The latent "factors" influencing spontaneous and clastogen-induced genetic damage, measured by rates of sister chromatid exchange (SCE) and chromosome breakage (CB), were investigated in a small sample of 20 unrelated, healthy individuals. The covariation of spontaneous and clastogen-induced (bleomycin [BLM], streptonigrin [SN], mitomycin-C [MMC], 4-nitroquinoline-1-oxide [4NQO]) SCEs and CBs was analyzed by maximum-likelihood factor analysis. A single-factor model resulted in large standardized regression coefficients of measured variables on the factor for spontaneous and BLM- and SN-induced SCE frequencies, and a modest regression coefficient for MMC-induced SCEs. A two-factor model, after varimax rotation, yielded one factor strongly associated with spontaneous and BLM- and SN-induced SCE frequencies, and a second factor associated with spontaneous and BLM- and SN-induced CBs. A bootstrap analysis of this data set indicated the statistical significance of one regression coefficient (i.e., P less than or equal to 0.05) and borderline significance (0.07 less than or equal to P less than or equal to 0.11) of three other regression coefficients on the first factor, to be interpreted as an effector of SCE frequencies. However, for the second factor, none of the bootstrapped regression coefficients was significant (P greater than 0.22). Due to the modest sample utilized in this study, the validity of this model should be further explored using additional, larger data sets.