Lethal concentration of methyl methanesulfonate in a new potential invertebrate model for ecotoxicology

Souza, Helena de Oliveira; Conceição, Moisés Basilio da; Weber, Laura Isabel

doi:10.1590/2358-2936e2018022

Abstract

Sensitivity to different concentrations (0-200 mgL^-1) of the alkylating agent methyl methanesulfonate (MMS) was evaluated in the new potential invertebrate model, the amphipod Quadrivisio lutzi (Shoemaker, 1933) after 48 h of exposure in two separate bioassays. In the first bioassay (0, 50, 100 and 200 mgL^-1 MMS), all amphipods at concentrations ≥ 50 mgL^-1 MMS were dead before completing the 48 h of exposure, which was also observed in the second bioassay for concentrations ≥ 30 mgL^-1 MMS. There was no significant effect of gender on average mortality. The median 48 h lethal concentration (LC₅₀) was 23.6 mgL^-1 MMS for Q. lutzi. Therefore, 1/3 or less of this concentration may be used for positive control in sublethal conditions. The high sensitivity of Q. lutzi to MMS is discussed in comparison to other invertebrates.

Key Words
Ecotoxicology; Amphipoda; Quadrivisio lutzi; Alkylating agent; Southeastern Brazil

INTRODUCTION

Amphipods have long been recognised as appropriate invertebrate models for ecotoxicological studies (Ingersol et al., 1998Ingersoll, C.G.; Brunsom, E.L.; Dwyer, F.J.; Hardesty, D.K. and Kemble, M.E. 1998. Use of sublethal endpoints in sediment toxicity testes with the amphipod Hyalella azteca. Environmental Toxicology and Chemistry, 17: 1508-1523.; Schulz, 2003Schulz, R. 2003. Using a freshwater amphipod in situ bioassay as a sensitive tool to detect pesticide effects in the field. Environmental Toxicology and Chemistry, 22: 1172-1176.; Anderson et al., 2004Anderson, B.; Nicely, P.; Gilbert, K.; Kosaka, R.; Hunt, J. and Phillips, B. 2004. Overview of Freshwater and Marine Toxicity Tests: A Technical Tool for Ecological Risk Assessment. California Environmental Protection Agency (Cal/EPA), Davis, University of California, 147p.; Lee et al., 2005Lee, J.S.; Lee, K.T.; Kim, D.H.; Kim, C.K.; Lee, J.H.; Park, K.H. and Park, G.S. 2005. Application of indigenous benthic amphipods as sediment toxicity testing organisms.Ocean Science Journal, 40: 17-24.; Melo and Nipper, 2007Melo, S.L.R. and Nipper, M. 2007. Sediment toxicity tests using the burrowing amphipod Tiburonella viscana (Amphipoda: Platyischnopidae). Ecotoxicology and Environmental Safety, 66: 412-420.; Hindarti et al., 2016Hindarti, D.; Sanusi, H. S.; Prartono, T.; Riani, E. and Arifin, Z. 2016. Acute toxicity of cadmium to amphipod Grandidierella bonnieroides: implications as test organism for sediment bioassay. AACL Bioflux, 9: 1182-1190.; Artal et al., 2017Artal, M.J.; Santos A.; Henry, B. and Umbuzeiro, A.G. 2017. Development of an acute toxicity test with the tropical marine amphipod Parhyale hawaiensis. Ecotoxicology, 27: 103-108.). They are among the most sensitive benthic organisms to anthropogenic disturbances such as pollution (Anderson et al., 2004Anderson, B.; Nicely, P.; Gilbert, K.; Kosaka, R.; Hunt, J. and Phillips, B. 2004. Overview of Freshwater and Marine Toxicity Tests: A Technical Tool for Ecological Risk Assessment. California Environmental Protection Agency (Cal/EPA), Davis, University of California, 147p.), including urban waste (de-la-Ossa-Carretero et al., 2012de-la-Ossa-Carretero, J.A.; Del-Pilar-Ruso, Y.; Giménez-Casalduero, F.; Sánchez-Lizaso, J.L. and Dauvin, J.C. 2012. Sensitivity of amphipods to sewage pollution. Estuarine, Coastal and Shelf Science, 96: 129-138.), metals (Borgman et al., 2005aBorgmann, U.; Couillard, Y.; Doyle, P. and Dixon, D. G. 2005a. Toxicity of sixty‐three metals and metalloids to Hyalella azteca at two levels of water hardness. Environmental Toxicology and Chemistry, 24: 641-652.; Roman et al., 2007Roman, Y.E.; De Schamphelaere, K.A.C.; Nguyen, L.T.H.; Janssen, C.R. 2007. Chronic toxicity of copper to five benthic invertebrates in laboratory-formulated sediment: Sensitivity comparison and preliminary risk assessment. Science of the Total Environment, 387: 128-140.; Pérez-Landa et al., 2008Pérez-Landa, V.; Belzunce, M.J. and Franco, J. 2008. The effect of seasonality and body size on the sensitivity of marine amphipods to toxicants. Bulletin of Environmental Contamination and Toxicology, 81: 548-552.) and pesticides (Schulz, 2003Schulz, R. 2003. Using a freshwater amphipod in situ bioassay as a sensitive tool to detect pesticide effects in the field. Environmental Toxicology and Chemistry, 22: 1172-1176.). Amphipods bioaccumulate toxic substances that are naturally associated with sediments (Wang et al., 2004Wang, F.; Goulet, R.R. and Chapman, P.M. 2004. Testing sediment biological effects with the freshwater amphipod Hyalella azteca: the gap between laboratory and nature. Chemosphere, 57: 1713-1724.; Borgman et al., 2005bBorgmann, U.; Grapentine, L; Norwood, W. P.; Bird, G.; Dixon, D. G. and Lindeman, D. 2005b. Sediment toxicity testing with the freshwater amphipod Hyalella azteca: relevance and application. Chemosphere, 61: 1740-1743.). Nonetheless, they may tolerate turbidity (Rowe et al., 2002Rowe, D.K.; Suren, A.M.; Martin, M.; Smith, J.P.; Smith B. and Williams, E. 2002. Lethal turbidity levels for common fish and invertebrates in Auckland streams. Auckland Regional Council, Technical Publication 377, 36p.) and low levels of dissolved oxygen (Landman et al., 2005Landman, M.J.; Van Den Heuvel, M.R. and Ling, N. 2005. Relative sensitivities of common freshwater fish and invertebrates to acute hypoxia. Marine and Freshwater Research, 39: 1061-1067.). Amphipods and other aquatic organisms (Grosell et al., 2007Grosell, M.; Blanchard, J.; Brix, K.V. and Gerdes, R. 2007. Physiology is pivotal for interactions between salinity and acute copper toxicity to fish and invertebrates. Aquatic Toxicology, 84: 162-172.) may show variations in their sensitivity depending on their physiological conditions (Artal et al., 2017Artal, M.J.; Santos A.; Henry, B. and Umbuzeiro, A.G. 2017. Development of an acute toxicity test with the tropical marine amphipod Parhyale hawaiensis. Ecotoxicology, 27: 103-108.), growth and reproductive stages (Pérez-Landa et al., 2008Pérez-Landa, V.; Belzunce, M.J. and Franco, J. 2008. The effect of seasonality and body size on the sensitivity of marine amphipods to toxicants. Bulletin of Environmental Contamination and Toxicology, 81: 548-552.) and degree of contact with sediments (de-la-Ossa-Carretero et al., 2012de-la-Ossa-Carretero, J.A.; Del-Pilar-Ruso, Y.; Giménez-Casalduero, F.; Sánchez-Lizaso, J.L. and Dauvin, J.C. 2012. Sensitivity of amphipods to sewage pollution. Estuarine, Coastal and Shelf Science, 96: 129-138.). The freshwater/brackish amphipod Quadrivisio lutzi (Schoemaker, 1933Shoemaker, C.R. 1933. Amphipoda from Florida and the West Indies. American Museum Novitates, 598: 1-24.) is found in coastal lagoons in the northern part of Rio de Janeiro state (Weber et al., 2013Weber, L.; Carvalho, L.; Sá, N.; Silva, V.; Beraldini, N.; Souza, V. and Conceição, M. 2013. Genotoxic effects of the water-soluble fraction of heavy oil in the brackish/fresh water amphipod Quadrivisio aff. lutzi (Gammaridea) as assessed using the comet assay. Ecotoxicology, 22: 642-655.). It inhabits the unstable environments of coastal lagoons, where it persists in part due to its high reproductive potential (Medeiros and Weber, 2016Medeiros, T.B. and Weber, L.I. 2016. Aspects of the reproductive biology of the freshwater/brackish amphipod Quadrivisio lutzi (Crustacea, Amphipoda) from an unstable coastal lagoon of southeastern Brazil. Nauplius, 24: e2016003.) and toleration to a wide range of salinities (freshwater to brackish). This amphipod have been used to study the genotoxic effects of petroleum (Weber et al., 2013Weber, L.; Carvalho, L.; Sá, N.; Silva, V.; Beraldini, N.; Souza, V. and Conceição, M. 2013. Genotoxic effects of the water-soluble fraction of heavy oil in the brackish/fresh water amphipod Quadrivisio aff. lutzi (Gammaridea) as assessed using the comet assay. Ecotoxicology, 22: 642-655.), gene expression (unpubl. data) and osmoregulatory responses (unpubl. data). The amphipod Q. lutzi has great potential as a local animal model for further studies, and efforts are being made to study its biology and to recognise its responses under controlled conditions to toxic compounds, such as methyl methanesulfonate (MMS). MMS (C2H6O3S) is an alkylating agent commonly used as a reference substance or as a positive control in genotoxic studies (Bouffant et al., 2008; Lewis and Galloway, 2008Lewis, C. and Galloway, T. 2008. Genotox damaging in Polychaetes: A study of species and cell-type sensitive. Mutation Research, 654: 69-75.; Štambuk et al., 2008; Lacaze et al., 2010; Weber et al., 2013). Ethyl methanesulfonate and MMS have been used as models to sudy responses to alkylating agents (Beranek, 1990Beranek, B.T. 1990. Distribution of methyl and ethyl adducts following alkylation with monofunctional alkylating agents. Mutation Research, 231: 11-30.). Alkylating agents may be endogenous (as a result of normal metabolisms) or exogenous, and their effects have been widely studied, either for inducing mutations and death or because of their use in human cancer treatment (Kleibl, 2002Kleibl, K. 2002. Molecular mechanisms of adaptative response to alkylating agents in Escherichia coli and some remarks on O6-methylguanine DNA-methyltransferase in other organisms. Mutation Research, 512: 67-84.).

In the environment, alkylating agents such as methyl chloride, bromomethane, iodomethane, dimethyl sulphate and diethyl sulphate may come from the chemical industry, generated by plants and fungi or through the nitrosation of natural compounds (Kleibl, 2002Kleibl, K. 2002. Molecular mechanisms of adaptative response to alkylating agents in Escherichia coli and some remarks on O6-methylguanine DNA-methyltransferase in other organisms. Mutation Research, 512: 67-84.; Štambuk et al., 2008Štambuk, A.; Pavlica, M.; Malović, L. and Klobučar, G.I.V. 2008. Persistence of DNA damage in the freshwater mussel Unio pictorum upon exposure to ethyl methanesulfonate and hydrogen peroxide. Environmental and Molecular Mutagenesis, 49: 217-225.). Alkylating agents react with ring nitrogen (N) and extracyclic oxygen (O) atoms of DNA bases to generate a variety of covalent adducts ranging from simple methyl groups to complex alkyl additions (Fu et al., 2012Fu, D.; Calvo, J.A. and Samson, L.D. 2012. Balancing repair and tolerance of DNA damage caused by alkylating agents. Nature Reviews Cancer, 12: 104-120.). MMS belongs to the monofunctional compound of the SN2 mechanism, inducing mainly the formation of N7-methyl-guanine (N ⁷-meG) and N3-methyl-adenine (N ³-meA; Beranek, 1990Beranek, B.T. 1990. Distribution of methyl and ethyl adducts following alkylation with monofunctional alkylating agents. Mutation Research, 231: 11-30.).

Agents inducing predominantly N-methylations (SN2 agents), such as MMS and DMS (dimethyl sulphates), exhibit a high clastogenic effect but low point mutagenic potency (Kaina, 2004Kaina, B. 2004. Mechanisms and consequences of methylating agent-induced SCEs and chromosomal aberrations: a long Road traveled still a far way to go. Cytogenetic and Genome Research, 104: 77-86.). Therefore, our aim was to evaluate the susceptibility of the amphipod Q. lutzi to MMS and to establish it as a positive control for bioassays for organisms at this level.

MATERIAL AND METHODS

Amphipods of Q. lutzi (Fig. 1A) were found in the roots of aquatic macrophytes. Aquatic macrophytes with amphipods were transferred to the laboratory in plastic boxes filled with lagoon water, and then the amphipods were removed using plastic pipettes and transferred to flasks with filtered and Ultraviolet-sterilized lagoon water. Amphipods were obtained on 11 March and 8 April 2014 from Paulista Lagoon (22°13'52.6″S 41°32'14.2″W), Quissamã, in the north of Rio de Janeiro state, Brazil. Water parameters were measured with a multiparameter YSI-556 to determine salinity (0.6), dissolved oxygen (6.04 mgL^-1), conductivity (2.67 µS) and pH (8.4). Adult amphipods were separated by sex; males were identified by the size of the second pair of gnathopods and females by the brood pouch. Juveniles and ovigerous females were not used. Amphipods were transferred, in groups, to 125 mL finger bowls containing sterilized, filtered lagoon at 27 ± 0.5°C, changed daily during the 96 h acclimatisation period with 12/12 h (day/night) photoperiod. They were fed with 0.07 g vegetable sticks from dried macrophytes obtained from the lagoon and with a commercial food supplement (Neon, MEP 200 complex, Alcon) added daily (1.24 mg/amphipod). A total of 400 amphipods were used for the bioassays. Exposure to all concentrations was performed in two replicates per gender, with 10 amphipods per replicate. Mortality was registered after 48 h. First, a broad range of MMS concentrations was tested: 0 (negative control), 50, 100 and 200 mgL^-1. After that, a narrow range of MMS concentrations (0, 2.5, 5, 10, 20 and 30 mgL^-1) was tested to determine the median lethal concentration (LC50). Average mortality was obtained for each concentration and gender.

Figure 1
(A) The amphipod Quadrivisio lutzi (Schoemaker, 1933); (B) Average mortality of male and female amphipods Q. lutzi after 48 h of exposure to different MMS concentrations; (C) Regression lines that associate male and female average mortality with MMS concentrations; (D) Regression line that associates PROBIT values with MMS concentrations and extrapolation of the median lethal concentration for Q. lutzi from PROBIT 5 to MMS concentration.

The effect of gender and all MMS concentrations on average mortality was evaluated by a factorial ANOVA. Mean comparisons were assessed using Tukey's test at 5% significance. Pearson linear regression was used to evaluate the association between average mortality and MMS concentration for males and females. The Univariate test of significance to compare slopes between gender regression lines was used. Median LC50 was determined by the PROBIT function, where mortality values of genders and replicates at different MMS concentrations were transformed to PROBIT values. The statistical package STATISTICA, v. 7 (Statsoft Inc.) was used for all analyses.

RESULTS AND DISCUSSION

All of the amphipods (males and females) exposed to ≥ 30 mgL^-1 of MMS were found dead within 48 h of exposure (Fig. 1B). No effect of gender was observed after factorial ANOVA (F(1,22) = 3.60, p = 0.071), but, as was expected, a significant effect of MMS concentrations on mortality was observed (F(8,22) = 210.37, p < 0.001). No effect of interaction gender-MMS concentration was observed (F(8,22) = 2.28, p = 0.060). When evaluated by a non-protected Tukey's test of mean comparisons at each MMS concentration, was discovered that males showed significantly higher average mortality than females (p = 0.031) but only at a concentration of 20 mgL^-1 of MMS (Fig. 1B; Tab. 1). At this concentration, males also differed significantly from the control (Tab. 1). Nonetheless, no significant differences were found between the controls and test groups at concentrations ≤ 20 mgL^-1 of MMS after Tukey's test when comparisons were done for each concentration and for all amphipods (Tab. 1), nor when effects were evaluated for all treatments ≤ 20 mgL^-1 of MMS together against controls (Treatment: F(1,17) = 0.226, p = 0.640; Gender: F(1,17) = 2.316, p = 0.146).

Thumbnail

Table 1
Results of Tukey's test of pair-wise mean comparisons between MMS-treated and control units, with the immediately anterior lower MMS concentration and between genders at each concentration (non-protected test).

Weber et al. (2013Weber, L.; Carvalho, L.; Sá, N.; Silva, V.; Beraldini, N.; Souza, V. and Conceição, M. 2013. Genotoxic effects of the water-soluble fraction of heavy oil in the brackish/fresh water amphipod Quadrivisio aff. lutzi (Gammaridea) as assessed using the comet assay. Ecotoxicology, 22: 642-655.) found slight but significant differences in genotoxic response between genders (males were more sensitive) at the sublethal concentration of 10 mgL^-1 of MMS. However, in the same article, females were found to be more sensitive than males to petroleum water-soluble fractions. Sornom et al. (2010Sornom, P.; Felten, V.; Médoc, V.; Sroda, S.; Rousselle, P. and Beisel, J-N. 2010. Effect of gender on physiological and behavioural responses of Gammarus roeseli (Crustacea, Amphipoda) to salinity and temperature. Environmental Pollution, 158: 1288-1295.) found that females of Gammarus roeselii (Gervais, 1835) were more sensitive than males to temperature and salinity stress. In the present study, where no significant effect of gender was observed, but at 20 mgL^-1 of MMS males showed significantly higher mortality compared to females, we cannot rule out that high variation in males mortality could be related to their aggressive behaviour rather than the effect of MMS.

The results of the Pearson linear regressions to determine an association between average mortality of males and females and MMS concentrations are shown in Fig. 1C. A significant correlation was found between male and female average mortality and MMS concentrations (females: F(1,10) = 14.968, p = 0.003, R = 0.774, R² = 0.599, y = 12.954 + 2.707 x; males: F(1,10) = 38.006, p < 0.001, R = 0.890, R² = 0.792, y = 10.472 + 3.079 x). The univariate test of significance was used to compare the slopes of male and female regressions to evaluate the effect of gender on average mortality and indicated that there was no effect of gender on slopes (F(1,20) = 0.0349; p = 0.854). The overall linear regression and the correlation that associates average mortality with MMS concentrations in Q. lutzi was significant (F(1,22) = 48.090; p < 0.001; R = 0.828; R² = 0.686; y = −11.7132 + 2.893 x). The PROBIT values that represent male and female mortalities showed a significant correlation with MMS concentration (F(1,22) = 48.090; p < 0.001; R = 0.777; R² = 0.603; y = − 0.3608 + 0.2272 x; Fig. 1D). The extrapolation of PROBIT five over MMS concentration using this regression gave a median lethal mortality for the amphipod Q. lutzi of 23.6 mgL^-1 of MMS after 48 h of exposure (48 h LC50 = 23.6 mg L^-1 of MMS; Fig. 1D).

The concentration of 10 mgL^-1 of MMS, in which mortality was not observed, was close to the value of 11 mgL^-1 (0.1 mM) of MMS, at which Lacaze et al. (2010Lacaze, E.; Geffard, O.; Bony, S. and Devaux, A. 2010. Genotoxicity assessment in the amphipod Gammarus fossarum by use of the alkaline Comet assay. Mutation Research/Genetic Toxicology and Environmental Mutagenesis, 700: 32-38.) found 9.5 times more DNA damage than controls in haemocytes of Gammarus fossarum (Koch, 1836) after five days of exposure. Similarly, Weber et al. (2013Weber, L.; Carvalho, L.; Sá, N.; Silva, V.; Beraldini, N.; Souza, V. and Conceição, M. 2013. Genotoxic effects of the water-soluble fraction of heavy oil in the brackish/fresh water amphipod Quadrivisio aff. lutzi (Gammaridea) as assessed using the comet assay. Ecotoxicology, 22: 642-655.) found 2.5 times more DNA damage for Q. lutzi when treated with 10 mgL^-1 MMS compared to the controls after two days of exposure.

At much higher concentrations of MMS (≥ 1,000 mgL^-1) than those used in our study (2.5 - 200 mgL^-1), severe damage has been found in the first stages of development of other invertebrates. Su (2010Su, T.T. 2010. The effect of a DNA damaging agent on embryonic cell cycles of the cnidarian Hydractinia echinata. PLoS ONE, 5: 11760.) found that 9.1 mM (1,002.2 mgL^-1) of MMS slowed cleavage divisions by about 50% in embryos of the cnidarian Hydractinia echinata (Fleming, 1828); Bouffant et al. (2008Bouffant, R.; Boulben, S.; Cormier, P.; Mulner-Lorillon, O.; Bellé, R. and Morales, J. 2008. Inhibition of translation and modification of translation factors during apoptosis induced by the DNA-damaging agent MMS in sea urchin embryos. Experimental Cell Research, 314: 961-968.) found that 10.0 mM (1,101.3 mgL^-1) of MMS completely inhibited the protein synthesis activity in early embryos of the sea urchin Sphaerechinus granularis (Lamarck, 1816). The high mortality of Q. lutzi at 30 mgL^-1 (0.27 mM) of MMS observed in this study along with the high degree of DNA damage of Q. lutzi (Weber et al., 2013Weber, L.; Carvalho, L.; Sá, N.; Silva, V.; Beraldini, N.; Souza, V. and Conceição, M. 2013. Genotoxic effects of the water-soluble fraction of heavy oil in the brackish/fresh water amphipod Quadrivisio aff. lutzi (Gammaridea) as assessed using the comet assay. Ecotoxicology, 22: 642-655.) and G. fossarum (Lacaze et al., 2010Lacaze, E.; Geffard, O.; Bony, S. and Devaux, A. 2010. Genotoxicity assessment in the amphipod Gammarus fossarum by use of the alkaline Comet assay. Mutation Research/Genetic Toxicology and Environmental Mutagenesis, 700: 32-38.) at lower concentrations (10 - 11 mgL^-1 of MMS) indicates a higher sensitivity of amphipods to MMS when compared with other invertebrate species, such as the aforementioned echinodermata and cnidaria species. Furthermore, the short range from sublethal to lethal concentrations of MMS (10 - 30 mgL^-1) in Q. lutzi may be explained by the drastic effects on protein synthesis and cell proliferation already observed in other invertebrates (Bouffant et al., 2008Bouffant, R.; Boulben, S.; Cormier, P.; Mulner-Lorillon, O.; Bellé, R. and Morales, J. 2008. Inhibition of translation and modification of translation factors during apoptosis induced by the DNA-damaging agent MMS in sea urchin embryos. Experimental Cell Research, 314: 961-968.; Su et al., 2010Su, T.T. 2010. The effect of a DNA damaging agent on embryonic cell cycles of the cnidarian Hydractinia echinata. PLoS ONE, 5: 11760.).

The most frequent adduct on double-stranded DNA induced by MMS, N ⁷-meG, is considered relatively harmless because it does not block transcription and replication, but the adduct N ³-meA has caused death in bacteria and in mammals after generating formamidopyrimidine, which blocks DNA synthesis (Kleibl, 2002Kleibl, K. 2002. Molecular mechanisms of adaptative response to alkylating agents in Escherichia coli and some remarks on O6-methylguanine DNA-methyltransferase in other organisms. Mutation Research, 512: 67-84.). The less-frequent adduct O ⁶-meG is the most dangerous, but MMS induces it in a lower proportion than the endogenous N-methyl-N-nitrosourea. DNA repair of the adduct O ⁶-meG mediated by base excision repair, present in all organisms, causes death by an uncertain mechanism; however, if repair does not occur, it leads to the point mutation A:T (Kleibl, 2002Kleibl, K. 2002. Molecular mechanisms of adaptative response to alkylating agents in Escherichia coli and some remarks on O6-methylguanine DNA-methyltransferase in other organisms. Mutation Research, 512: 67-84.). The clastogenic effects of MMS may determine severe nuclear damage on haemocytes, which may lead cells to apoptosis. Formation and development of mature haemocytes in crustaceans involves proliferation and differentiation from undifferentiated haematopoietic cells, which are continuously and proportionally produced throughout the animal’s lifetime (Lin and Sӧderhӓll, 2011Lin, X. and SӧderhӓlL, I. 2011. Crustaceans hematopoietic and the astakine cytokines. Blood, 117: 6417-6424.). The protein Astakine 1 (Ast1), found in crustaceans, is responsible for inducing the proliferation of undifferentiated haemocytes, which, under haematopenia, stimulates the rapid production and release of new cells from the haematopoietic tissue (Lin and Sӧderhӓll, 2011Lin, X. and SӧderhӓlL, I. 2011. Crustaceans hematopoietic and the astakine cytokines. Blood, 117: 6417-6424.). The time taken to produce new cells, which represents the recovery time, is after 24-48 h, as observed in crayfish after microbial infection (Sӧderhӓll et al., 2003Sӧderhӓll, I.; Bangyeekhun, E.; Mayo, S. and Sӧderhӓll, K. 2003. Hemocyte production and maturation in an invertebrate animal; proliferation and gene expression in hematopoietic stem cells of Pacifastacus leniusculus. Development and Comparative Immunology, 27: 661-672.). In the amphipod Q. lutzi, it is expected that new cells are already in the circulatory systems after 24 h of chemical damage based on the recovery of haemocytes after petroleum exposure (Weber et al., 2013Weber, L.; Carvalho, L.; Sá, N.; Silva, V.; Beraldini, N.; Souza, V. and Conceição, M. 2013. Genotoxic effects of the water-soluble fraction of heavy oil in the brackish/fresh water amphipod Quadrivisio aff. lutzi (Gammaridea) as assessed using the comet assay. Ecotoxicology, 22: 642-655.). In Saccharomyces cerevisiae, after MMS exposure, it was found that nuclear proteins associated with DNA repair, cell-cycle checkpoints and transcriptions were over-represented, suggesting events of DNA repair, apoptosis and induction of cell proliferation (Begley et al., 2004Begley, T.L.; Rosenbach, A.S.; Ideker, T. and Samson, L.D. 2004. Hotspot for modulation toxicity identified by genomic phenotyping and localization mapping. Molecular Cell, 16: 117-125.). Nonetheless, in the few invertebrates that have been studied, the arrest of protein synthesis activity after exposure to MMS (Bouffant et al., 2008Bouffant, R.; Boulben, S.; Cormier, P.; Mulner-Lorillon, O.; Bellé, R. and Morales, J. 2008. Inhibition of translation and modification of translation factors during apoptosis induced by the DNA-damaging agent MMS in sea urchin embryos. Experimental Cell Research, 314: 961-968.) may also interrupt the synthesis of Ast1, which may accelerate death in amphipods.

We conclude that the amphipod Q. lutzi is highly sensitive to MMS. Therefore, MMS at concentrations of 1/3 of the 48 h LC50 (23.6 mgL^-1) may be used for positive control of bioassays with potentially genotoxic substances. To better understand the effects of MMS in amphipods, further studies are needed at the molecular and cytological levels.

ACKNOWLEDGEMENTS

Financial support by Conselho Nacional de Desenvolvimento Científico e Tecnológico, CNPq, (PELD 2012-2015, 403841/2012-7) and M.Sc. (PPGCIAC-UFRJ) grant to H.O.S. from Fundação de Amparo à Pesquisa do Estado do Rio de Janeiro (FAPERJ). This research was conducted in accordance with ICMBio Licenses 25689 and 26145. We are also very grateful to anonymous reviewers that allowed to improve significantly the present manuscript.

REFERENCES

Anderson, B.; Nicely, P.; Gilbert, K.; Kosaka, R.; Hunt, J. and Phillips, B. 2004. Overview of Freshwater and Marine Toxicity Tests: A Technical Tool for Ecological Risk Assessment. California Environmental Protection Agency (Cal/EPA), Davis, University of California, 147p.
Artal, M.J.; Santos A.; Henry, B. and Umbuzeiro, A.G. 2017. Development of an acute toxicity test with the tropical marine amphipod Parhyale hawaiensis Ecotoxicology, 27: 103-108.
Begley, T.L.; Rosenbach, A.S.; Ideker, T. and Samson, L.D. 2004. Hotspot for modulation toxicity identified by genomic phenotyping and localization mapping. Molecular Cell, 16: 117-125.
Beranek, B.T. 1990. Distribution of methyl and ethyl adducts following alkylation with monofunctional alkylating agents. Mutation Research, 231: 11-30.
Borgmann, U.; Couillard, Y.; Doyle, P. and Dixon, D. G. 2005a. Toxicity of sixty‐three metals and metalloids to Hyalella azteca at two levels of water hardness. Environmental Toxicology and Chemistry, 24: 641-652.
Borgmann, U.; Grapentine, L; Norwood, W. P.; Bird, G.; Dixon, D. G. and Lindeman, D. 2005b. Sediment toxicity testing with the freshwater amphipod Hyalella azteca: relevance and application. Chemosphere, 61: 1740-1743.
Bouffant, R.; Boulben, S.; Cormier, P.; Mulner-Lorillon, O.; Bellé, R. and Morales, J. 2008. Inhibition of translation and modification of translation factors during apoptosis induced by the DNA-damaging agent MMS in sea urchin embryos. Experimental Cell Research, 314: 961-968.
de-la-Ossa-Carretero, J.A.; Del-Pilar-Ruso, Y.; Giménez-Casalduero, F.; Sánchez-Lizaso, J.L. and Dauvin, J.C. 2012. Sensitivity of amphipods to sewage pollution. Estuarine, Coastal and Shelf Science, 96: 129-138.
Fu, D.; Calvo, J.A. and Samson, L.D. 2012. Balancing repair and tolerance of DNA damage caused by alkylating agents. Nature Reviews Cancer, 12: 104-120.
Grosell, M.; Blanchard, J.; Brix, K.V. and Gerdes, R. 2007. Physiology is pivotal for interactions between salinity and acute copper toxicity to fish and invertebrates. Aquatic Toxicology, 84: 162-172.
Hindarti, D.; Sanusi, H. S.; Prartono, T.; Riani, E. and Arifin, Z. 2016. Acute toxicity of cadmium to amphipod Grandidierella bonnieroides: implications as test organism for sediment bioassay. AACL Bioflux, 9: 1182-1190.
Ingersoll, C.G.; Brunsom, E.L.; Dwyer, F.J.; Hardesty, D.K. and Kemble, M.E. 1998. Use of sublethal endpoints in sediment toxicity testes with the amphipod Hyalella azteca Environmental Toxicology and Chemistry, 17: 1508-1523.
Kaina, B. 2004. Mechanisms and consequences of methylating agent-induced SCEs and chromosomal aberrations: a long Road traveled still a far way to go. Cytogenetic and Genome Research, 104: 77-86.
Kleibl, K. 2002. Molecular mechanisms of adaptative response to alkylating agents in Escherichia coli and some remarks on O⁶-methylguanine DNA-methyltransferase in other organisms. Mutation Research, 512: 67-84.
Lacaze, E.; Geffard, O.; Bony, S. and Devaux, A. 2010. Genotoxicity assessment in the amphipod Gammarus fossarum by use of the alkaline Comet assay. Mutation Research/Genetic Toxicology and Environmental Mutagenesis, 700: 32-38.
Landman, M.J.; Van Den Heuvel, M.R. and Ling, N. 2005. Relative sensitivities of common freshwater fish and invertebrates to acute hypoxia. Marine and Freshwater Research, 39: 1061-1067.
Lee, J.S.; Lee, K.T.; Kim, D.H.; Kim, C.K.; Lee, J.H.; Park, K.H. and Park, G.S. 2005. Application of indigenous benthic amphipods as sediment toxicity testing organisms.Ocean Science Journal, 40: 17-24.
Lewis, C. and Galloway, T. 2008. Genotox damaging in Polychaetes: A study of species and cell-type sensitive. Mutation Research, 654: 69-75.
Lin, X. and SӧderhӓlL, I. 2011. Crustaceans hematopoietic and the astakine cytokines. Blood, 117: 6417-6424.
Medeiros, T.B. and Weber, L.I. 2016. Aspects of the reproductive biology of the freshwater/brackish amphipod Quadrivisio lutzi (Crustacea, Amphipoda) from an unstable coastal lagoon of southeastern Brazil. Nauplius, 24: e2016003.
Melo, S.L.R. and Nipper, M. 2007. Sediment toxicity tests using the burrowing amphipod Tiburonella viscana (Amphipoda: Platyischnopidae). Ecotoxicology and Environmental Safety, 66: 412-420.
Pérez-Landa, V.; Belzunce, M.J. and Franco, J. 2008. The effect of seasonality and body size on the sensitivity of marine amphipods to toxicants. Bulletin of Environmental Contamination and Toxicology, 81: 548-552.
Roman, Y.E.; De Schamphelaere, K.A.C.; Nguyen, L.T.H.; Janssen, C.R. 2007. Chronic toxicity of copper to five benthic invertebrates in laboratory-formulated sediment: Sensitivity comparison and preliminary risk assessment. Science of the Total Environment, 387: 128-140.
Rowe, D.K.; Suren, A.M.; Martin, M.; Smith, J.P.; Smith B. and Williams, E. 2002. Lethal turbidity levels for common fish and invertebrates in Auckland streams. Auckland Regional Council, Technical Publication 377, 36p.
Schulz, R. 2003. Using a freshwater amphipod in situ bioassay as a sensitive tool to detect pesticide effects in the field. Environmental Toxicology and Chemistry, 22: 1172-1176.
Shoemaker, C.R. 1933. Amphipoda from Florida and the West Indies. American Museum Novitates, 598: 1-24.
Sӧderhӓll, I.; Bangyeekhun, E.; Mayo, S. and Sӧderhӓll, K. 2003. Hemocyte production and maturation in an invertebrate animal; proliferation and gene expression in hematopoietic stem cells of Pacifastacus leniusculus Development and Comparative Immunology, 27: 661-672.
Sornom, P.; Felten, V.; Médoc, V.; Sroda, S.; Rousselle, P. and Beisel, J-N. 2010. Effect of gender on physiological and behavioural responses of Gammarus roeseli (Crustacea, Amphipoda) to salinity and temperature. Environmental Pollution, 158: 1288-1295.
Štambuk, A.; Pavlica, M.; Malović, L. and Klobučar, G.I.V. 2008. Persistence of DNA damage in the freshwater mussel Unio pictorum upon exposure to ethyl methanesulfonate and hydrogen peroxide. Environmental and Molecular Mutagenesis, 49: 217-225.
Su, T.T. 2010. The effect of a DNA damaging agent on embryonic cell cycles of the cnidarian Hydractinia echinata PLoS ONE, 5: 11760.
Wang, F.; Goulet, R.R. and Chapman, P.M. 2004. Testing sediment biological effects with the freshwater amphipod Hyalella azteca: the gap between laboratory and nature. Chemosphere, 57: 1713-1724.
Weber, L.; Carvalho, L.; Sá, N.; Silva, V.; Beraldini, N.; Souza, V. and Conceição, M. 2013. Genotoxic effects of the water-soluble fraction of heavy oil in the brackish/fresh water amphipod Quadrivisio aff. lutzi (Gammaridea) as assessed using the comet assay. Ecotoxicology, 22: 642-655.

Zoobank:

http://zoobank.org/urn:lsid:zoobank.org:pub:E1E5E38E-8318-439D-9317-D8EE2650E92B

Publication Dates

Publication in this collection
01 Nov 2018
Date of issue
2018

History

Received
11 Apr 2018
Accepted
17 Sept 2018

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Anderson, B.; Nicely, P.; Gilbert, K.; Kosaka, R.; Hunt, J. and Phillips, B. 2004. Overview of Freshwater and Marine Toxicity Tests: A Technical Tool for Ecological Risk Assessment. California Environmental Protection Agency (Cal/EPA), Davis, University of California, 147p.

[2] Artal, M.J.; Santos A.; Henry, B. and Umbuzeiro, A.G. 2017. Development of an acute toxicity test with the tropical marine amphipod Parhyale hawaiensis Ecotoxicology, 27: 103-108.

[3] Begley, T.L.; Rosenbach, A.S.; Ideker, T. and Samson, L.D. 2004. Hotspot for modulation toxicity identified by genomic phenotyping and localization mapping. Molecular Cell, 16: 117-125.

[4] Beranek, B.T. 1990. Distribution of methyl and ethyl adducts following alkylation with monofunctional alkylating agents. Mutation Research, 231: 11-30.

[5] Borgmann, U.; Couillard, Y.; Doyle, P. and Dixon, D. G. 2005a. Toxicity of sixty‐three metals and metalloids to Hyalella azteca at two levels of water hardness. Environmental Toxicology and Chemistry, 24: 641-652.

[6] Borgmann, U.; Grapentine, L; Norwood, W. P.; Bird, G.; Dixon, D. G. and Lindeman, D. 2005b. Sediment toxicity testing with the freshwater amphipod Hyalella azteca: relevance and application. Chemosphere, 61: 1740-1743.

[7] Bouffant, R.; Boulben, S.; Cormier, P.; Mulner-Lorillon, O.; Bellé, R. and Morales, J. 2008. Inhibition of translation and modification of translation factors during apoptosis induced by the DNA-damaging agent MMS in sea urchin embryos. Experimental Cell Research, 314: 961-968.

[8] de-la-Ossa-Carretero, J.A.; Del-Pilar-Ruso, Y.; Giménez-Casalduero, F.; Sánchez-Lizaso, J.L. and Dauvin, J.C. 2012. Sensitivity of amphipods to sewage pollution. Estuarine, Coastal and Shelf Science, 96: 129-138.

[9] Fu, D.; Calvo, J.A. and Samson, L.D. 2012. Balancing repair and tolerance of DNA damage caused by alkylating agents. Nature Reviews Cancer, 12: 104-120.

[10] Grosell, M.; Blanchard, J.; Brix, K.V. and Gerdes, R. 2007. Physiology is pivotal for interactions between salinity and acute copper toxicity to fish and invertebrates. Aquatic Toxicology, 84: 162-172.

[11] Hindarti, D.; Sanusi, H. S.; Prartono, T.; Riani, E. and Arifin, Z. 2016. Acute toxicity of cadmium to amphipod Grandidierella bonnieroides: implications as test organism for sediment bioassay. AACL Bioflux, 9: 1182-1190.

[12] Ingersoll, C.G.; Brunsom, E.L.; Dwyer, F.J.; Hardesty, D.K. and Kemble, M.E. 1998. Use of sublethal endpoints in sediment toxicity testes with the amphipod Hyalella azteca Environmental Toxicology and Chemistry, 17: 1508-1523.

[13] Kaina, B. 2004. Mechanisms and consequences of methylating agent-induced SCEs and chromosomal aberrations: a long Road traveled still a far way to go. Cytogenetic and Genome Research, 104: 77-86.

[14] Kleibl, K. 2002. Molecular mechanisms of adaptative response to alkylating agents in Escherichia coli and some remarks on O⁶-methylguanine DNA-methyltransferase in other organisms. Mutation Research, 512: 67-84.

[15] Lacaze, E.; Geffard, O.; Bony, S. and Devaux, A. 2010. Genotoxicity assessment in the amphipod Gammarus fossarum by use of the alkaline Comet assay. Mutation Research/Genetic Toxicology and Environmental Mutagenesis, 700: 32-38.

[16] Landman, M.J.; Van Den Heuvel, M.R. and Ling, N. 2005. Relative sensitivities of common freshwater fish and invertebrates to acute hypoxia. Marine and Freshwater Research, 39: 1061-1067.

[17] Lee, J.S.; Lee, K.T.; Kim, D.H.; Kim, C.K.; Lee, J.H.; Park, K.H. and Park, G.S. 2005. Application of indigenous benthic amphipods as sediment toxicity testing organisms.Ocean Science Journal, 40: 17-24.

[18] Lewis, C. and Galloway, T. 2008. Genotox damaging in Polychaetes: A study of species and cell-type sensitive. Mutation Research, 654: 69-75.

[19] Lin, X. and SӧderhӓlL, I. 2011. Crustaceans hematopoietic and the astakine cytokines. Blood, 117: 6417-6424.

[20] Medeiros, T.B. and Weber, L.I. 2016. Aspects of the reproductive biology of the freshwater/brackish amphipod Quadrivisio lutzi (Crustacea, Amphipoda) from an unstable coastal lagoon of southeastern Brazil. Nauplius, 24: e2016003.

[21] Melo, S.L.R. and Nipper, M. 2007. Sediment toxicity tests using the burrowing amphipod Tiburonella viscana (Amphipoda: Platyischnopidae). Ecotoxicology and Environmental Safety, 66: 412-420.

[22] Pérez-Landa, V.; Belzunce, M.J. and Franco, J. 2008. The effect of seasonality and body size on the sensitivity of marine amphipods to toxicants. Bulletin of Environmental Contamination and Toxicology, 81: 548-552.

[23] Roman, Y.E.; De Schamphelaere, K.A.C.; Nguyen, L.T.H.; Janssen, C.R. 2007. Chronic toxicity of copper to five benthic invertebrates in laboratory-formulated sediment: Sensitivity comparison and preliminary risk assessment. Science of the Total Environment, 387: 128-140.

[24] Rowe, D.K.; Suren, A.M.; Martin, M.; Smith, J.P.; Smith B. and Williams, E. 2002. Lethal turbidity levels for common fish and invertebrates in Auckland streams. Auckland Regional Council, Technical Publication 377, 36p.

[25] Schulz, R. 2003. Using a freshwater amphipod in situ bioassay as a sensitive tool to detect pesticide effects in the field. Environmental Toxicology and Chemistry, 22: 1172-1176.

[26] Shoemaker, C.R. 1933. Amphipoda from Florida and the West Indies. American Museum Novitates, 598: 1-24.

[27] Sӧderhӓll, I.; Bangyeekhun, E.; Mayo, S. and Sӧderhӓll, K. 2003. Hemocyte production and maturation in an invertebrate animal; proliferation and gene expression in hematopoietic stem cells of Pacifastacus leniusculus Development and Comparative Immunology, 27: 661-672.

[28] Sornom, P.; Felten, V.; Médoc, V.; Sroda, S.; Rousselle, P. and Beisel, J-N. 2010. Effect of gender on physiological and behavioural responses of Gammarus roeseli (Crustacea, Amphipoda) to salinity and temperature. Environmental Pollution, 158: 1288-1295.

[29] Štambuk, A.; Pavlica, M.; Malović, L. and Klobučar, G.I.V. 2008. Persistence of DNA damage in the freshwater mussel Unio pictorum upon exposure to ethyl methanesulfonate and hydrogen peroxide. Environmental and Molecular Mutagenesis, 49: 217-225.

[30] Su, T.T. 2010. The effect of a DNA damaging agent on embryonic cell cycles of the cnidarian Hydractinia echinata PLoS ONE, 5: 11760.

[31] Wang, F.; Goulet, R.R. and Chapman, P.M. 2004. Testing sediment biological effects with the freshwater amphipod Hyalella azteca: the gap between laboratory and nature. Chemosphere, 57: 1713-1724.

[32] Weber, L.; Carvalho, L.; Sá, N.; Silva, V.; Beraldini, N.; Souza, V. and Conceição, M. 2013. Genotoxic effects of the water-soluble fraction of heavy oil in the brackish/fresh water amphipod Quadrivisio aff. lutzi (Gammaridea) as assessed using the comet assay. Ecotoxicology, 22: 642-655.

Treatment (mgL^-1)	Overall (n = 4)		p values after Tukey test
	Overall (n = 4)		With lower	With Control			Males &Females
	Mean	SD	With lower	Males	Females	All	(n = 8)
0	2.5	4.6					0.999
2.5	0.0	0.0	0.999	1.000	0.999	0.999	1.000
5	5.0	10.0	0.994	0.991	0.999	0.999	0.991
10	2.5	5.0	0.499	0.999	0.999	1.000	0.999
20	15.0	23.8	0.499	0.008	0.999	0.314	0.031
30	100.0	0.0	< 0.001	< 0.001	< 0.001	< 0.001	1.000
50	100.0	0.0	1.000	< 0.001	< 0.001	< 0.001	1.000
100	100.0	0.0	1.000	< 0.001	< 0.001	< 0.001	1.000
200	100.0	0.0	1.000	< 0.001	< 0.001	< 0.001	1.000

Brasil