Abstract
The effect of previous toxicant exposure (i.e., exposure history) on an organism’s response to re-exposure to the toxicant is of considerable interest. The marine mussel Mytilus edulis was collected from reference and polluted sites in southwest England, and groups of mussels from each site were exposed to 20 μg/L CdCl2 for 0, 1, 4, and 8 days and compared with unexposed controls. End points evaluated were tissue metal and electrolyte concentrations, haemolymph chemistry, haemocyte characteristics [counts, neutral red uptake (NRU), and phagocytosis], histology, and expression of metallothionein gene (mt10) expression in digestive glands. Field-collected animals differed by collection site for some end points at time zero, at which time tissue Fe and Pb concentrations were greater and NRU and condition index lower in mussels from the polluted site. Subsequent exposure to cadmium (Cd) in the laboratory caused Cd accumulation mainly in digestive gland, but there were no site-specific effects on tissue trace-metal concentrations. NRU, phagocytosis, and haemolymph Na+ and K+ concentrations differed among sites and Cd treatment, but there were no clear trends. Exposure to Cd resulted in lower Ca2+ concentrations in gill, digestive gland, and haemolymph in animals from the polluted site compared with controls (Kruskal–Wallis, p ≤ 0.05). Lesions, including necrosis, inflammation, and neoplasia, were observed in animals from the polluted site, but the frequency of these lesions appeared to decrease unexpectedly after Cd exposure. Expression of mt10 increased 3-fold in Cd-exposed animals from the polluted site compared with all other groups (Kruskal–Wallis, p = 0.01). We conclude that Cd exposure affected some immune responses in M. edulis, but pre-exposure history influenced toxicological outcomes of Cd exposure in the laboratory.
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References
Aguirre MJ (1979) Biologia del mejillon (Mytilus edulis) de cultivo de la Ria Vigo. Biol Inst Espnol de Oceanogr 5:107–160
Au DWT (2004) The application of histo-cytopathological biomarkers in marine pollution monitoring: a review. Mar Pollut Bull 48:817–834
Auffret M (1988) Histopathological changes related to chemical contamination in Mytilus edulis from field and experimental conditions. Mar Ecol Prog Ser 46:101–107
Babich H, Borenfreund E (1992) Neutral red assay for toxicology in vitro. In: Watson RR (ed) In vitro methods of toxicology. CRC Press, Boca Raton, pp 237–251
Barber BJ (1996) Effects of gonadal neoplasms on oogenesis in softshell clams, Mya arenaria. J Invertebr Pathol 67:161–168
Baršyté D, White KN, Lovejoy DA (1999) Cloning and characterization of metallothionein cDNAs in the mussel Mytilus edulis L. digestive gland. Comp Biochem Physiol C 122:287–296
Blackmore G, Wang W (2002) Uptake and efflux of Cd and Zn by the green mussel Perna viridis after metal preexposure. Environ Sci Technol 36:989–995
Booth AM, Scarlett AG, Lewis CA, Belt ST, Rowland SJ (2008) Unresolved complex mixtures (UCMs) of aromatic hydrocarbons: branched alkyl indanes and branched alkyl tetralins are present in UCMs and accumulated by and toxic to, the mussel Mytilus edulis. Environ Sci Technol 42:8122–8126
Brousseau P, Pellerin J, Morin Y, Cyi D, Blakley B, Boermens H et al (1999) Flow cytometry as a tool to monitor the disturbance of phagocytosis in the clam Mya arenaria hemocytes following in vitro exposure to heavy metals. Toxicology 3:145–156
Bryan GW, Gibbs PE, Hummerstone LG, Burt GR (1986) The decline of the gastropod Nucella lapillus around south-west England: evidence for the effect of tributyltin from antifouling paints. J Mar Biol Assoc UK 66:611–640
Cairns JJ, Heath AG, Parker BC (1975) The effects of temperature upon the toxicity of chemicals to aquatic organisms. Hydrobiologia 47:135–171
Coles JA, Farley SR, Pipe RK (1995) Alteration of the immune response of the common marine mussel M. edulis resulting from exposure to cadmium. Dis Aquat Organ 22:59–65
Da Ros L, Nasci C, Campesan G, Sartirello P, Stocco G, Menetto A (1995) Effects of linear alkylbenzene sulphonate (LAS) and cadmium in the digestive gland of mussels, Mytilus sp. Mar Environ Res 39:321–324
Dallinger R, Prosi F, Segner H, Back H (1987) Contaminated food and uptake of heavy metals by fish: a review and a proposal for further research. Oecologia 73:91–98
David JAO, Salaroli RB, Fontanetti CS (2008) The significance of changes in Mytella Falcata (Orbigny 1842) gill filaments chronically exposed to polluted environments. Micron 39:1293–1299
Dondero F, Piacentini L, Banni M, Rebelo M, Burlando B, Viarengo A (2005) Quantitative PCR analysis of two molluscan metallothionein genes unveils differential expression and regulation. Gene 345:259–270
Dondero F, Piacentini L, Marsano F, Rebelo M, Vergani L, Venier P et al (2006) Gene transcription profiling in pollutant exposed mussels (Mytilus spp.) using a new low-density oligonucleotide microarray. Gene 376:24–36
Dondero F, Banni M, Negri A, Boatti L, Dagnino A, Viarengo A (2011) Interactions of a pesticide/heavy metal mixture in marine bivalves: a transcriptomic assessment. BMC Genomics 12:195–212
Duarte CA, Giarratano E, Amin OA, Comoglio LI (2011) Heavy metal concentrations and biomarkers of oxidative stress in native mussels (Mytilus edulis chilensis) from Beagle Channel coast (Tierra del Fuego, Argentina). Mar Pollut Bull 62:1895–1904
Dyrynda EA, Pipe RK, Burt GR, Ratcliffe NA (1998) Modulations in the immune defences of mussels (Mytilus edulis) from contaminated sites in the UK. Aquat Toxicol 42:169–185
Ellis RP, Parry H, Spicer JI, Hutchinson TH, Pipe RK, Widdicombe S (2011) Immunological function in marine invertebrates: responses to environmental perturbation. Fish Shellfish Immunol 30:1209–1222
Ferderici G, Shaw BJ, Handy RD (2007) Toxicity of titanium dioxide nanoparticles to rainbow trout (Oncorhynchus mykiss): gill injury, oxidative stress, and other physiological effects. Aquat Toxicol 84:415–430
Gagnaire B, Thomas-Guyon H, Renault T (2004) In vitro effects of cadmium and mercury on Pacific oyster, Crassostrea gigas (Thunberg), hemocytes. Fish Shellfish Immunol 16:501–512
Galloway TS, Depledge MH (2001) Immunotoxicity in invertebrates: measurements and ecotoxicological relevance. Ecotoxicology 10:5–23
Garrigues P, Narbonne JF, Lafaurie M, Ribera D, Lemaire P, Raoux C et al (1993) Banking of environmental samples for short-term biochemical and chemical monitoring of organic contamination in coastal marine environments: the GICBEM experience (1986–1990). Sci Total Environ 139–140:225–236
Giambrini L, Auffret M, Pihan JC (1996) Haemocytes of the freshwater mussel, Dreissena polymorpha Pallas: cytology, cytochemistry and X-ray microanalysis. J Mollusc Stud 62:367–379
Goldberg ED (1989) The Mussel Watch concept. Environ Monit Assess 7:91–103
Hagger JA, Jones MB, Lowe D, Leonard DRB, Owen R, Galloway TS (2008) Application of biomarkers for improving risk assessments of chemicals under the Water Framework Directive: a case study. Mar Pollut Bull 56:1111–1118
Hagger JA, Lowe D, Dissanayake A, Jones M, Galloway T (2010) The influence of seasonality on biomarker responses in Mytilus edulis. Ecotoxicology 19:953–962
Handy RD (1995) Comparison of intermittent and continuous exposure to mercuric chloride in rainbow trout (Oncorhynchus mykiss), goldfish (Carassius auratus), and the fathead minnow (Pimephales promelas). Can J Fish Aquat Sci 52:13–22
Hawkins HK (1980) Reactions of lysosomes to cell injury. In: Trump BF, Arstilla AU (eds) Pathobiology of cell membranes. Academic, New York, pp 251–285
Hinton DE, Baumann BC, Gardner GR, Hawkins WE, Hindricks JD, Murchelano RA et al (1992) Biomarkers: biochemical, physiological, and histological markers of anthropogenic stress. Lewis, Boca Raton, p 347
Hogstrand C, Haux C (1996) Naturally high levels of zinc and metallothionein in liver of several species of the squirrelfish family from Queensland, Australia. Mar Biol 125:23–31
Huanxin W, Lejun Z, Presley BJ (2000) Bioaccumulation of heavy metals in oyster (Crassostrea virginica) tissue and shell. Environ Geol 39:1216–1226
Humphreys B, Smith SA (1989) The distribution and significance of sedimentary apatite in Lower to Middle Devonian sediments east of Plymouth Sound. Proc Ussher Soc 7:118–124
Jackim E, Morrison G, Steele R (1977) Effects of environmental factors on radiocadmium uptake by four species of marine bivalves. Mar Biol 40:303–308
Kayama F, Yoshida D, Elwell MR, Luster MI (1995) Role of tumour necrosis factor-α in cadmium-induced hepatotoxicity. Toxicol Appl Pharm 131:224–234
Kljaković-Gaspić Z, Odžak N, Ujević I, Zvonarić T, Horvat M, Barić A (2006) Biomonitoring of mercury in polluted coastal area using transplanted mussels. Sci Total Environ 368:199–209
Liu F, Wang W-X (2011) Differential roles of metallothionein-like proteins in cadmium uptake and elimination by the scallop Chlamys nobilis. Environ Toxicol Chem 30:738–746
Livak KJ, Schmittgen TD (2001) Analysis of relative gene expression data using real-time quantitative PCR and the 2-ΔΔ Ct method. Methods 25:402–408
Luengen AC, Friedman CS, Raimondi PT, Flegal AR (2004) Evaluation of mussel immune responses as indicators of contamination in San Francisco Bay. Mar Environ Res 57:197–212
Luoma SN, Rainbow PS (2005) Why is metal bioaccumulation so variable? Biodynamics as a unifying concept. Environ Sci Technol 39:1921–1931
Marchi B, Burlando B, Moore MN, Viarengo A (2004) Mercury- and copper-induced lysosomal membrane destabilisation depends on [Ca2+]i dependent phospholipase A2 activation. Aquat Toxicol 66:197–204
Moreau JL, Baudrimont M, Carrier P, Peltier G, Bourdineaud JP (2008) Metal binding and antioxidant properties of chimeric tri- and tetra-domained metallothioneins. Biochimie 90:705–716
Neff JM, Hillman RE, Scott Carr R, Buhl RL, Lahey JI (1987) Histopathologic and biochemical responses in arctic marine bivalve molluscs exposed to experimentally spilled oil. Arctic 40:220–229
Newman MC, Mulvey M, Beeby A, Hurst RW, Richmond L (1994) Snail (Helix aspersa) exposure history and possible adaptation to lead as reflected in shell composition. Arch Environ Contam Toxicol 27:346–351
Nicholson S (2001) Ecotoxicological and toxicological responses to copper in Perna viridis (L.) (Bivalvia: Mytilidae) haemocyte lysosomal membranes. Chemosphere 45:399–407
Orbea A, Ortiz-Zarragoitia M, Sole M, Porte C, Cajaraville MP (2002) Antioxidant enzymes and peroxisome proliferation in relation to contaminant body burdens of PAHs and PCBs in bivalve molluscs, crabs and fish from the Urdaibai and Plentzia estuaries (Bay of Biscay). Aquat Toxicol 58:75–98
Orrenius S, McConkey DJ, Bellomo G, Necotera P (1989) Role of Ca2+ in toxic cell killing. Trends Pharmacol Sci 7:281–285
Pickwell GV, Steinert SA (1984) Serum biochemical and cellular responses to experimental cupric ion challenge in mussels. Mar Environ Res 14:245–265
Pipe RK, Coles JA (1995) Environmental contaminants influencing immune function in marine bivalve molluscs. Fish Shellfish Immunol 5:581–595
Pipe RK, Coles JA, Thomas ME, Fossato VU, Pulsford AL (1995) Evidence for environmentally derived immunomodulation in mussels from the Venice Lagoon. Aquat Toxicol 32:59–73
Rainbow PS, Blackmore G, Wang W-X (2003) Effects of previous field-exposure history on the uptake of trace metals from water and food by the barnacle Balanus amphitrite. Mar Ecol Prog Ser 259:201–213
Rickwood CJ, Galloway TS (2004) Acetylcholinesterase inhibition as a biomarker of adverse effect: a study of Mytilus edulis exposed to the priority pollutant chlorfenvinphos. Aquat Toxicol 67:45–56
Roesijadi G, Young JS, Drum AS, Gurtisen JM (1984) Behaviour of trace metals in Mytilus edulis during a reciprocal transplant field experiment. Mar Ecol Prog Ser 18:155–170
Roesijadi G, Brubacher LL, Unger ME, Anderson RS (1997) Metallothionein mRNA induction and generation of reactive oxygen species in molluscan hemocytes exposed to cadmium in vitro. Comp Biochem Physiol C 118:171–176
Schneider KR, Wethey DS, Helmuth BST, Hilbish TJ (2005) Implications of movement behavior on mussel dislodgement: exogenous selection in a Mytilus spp. hybrid zone. Mar Biol 146:333–343
Schoenmakers TJM, Klaren PHM, Flik G, Lock RAC, Pang PKT, Wendelaar Bonga SE (1992) Actions of cadmium on basolateral plasma membrane proteins involved in calcium uptake by fish intestine. J Membr Biol 127:161–172
Sheir S, Handy R (2010) Tissue injury and cellular immune responses to cadmium chloride exposure in the common mussel Mytilus edulis: modulation by lipopolysaccharide. Arch Environ Contam Toxicol 59:602–613
Shi D, Wang W-X (2005) Uptake of aqueous and dietary metals by mussel Perna viridis with different Cd exposure histories. Environ Sci Technol 39:9363–9369
Smaoui-Damak W, Rebai T, Berthet B, Hamza-Chaffai A (2006) Does cadmium pollution affect reproduction in the clam Ruditapes decussatus? A one-year case study. Comp Biochem Physiol C 143:252–261
Soazig L, Marc L (2003) Potential use of the levels of the mRNA of a specific metallothionein isoform (MT-20) in mussel (Mytilus edulis) as a biomarker of cadmium contamination. Mar Pollut Bull 46:1450–1455
Sokolova IM, Evans S, Hughes FM (2004) Cadmium-induced apoptosis in oyster hemocytes involves disturbance of cellular energy balance but no mitochondrial permeability transition. J Exp Biol 207:3369–3380
Soto M, Cajaraville MP, Angulo E, Mrigomez I (1996) Autometallographic localizaton of protein-bound copper and zinc in the common winkle, Littorina littorea: a light microscopical study. Histochem J 28:689–701
Stewart AR, Luoma SN, Schlekat CE, Doblin MA, Hieb KA (2004) Food web pathway determines how selenium affects aquatic ecosystems: a San Francisco Bay case study. Environ Sci Technol 38:4519–4526
Sunila I (1988) Acute histological responses of the gill of the mussel, Mytilus edulis, to exposure by environmental pollutants. J Invertebr Pathol 52:137–141
Svärdh L, Johannesson K (2002) Incidence of hemocytes and parasites in costal populations of blue mussel (M. edulis)—testing correlations with area, season and distance to industrial plants. J Invertebr Pathol 80:22–28
Tripp MR (1992) Phagocytosis by hemocytes of the hard clam, Mercenaria mercinaria. J Invertebr Pathol 59:222–227
Turner A, Barrett M, Brown MT (2009) Processing of antifouling paint particles by Mytilus edulis. Environ Pollut 157:215–220
Veldhuizen-Tsoerkan MB, Holwerda DA, van der Mast CA, Zandee DI (1991) Synthesis of stress proteins under normal and heat shock conditions in gill tissue of sea mussels (Mytilus edulis) after chronic exposure to cadmium. Comp Biochem Physiol C 100:699–706
Vidal-Liñán L, Bellas J, Campillo JA, Beiras R (2010) Integrated use of antioxidant enzymes in mussels, Mytilus galloprovincialis, for monitoring pollution in highly productive coastal areas of Galicia (NW Spain). Chemosphere 78:265–272
Vlahogianni T, Dassenakis M, Scoullos MJ, Valavanidis A (2007) Integrated use of biomarkers (superoxide dismutase, catalase and lipid peroxidase) in mussels M. galloprovincialis for assessing heavy metal pollution in coastal areas from the Saronikos Gulf of Greece. Mar Pollut Bull 54:1361–1371
Weeks BA, Anderson DP, DuFour AP, Fairbrother A, Goven AJ, Lahvis GP et al (1992) Immunological biomarkers to assess environmental stress. In: Huggert RL, Kimerle RA, Mehrle JPM, Bergman HL (eds) Biomarkers: biological, physiological and histological markers. Lewis, Chelsea, pp 211–234
Weibel ER, Kistler GS, Scherle WF (1966) Practical stereological methods for morphometric cytology. J Cell Biol 30:23–38
Yap C, Azmizan A, Hanif M (2011) Biomonitoring of trace metals (Fe, Cu, and Ni) in the mangrove area of peninsular Malaysia using different soft tissues of flat tree oyster Isognomon alatus. Water Air Soil Pollut 218:19–36
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This study was funded by a Grant from the Egyptian government through a doctoral scholarship to S. Sheir.
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Sheir, S.K., Handy, R.D. & Henry, T.B. Effect of Pollution History on Immunological Responses and Organ Histology in the Marine Mussel Mytilus edulis Exposed to Cadmium. Arch Environ Contam Toxicol 64, 701–716 (2013). https://doi.org/10.1007/s00244-012-9868-y
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DOI: https://doi.org/10.1007/s00244-012-9868-y