Abstract
Exposure to copper pollution affects reproduction, growth and survival of earthworms. It is known that earthworms can cope with high copper burdens, but the distinction between physiological acclimation and evolutionary heritable changes and associated fitness consequences of the adaption to long-term copper exposure has rarely been studied. To investigate adaptation of earthworm populations of Dendrobaena octaedra to copper contamination, three populations from polluted soil were studied and compared to three unpolluted reference sites. Adult worms were collected at all six sites and cultured in uncontaminated control soil in the laboratory, where life-history traits were studied and F1-generations were produced. The newly hatched F1-generation worms were placed in uncontaminated control or copper-spiked soil to study if the adaptation was due to acclimation or genetic inheritance. This experiment showed that populations from polluted areas generally had a higher individual growth rate, reduced time to maturity, increased reproduction, and also increased mortality compared to the reference populations in both control and copper-spiked soil. The differences in life-history traits indicate that natural selection has resulted in genetic adaptation to copper pollution in the exposed populations. The population growth rates suggest a weak detrimental effect on population growth rate of being exposed to copper for both type of populations, but no sign of cost. On the contrary, estimates of population growth rates integrating all life-history traits showed that copper adapted populations perform on average relatively better than reference populations in both uncontaminated and copper-spiked soil.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Agra AR, Guilhermino L, Soares A, Barata C (2010) Genetic costs of tolerance to metals in Daphina longispina populations historically exposed to a copper mine drainage. Environ Toxicol Chem 29(4):939–946
Arnaud L, Haubruge E (2002) Insecticide resistance enhances male reproductive success in a beetle. Evolution 56(12):2435–2444
Aziz NA, Morgan AJ, Kille P (1999) Metal resistance in earthworms; genetic adaptation or physiological acclimation. Pedobiologia 43(6):594–601
Bengtsson G, Rundgren S (1982) Population-density and species number of enchytraeids in coniferous forest soils polluted by a brass mill. Pedobiologia 24(4):211–218
Bengtsson G, Rundgren S (1984) Ground-living invertebrates in metal-polluted forest soils. Ambio 13(1):29–33
Bengtsson G, Rundgren S (1988) The Gusum case—a brass mill and the distribution of soil Collembola. Can J Zool Revue Canadienne De Zoologie 66(7):1518–1526
Bengtsson G, Nordstrom S, Rundgren S (1983) Population-density and tissue metal concentration of lumbricids in forest soils near a brass mill. Environ Pollut Ser A Ecol Biol 30(2):87–108
Bengtsson G, Ek H, Rundgren S (1992) Evolutionary response of earthworms to long-term metal exposure. Oikos 63(2):289–297
Bindesbøl AM, Bayley M, Damgaard C, Holmstrup M (2007) Life-history traits and population growth rate in the laboratory of the earthworm Dendrobaena octaedra cultured in copper-contaminated soil. Appl Soil Ecol 35(1):46–56
Brandon RN (1991) Adaptation and environment. Princeton University Press, Princeton, New Jersey
Brulle F, Mitta G, Leroux R, Lemiere S, Lepretre A, Vandenbulcke F (2007) The strong induction of metallothionein gene following cadmium exposure transiently affects the expression of many genes in Eisenia fetida: a trade-off mechanism? Comp Biochem Physiol C Toxicol Pharmacol 144(4):334–341
Calow P, Sibly RM (1990) A physiological-basis of population processes—ecotoxicological implications. Funct Ecol 4(3):283–288
Caswell H (2001) Matrix population models. Construction, analysis and interpretation, 2nd edn. Sinauer, Sunderland
Damgaard C, Hojer R, Bayley M, Scott-Fordsmand JJ, Holmstrup M (2002) Dose-response curve modeling of excess mortality caused by two forms of stress. Environ Ecol Stat 9(2):195–200
Dechamps C, Noret N, Mozek R, Escarre J, Lefebvre C, Gruber W, Meerts P (2008) Cost of adaptation to a metalliferous environment for Thlaspi caerulescens: a field reciprocal transplantation approach. New Phytol 177(1):167–177
Demuynck S, Grumiaux F, Mottier V, Schikorski D, Lemiere S, Lepretre A (2006) Metallothionein response following cadmium exposure in the oligochaete Eisenia fetida. Comp Biochem Physiol C Toxicol Pharmacol 144(1):34–46
Donker MH, Zonneveld C, van Straalen NM (1993) Early reproduction and increased reproductive allocation in metal-adapted populations of the terrestrial isopod Porcellio scaber. Oecologia 96(3):316–323
Edwards CA, Bohlen PJ (1996) Biology and ecology of earthworms, 3rd edn. Chapman & Hall, London
Forbes VE, Calow P, Sibly RM (2001) Are current species extrapolation models a good basis for ecological risk assessment? Environ Toxicol Chem 20(2):442–447
Hamel S, Gaillard JM, Yoccoz NG, Loison A, Bonenfant C, Descamps S (2010) Fitness costs of reproduction depend on life speed: empirical evidence from mammalian populations. Ecol Lett 13(7):915–935
Holmstrup M, Krogh PH, Lokke H, de Wolf W, Marshall S, Fox K (2001) Effects and risk assessment of linear alkylbenzene sulfonates in agricultural soil. 4. The influence of salt speciation, soil type, and sewage sludge on toxicity using the collembolan Folsomia fimetaria and the earthworm Aporrectodea caliginosa as test organisms. Environ Toxicol Chem 20(8):1680–1689
Holmstrup M, Sørensen JG, Overgaard J, Bayley M, Bindesbøl AM, Slotsbo S, Fisker KV, Maraldo K, Waagner D, Labouriau R, Asmund G (2011) Body metal concentrations and glycogen reserves in earthworms (Dendrobaena octaedra) from contaminated and uncontaminated forest soil. Environ Pollut 159(1):190–197
Hopkin SP (1989) Ecophysiology of metals in terrestrial invertebrates. Pollution monitoring series. Elsevier applied science, London
Knott KE, Haimi J (2010) High mitochondrial DNA sequence diversity in the parthenogenetic earthworm Dendrobaena octaedra. Heredity 105(4):341–347
Langdon CJ, Piearce TG, Meharg AA, Semple KT (2001) Resistance to copper toxicity in populations of the earthworms Lumbricus rubellus and Dendrodrilus rubidus from contaminated mine wastes. Environ Toxicol Chem 20(10):2336–2341
Langdon CJ, Piearce TG, Meharg AA, Semple KT (2003) Inherited resistance to arsenate toxicity in two populations of Lumbricus rubellus. Environ Toxicol Chem 22(10):2344–2348
Langdon CJ, Morgan AJ, Charnock JM, Semple KT, Lowe CN (2009) As-resistance in laboratory-reared F1, F2 and F3 generation offspring of the earthworm Lumbricus rubellus inhabiting an As-contaminated mine soil. Environ Pollut 157(11):3114–3119
Lukkari T, Taavitsainen M, Vaisanen A, Haimi J (2004) Effects of heavy metals on earthworms along contamination gradients in organic rich soils. Ecotoxicol Environ Saf 59(3):340–348
Maestri E, Marmiroli M, Visioli G, Marmiroli N (2010) Metal tolerance and hyperaccumulation: costs and trade-offs between traits and environment. Environ Exp Bot 68(1):1–13
Morgan AJ, Kille P, Sturzenbaum SR (2007) Microevolution and ecotoxicology of metals in invertebrates. Environ Sci Technol 41(4):1085–1096
Mousseau TA, Fox CW (1998) The adaptive significance of maternal effects. Trends Ecol Evol 13:403–407
Posthuma L (1997) Effects of toxicants on population and community parameters in field conditions, and their potential use in the validation of risk assessment methods. In: van Straalen NM, Løkke H (eds) Ecological risk assessment of contaminants in soil. vol Ecotoxicology series 5. Chapman & Hall, Cornwall, p 335
Posthuma L, van Straalen NM (1993) Heavy-metal adaptation in terrestrial invertebrates—a review of occurrence, genetics, physiology and ecological consequences. Comp Biochem Physiol C Pharmacol Toxicol Endocrinol 106(1):11–38
Posthuma L, Verweij RA, Widianarko B, Zonneveld C (1993) Life-history patterns in metal-adapted Collembola. Oikos 67(2):235–249
Reinecke SA, Prinsloo MW, Reinecke AJ (1999) Resistance of Eisenia fetida (Oligochaeta) to cadmium after long-term exposure. Ecotoxicol Environ Saf 42(1):75–80
Roelofs D, Marien J, van Straalen NM (2007) Differential gene expression profiles associated with heavy metal tolerance in the soil insect Orchesella cincta. Insect Biochem Mol Biol 37(4):287–295
Rozen A (2006) Effect of cadmium on life-history parameters in Dendrobaena octaedra (Lumbricidae: Oligochaeta) populations originating from forests differently polluted with heavy metals. Soil Biol Biochem 38(3):489–503
Rundgren S (1975) Vertical distribution of Lumbricids in Southern Sweden. Oikos 26(3):299–306
Salice CJ, Anderson TA, Roesijadi G (2010) Adaptive responses and latent costs of multigeneration cadmium exposure in parasite resistant and susceptible strains of a freshwater snail. Ecotoxicology 19(8):1466–1475
Seber GAF, Wild CJ (1989) Nonlinear regression. Wiley, New York
Simonsen V, Holmstrup M (2008) Deviation from apomictic reproduction in Dendrobaena octaedra? Hereditas 145(4):212–214
Simonsen V, Laskowski R, Bayley M, Holmstrup M (2008) Low impact of metal pollution on genetic variation in the earthworm Dendrobaena octaedra measured by allozymes. Pedobiologia 52(1):51–60
Spurgeon DJ, Hopkin SP (1996) The effects of metal contamination on earthworm populations around a smelting works: quantifying species effects. Appl Soil Ecol 4(2):147–160
Spurgeon DJ, Hopkin SP (1999a) Life-history patterns in reference and metal-exposed earthworm populations. Ecotoxicology 8(2):133–141
Spurgeon DJ, Hopkin SP (1999b) Tolerance to zinc in populations of the earthworm Lumbricus rubellus from uncontaminated and metal-contaminated ecosystems. Arch Environ Contam Toxicol 37(3):332–337
Spurgeon DJ, Hopkin SP (2000) The development of genetically inherited resistance to zinc in laboratory-selected generations of the earthworm Eisenia fetida. Environ Pollut 109(2):193–201
Stöp-Bowitz C (1969) A contribution to our knowlege of the systematics and zoogeography of Norwegian earthworms. (Annelida, Oligochaeta: Lumbricidae). Nytt Magasin Zoologi 17:169–280
Sturzenbaum SR, Georgiev O, Morgan AJ, Kille P (2004) Cadmium detoxification in earthworms: from genes to cells. Environ Sci Technol 38(23):6283–6289
Timmermans M, Ellers J, Roelofs D, van Straalen NM (2005) Metallothionein mRNA expression and cadmium tolerance in metal-stressed and reference populations of the springtail Orchesella cincta. Ecotoxicology 14(7):727–739
Tosza E, Dumnicka E, Niklinska M, Rozen A (2010) Enchytraeid and earthworm communities along a pollution gradient near Olkusz (southern Poland). Eur J Soil Biol 46(3–4):218–224
Tranvik L, Bengtsson G, Rundgren S (1993) Relative abundance and resistance traits of 2 Collembola species under metal stress. J Appl Ecol 30(1):43–52
Tyler G, Pahlsson AMB, Bengtsson G, Baath E, Tranvik L (1989) Heavy-metal ecology of terrestrial plants, microorganisms and invertebrates—a review. Water Air Soil Pollut 47(3–4):189–215
van Straalen NM, Timmermans M (2002) Genetic variation in toxicant-stressed populations: an evaluation of the “genetic erosion” hypothesis. Human Ecol Risk Assess 8(5):983–1002
Wang YP, Shi JY, Wang H, Lin Q, Chen XC, Chen YX (2007) The influence of soil heavy metals pollution on soil microbial biomass, enzyme activity, and community composition near a copper smelter. Ecotoxicol Environ Saf 67(1):75–81
Yamamura M, Mori T, Suzuki KT (1981) Metallothionein induced in the earthworm. Experientia 37(11):1187–1189
Acknowledgments
This study was supported by grants from The Carlsberg Foundation (JGS) and Danish Research Council (MH). We thank Valery Forbes for constructive comments on the manuscript.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Fisker, K.V., Sørensen, J.G., Damgaard, C. et al. Genetic adaptation of earthworms to copper pollution: is adaptation associated with fitness costs in Dendrobaena octaedra?. Ecotoxicology 20, 563–573 (2011). https://doi.org/10.1007/s10646-011-0610-8
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10646-011-0610-8