Abstract
Data in the literature on the toxicity and uptake of copper by soil invertebrates are contradictory. Copper toxicity and bioaccumulation studies were therefore performed using earthworms and oribatid mites. Field-simulating experiments in soil-filled plastic containers showed that earthworms try to escape moderately toxic situations and that they are much more sensitive than oribatid mites to temporary high Cu2+ concentrations in soils. The total copper concentration in the bodies of the earthworm species Octolasium cyaneum was measured in experiments with different soil types and different amounts of added CuSO4. The copper concentrations in the earthworms increased in response to the higher concentrations of the copper fraction extractable with 2.5% acetic acid in the soil. Furthermore, internal copper concentrations showed a slight tendency to oscillate. The worms died when the concentrations within their bodies exceeded about 100–120 ppm, calculated on a dry weight basis. To interpret the experimental results, a compartment model is proposed which describes the dynamics of different fractions of copper in worms living in varying soil environments. Applying this model, the different reports on toxicity and uptake of copper in the literature no longer contradict each other.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Beyer WN, Chaney RL, Mulhern BM (1982) Heavy metal concentrations in earthworms from soil amended with sewage sludge. J Environ Qual 11:381–385
Brown BE (1977) Uptake of copper and lead by a metal-tolerant isopod Asellus meridianus Rac. Freshwater Biol 1:235–244
Chang AC, Warneke JE, Page AL, Lund LJ (1984) Accumulation of heavy metals in sewage sludge-treated soils. J Environ Qual 13:87–91
Cotton DCF, Curry JP (1980a) The effects of cattle and pig slurry fertilizers on earthworms in grassland managed for silage production. predobiologia 20:181–188
Cotton DCF, Curry JP (1980b) The response of earthworm populations to high applications of pig slurry. Pedobiologia 20:189–196
Coughtrey PJ, Martin MH (1977) The uptake of lead, zinc, cadmium, and copper by the pulmonate mollusc, Helix aspersa Mueller, and its relevance to the monitoring of heavy metal contamination of the environment. Oecologia (Berlin) 27:65–74
Eisler R (1981) Trace metal concentrations in marine organisms. Pergamon Press, New York
Emmerich WE, Lund LJ, Page AL, Change AC (1982) Predicted solution phase forms of heavy metals in sewage sludge-treated soils. J Environ Qual 11:182–186
Evans GW (1973) Copper homeostasis in the mammalian system. Physiol Rev 53:535–570
Gunkel G, Streit B (1980) Mechanisms of bioaccumulation of a herbicide (atrazine, s-triazine) in a freshwater mollusc (Ancylus fluviatilis Muell.) and a fish (Coregonus fera Jurine). Water Research 14:1573–1584
Hall RA, Zook EG, Meaburn GM (1978) National marine fisheries service survey of trace elements in the fishery resource. U.S. Dept. Commerce NOAA Tech. Rept. NMFS SSRF-721:1–313
Hartenstein R, Leaf AL, Neuhauser EF, Bickelhaupt DH (1980a) Composition of the earthworm Eisenia foetida (SAVIGNY) and assimilation of 15 elements from sludge during growth. Comp Biochem Physiol 66C:187–192
Hartenstein R, Neuhauser EF, Collier J (1980b) Accumulation of heavy metals in the earthworm Eisenia foetida. J Environ Qual 9:23–26
Hartenstein R, Neuhauser EF, Narahara A (1981) Effects of metal and other elemental additives to activated sludge on growth of Eisenia foetida. J Environ Qual 10:372–376
Helmcke PA, Robarge WP, Korotev RL, Schomberg PJ (1979) Effects of soil-applied sewage sludge on concentrations of elements in earthworms. J Environ Qual 8:322–327
Hopkin SP, Martin MH (1982) The distribution of zinc, cadmium, lead and copper within the woodlouse Oniscus asellus (Crustacea, Isopoda). Oecologia (Berlin) 54:227–232
Hopps HC (1974) “Overview”. In: Geochemistry and the Environment, Vol. I. The relation of selected trace elements to health and disease.—Workshop at the Asilomar Conference Grounds, Pacific Grove, California, February, 1972. National Academy of Sciences, Washington D.C.
Hunter BA, Johnson MS (1982) Food chain relationships of copper and cadmium in contaminated grassland ecosystems. OIKOS 38:108–117
Ireland MP (1979) Metal accumulation by the earthworms Lumbricus rubellus, Dendrobaena veneta and Eiseniella tetraedra living in heavy metal polluted sites. Environ Pollut 19:201–206
Jaeggy A, Streit B (1982) Toxic effects of soluble copper on Octolasium cyaneum SAV. (Lumbricidae.) Revue suisse Zool 89:887–889
Larcher W (1980) Physiological Plant Ecology. 2nd ed., Springer 1980 (transl from German)
McLaren RG, Crawford DV (1973a) Studies on soil copper. I. The fractionation of copper in soils. J Soil Science 24:172–181
McLaren RG, Crawford DV (1973b) Studies on soil copper. II. The specific adsorption of copper by soils. J Soil Science 24:443–452
Mullins GL, Martens DC, Gettier SW, Miller WP (1982) Form and availability of copper and zinc in a rhodic paleudult following long-term CuSO4 and ZnSO4 applications. J Environ Qual 11:573–577
Neuhauser EF, Hartenstein R (1980) Efficiencies of extractants used in analyses of heavy metals in sludges. J Environ Qual 9:21–22
Owen ChA Jr (1964) Distribution of copper in the rat. Am J Physiol 207:446–448
Rhee JA van (1975) Copper contamination effects on the earthworms by disposal of pig waste in pastures. Progr Soil Zool: 451–457
Sanders BM, Jenkins KD, Sunda WG, Costlow JD (1983) Free cupric ion activity in seawater: Effects on metallothionein and growth in crab, larvae. Science 222:53–55
Scheffer F, Schachtschabel P, Blume HP, Hartge KH (1979) Lehrbuch der Bodenkunde. Enke, Stuttgart 10th ed
Streit B (1979) Uptake, accumulation, and release of organic pesticides by benthic invertebrates. 3. Distribution of 14C-atrazine and 14C-lindane in an experimenta, 3-step food chain microcosm. Arch Hydrobiol Suppl 55:373–400
Streit B (1982) “Minireview”: Water turnover rates and half-life times in animals studied by use of labelled and non-labelled water. Comp Biochem Physiol 72A:445–454
Streit B (1982b) Microarthropod population, gradients and aggregations in the soil of a mixed temperate deciduous forest. Revue suisse Zool 89:993–1004
Streit B, Jaeggy A (1983) Effect of soil type on copper toxicity and copper uptake in Octolasium cyaneum (Lumbricidae). In: Lebrun Ph et al. (eds) New Trends in Soil Biology: 569–575
Stumm W, Morgan JJ (1981) Aquatic Chemistry. Wiley, New York, 2nd ed, 1981
Thornton I (1981) Geochemical aspects of the distribution and forms of heavy metals in soil. In: Lepp NW (ed) Effect of heavy metal pollution on plants, London, 1–33
Wieser W (1979) Flow of copper through a terrestrial food web. In: Nriagu JO (ed) Copper in the environment. Part I: Ecological cycling. Wiley, New York
Wieser W, Dallinger R, Busch G (1977) The flow of copper through a terrestial food chain. II. Factors affecting the copper content of isopods. Oecologia (Berlin) 30:265–272
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Streit, B. Effects of high copper concentrations on soil invertebrates (earthworms and oribatid mites):. Oecologia 64, 381–388 (1984). https://doi.org/10.1007/BF00379137
Received:
Issue Date:
DOI: https://doi.org/10.1007/BF00379137