Abstract
Aluminum increases in concentration in acidified waters and is sometimes more toxic to aquatic organisms at acidic than at neutral pH. This paper examined the interaction of pH and Al in inhibiting uptake of Ca++ from lake water by postmolt crayfish,Orconectes virilis (Hagen). Aluminum at 200 μg/L in non-acidified media had no effect on45Ca uptake. Media at pH 5.5 without Al reduced45Ca uptake to 30% of that in non-acidified media. Aluminum at each of the concentrations of 200, 500 or 1,000 μg/L in media at pH 5.5 reduced45Ca uptake slightly more, to about 20% of that in non-acidified media. The degree of inhibition of45Ca uptake by Al in acidified media was not related to its concentration. Lack of dose-response may be explained by the limited solubility of Al salts and the limited concentrations of the toxic monomeric species which are present in spite of increases in total Al concentration. These toxic species are presumably in the dialyzable fraction of Al which represented 6 to 17% of total lumogallion-reactive Al in media at pH 5.5 and 1 to 10% of total reactive Al at pH 7.O. At pH 5.5, concentration of dialyzable Al was only 67% higher in 1,000 μg/L than in 200 μg/L Al media. Lack of Al toxicity at pH 7.0 may be explained by changes in Al species to less toxic species and/or the apparent lower solubility of A1C13 in the Precambrian Shield lake water at pH 7.0 than at 5.5. Aluminum toxicity constitutes a small additional stress to moltingO. virilis in softwater lakes acidified to between pH 6.0 and 5.0 which have elevated Al levels. In this pH range, natural populations ofO. virilis subject to acidification fail, apparently because of difficulties of ionic regulation coupled with other factors.
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References
Baker JP, Schofield CL (1980) Aluminum toxicity to fish as related to acid precipitation and Adirondack surface water quality. In: Drabløs D, Tollan A (eds) Ecological impact of acid precipitation, SNSF Project, Oslo, Norway, pp 292–293
— (1982) Aluminum toxicity to fish in acidic waters. Water Air Soil Pollut 18:289–309
Blarney FPC, Edwards DG, Asher CJ (1983) Effects of aluminum, OH:A1 and P:A1 ratios, and ionic strength on soybean root elongation in solution culture. Soil Sci 136:197–207
Burrows WD (1977) Aquatic aluminum: Chemistry, toxicology, and environmental prevalence. CRC Critical Reviews in Environmental Control 7:167–216
Campbell PGC, Brisson M, Bougie R, Tessier A, Villeneuve J-P (1983) Speciation of aluminum in acidic freshwaters. Anal Chem 55:2246–2252
Clark KL, Hall RJ (1985) Effects of elevated hydrogen ion and aluminum concentrations on the survival of amphibian embryos and larvae. Can J Zool 63:116–123
Cleugh TR, Hauser BW (1971) Results of the initial survey of the Experimental Lakes Area, northwestern Ontario. J Fish Res Board Can 28:129–137
Cronan CS, Schofield CL (1979) Aluminum leaching response to acid precipitation: Effects on high-elevation watersheds in the northeast. Science 204:304–306
Davies IJ (1986) Population collapse of the crayfishOrconectes virilis (Hagen) in response to an experimental whole-lake acidification. Can J Fish Aquat Sci (submitted for publication)
Dickson W (1978) Some effects of the acidification of Swedish lakes. Verb Internat Verein Limnol 20:851–856
Dixon WJ, Massey FJ, Jr (1969) Introduction to statistical analysis, 3rd ed. McGraw Hill, Toronto, xii + 638 pp
Driscoll CT, Jr, Baker JP, Jr, Bisgoni JJ, Jr, Schofield CL (1980) Effect of aluminum speciation on fish in dilute acidified waters. Nature 284:161–164
France RL (1982) Comment onDaphnia respiration in low pH water. Hydrobiologia 94:195–198
Havas M, Hutchinson TC (1982) Aquatic invertebrates from the Smoking Hills, N.W.T.: effect of pH and metals on mortality. Can J Fish Aquat Sci 39:890–903
— (1983) Effect of low pH on the chemical composition of aquatic invertebrates from tundra ponds at the Smoking Hills, N.W.T. Canada. Can J Zool 61:241–249
Herczeg A, Hesslein RH (1984) Determination of hydrogen ion concentration in softwater lakes using carbon dioxide equilibria. Geochim Cosmochim Acta 48:837–845
Herrmann R, Baron J (1980) Aluminum mobilization in acid stream environments Great Smoky Mountains National Park, USA. In: Drabløs D, Tollan A (eds) Ecological impact of acid precipitation, SNSF Project, Oslo, Norway, pp 218–219
Hydes DJ, Liss PS (1976) Fluorometric method for the determination of low concentrations of dissolved aluminum in natural waters. Analyst 101:922–931
Johnson GH, Taylor HE, Skogerboe RK (1979) Determination of trace metals in natural waters by the d.c. argon plasma, multi-element atomic emission spectrometer (DCP-MAES) technique. Spectrochimica Acta 348:197–212
LaZerte BD (1984) Forms of aqueous aluminum in acidified catchments of central Ontario: a methodological analysis. Can J Fish Aquat Sci 41:766–776
Malley DF (1980) Decreased survival and calcium uptake by the crayfishOrconectes virilis in low pH. Can J Fish Aquat Sci 37:364–372
Malley DF, Tinker LJ (1979) Calcium uptake: A sublethal test for crayfish. In: Scherer E (ed) Toxicity tests for freshwater rganisms. Can Spec Publ Fish Aquat Sci 44:150–159
Muniz IP, Leivestad H (1980) Toxic effects of aluminum on the brown trout,Salmo trutta L. In: Drabløs D, Tollan A (eds) Ecological impact of acid precipitation, SNSF Project, Oslo, Norway, pp 320–321
Playle R, Gleed G, Jonasson R, Kramer JR (1982) Comparison of atomic absorption spectrometric, spectrophotometric, and fluorimetric methods for determination of aluminum in water. Anal Chim Acta 134:369–373
Schindler DW, Ruszczynski T (1983) A test of limnological data from the Experimental Lakes Area, northwestern Ontario, for evidence of acidification. Can Tech Rep Fish Aquat Sci 1147:iv + 17 pp
Schindler DW, Wagemann R, Cook RB, Ruszczynski T, Prokopowich, J (1980) Experimental acidification of Lake 223, Expèrimental Lakes Area: background data and the first three years of acidification. Can J Fish Aquat Sci 37:342–354
Spry DJ, Wood CM, Hodson PV (1981) The effects of environmental acid on freshwater fish with particular reference to the softwater lakes in Ontario and the modifying effects of heavy metals. A literature review. Can Tech Rep Fish Aquat Sci No. 999, 144 pp
Steel GD, Torrie JH (1960) Principles and procedures of statistics. McGraw-Hill, New York, 481 pp
Stevenson JR (1975) The molting cycle in the crayfish: Recognizing the molting stages, effects of ecdysone, and changes during the cycle. In: Avault JW, Jr (ed) Freshwater crayfish, Louisiana State University, LA, pp 218–219
Winer BJ (1971) Statistical principles in experimental design. 2nd ed. McGraw Hill, New York, 907 pp
Witters H, Vangenechten JHD, Van Puymbroeck S, Vanderborght OLJ (1984) Interference of aluminum and pH on the Na-influx in an aquatic insectCorixa punctata (Illig.) Bull Environ Contam Toxicol 32:575–579
Wright RF, Skogheim OK (1983) Aluminum speciation at the interface of an acid stream and a limed lake. Vatten 39:301–304
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Malley, D.F., Chang, P.S.S. Effects of aluminum and acid on calcium uptake by the crayfishOrconectes virilis . Arch. Environ. Contam. Toxicol. 14, 739–747 (1985). https://doi.org/10.1007/BF01055781
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DOI: https://doi.org/10.1007/BF01055781