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A morphometric and x-ray energy dispersive approach to monitoring pH-altered cadmium toxicity inAnabaena flos-aquae

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Abstract

Cadmium toxicity and uptake as influenced by different pH values have been studied in the freshwater cyanobacteriumAnabaena flos-aquae, using the techniques of morphometric analysis, x-ray energy dispersive analysis and atomic absorption spectrophotometry. A general reduction in cell dimension, thylakoid surface area, number and volume of polyhedral bodies, polyphosphate bodies, cyanophycin granules, lipid bodies, membrane limited crystalline inclusions, volume and number of wall layers and mesosomes was observed. These reductions were more pronounced in both acidic and alkaline medium than at pH 7.2. At 0.12 μM Cd, the uptake increased with alkaline pH values, and uptake was greater at pH 7.2 than at either acid or alkaline pHs. Lysis of cell wall at 1.18 μM Cd showed the following decreasing trend: pH 4.0 > pH 5.5 > pH 10.0 > pH 9.0 > pH 7.2. There was a total loss of lipid bodies at 1.18 μM Cd at all pH values listed.

It is suggested that these techniques can be successfully employed for bioassay studies of metal toxicity to algae. In particular, cell wall lysis and loss of lipids by algae are good indicators of pH effects and metal toxicity in the aquatic ecosystem.

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References

  • Baxter M, Jensen TE (1980a) Uptake of magnesium, strontium, barium, and manganese byPlectonema boryanum (Cyanophyceae) with special reference to polyphosphate bodies. Protoplasma 104:81–89

    Google Scholar 

  • — (1980b) A study of methods forin situ X-ray energy dispersive analysis of polyphosphate bodies inPlectonema boryanum. Arch Microbiol 126:213–215

    Google Scholar 

  • Codd GA, Stewart WDP (1976) Polyhedral bodies and ribulose 1,5biphosphate carboxylase of the blue-green algaAnabaena cylindrica. Planta (Berl) 130:323–326

    Google Scholar 

  • Demon A, DeBruin M, Wolterbeek H Th (1988) The influence of pH on trace metal uptake by an alga (Scenedesmus pannonicus subsp. Berlin) and fungus (Aureobasidium pullulons). Environ Monitor and Assess 10:165–173

    Google Scholar 

  • Jensen TE, Baxter M, Rachlin JW, Jani V (1982a) Uptake of heavy metals byPlectonema boryanum (Cyanophyceae) into cellular components, especially polyphosphate bodies: An X-ray energy dispersive study. Environ Pollut Ser A 27:119–127

    Google Scholar 

  • Jensen TE, Rachlin JW, Jani V, Warkentine B (1982b) An X-ray energy dispersive study of cellular compartmentalization of lead and zinc inChlorella saccharophila (Chlorophyta),Navicula incerta andNitzschia closterium (Bacillariophyta). Environ and Exp Bot 22:319–328

    Google Scholar 

  • Jensen TE, Sicko LM (1974) Phosphate metabolism in blue-green algae. I. Fine structure of the “polyphosphate overplus” phenomenon inPlectonema boryanum. Can J Microbiol 20:1235–1240

    PubMed  Google Scholar 

  • Kayser H, Sperling KR (1980) Cadmium effects and accumulation in cultures ofProrocentrum micans (Dinophyta) Helgol. Wiss. Meeresunters 33:89–102

    Google Scholar 

  • Lanaras T, Codd GA (1982) Variations in ribulose 1,5-biphosphate carboxylase protein levels, activities and subcellular distribution during photoautotrophic batch culture ofChlorogloeopsis fritschi. Planta 154:284–288

    Google Scholar 

  • Les A, Walker RW (1984) Toxicity and binding of copper, zinc and cadmium by the blue-green algaChroococcus pairs. Water Air Soil Pollut 23:129–139

    Google Scholar 

  • Lawry NH, Simon RD (1982) The normal and induced occurrence of cyanophycin inclusion bodies in several blue-green algae. J Phycol 18:391–399

    Google Scholar 

  • Martin JH (1979) Bioaccumulation of heavy metals by littoral and pelagic marine organisms. EPA-60013-79-038

  • Massalski A, Laube VM, Kushner DJ (1981) Effect of cadmium and copper on the ultrastructure ofAnkistrodesmus braunii andAnabaena 7120. Microb Ecol 7:183–193

    Google Scholar 

  • Nakajima A, Horikoshi T, Sakaguchi T (1979) Uptake of copper ion by green microalgae. Agric Biol Chem 43:1455–1460

    Google Scholar 

  • Passow H, Rothstein A (1960) The binding of mercury by the yeast cell in relation to changes in permeability. J Gen Physiol 43:621–633

    PubMed  Google Scholar 

  • Rachlin JW, Jensen TE, Baxter M, Jani V (1982a) Utilization of morphometric analysis in evaluating response ofPlectonema boryanum (Cyanophyceae) to exposure to eight heavy metals. Arch Environ Contam Toxicol 11:323–333

    PubMed  Google Scholar 

  • — (1984) The toxicological response of the algaAnabaena flosaquae (Cyanophyceae) to cadmium. Arch Environ Contam Toxicol 13:143–151

    Google Scholar 

  • Rachlin JW, Warkentine B, Jensen TE (1982b) The growth response ofChlorella saccharophila, Navicula incerta andNitzschia dosterium to selected concentrations of cadmium. Bull Torrey Bot Club 109:129–135

    Google Scholar 

  • Rai LC, Gaur JP, Kumar HD (1981a) Phycology and heavy metal pollution. Biol Rev 56:99–151

    Google Scholar 

  • — (1981b) Protective effects of certain environmental factors on the toxicity of zinc, mercury and methyl mercury toChlorella vulgaris. Environ Res 25:250–259

    PubMed  Google Scholar 

  • Rai LC, Raizada M (1987) Toxicity of nickel and silver toNostoc muscorum: Interaction with ascorbic acid, glutathione and sulphur containing amino acids. Ecotoxicol Environ Safety 14:12–21

    PubMed  Google Scholar 

  • — (1988) Impact of chromium and lead onNostoc muscorum: Regulation of toxicity by ascorbic acid, glutathione and sulfurcontaining amino acids. Ecotoxicol Environ Safety 15:195–205

    PubMed  Google Scholar 

  • Rosko JJ, Rachlin JW (1975) The effect of copper, zinc, cobalt, and manganese on the growth of the marine diatomNitzschia dosterium. Bull Torrey Bot Club 102:100–105

    Google Scholar 

  • Rothstein A (1959) Cell membrane as site of action of heavy metals. Fed Proc Amer Soc Exp Biol 18:1026–1028

    Google Scholar 

  • Sakaguchi T, Tsuji T, Nakajima A, Horokoshi T (1979) Accumulation of cadmium by green microalgae. Eur J Appl Microbiol Biotechnol 81:207–215

    Google Scholar 

  • Schmitz R (1967) Uber die Zusammensetzung der pigmenthaltigen Strukturen aus Prokaryonten. I. Untersuchungen an Thylakoiden vonOscillatoria chalybea Kutz. Arch Mikrobiol 56:225–237

    Google Scholar 

  • Sela M, Tel-or E, Fritz E, Hutterman A (1988) Localization and toxic effects of cadmium, copper and uranium inAzolla. PI Physiol 88:30–36

    Google Scholar 

  • Sicko-Goad L, Stoermer EF (1979) A morphometric study of lead and copper effects onDiatoma tenue var. elongatum (Bacilllariophyta). J Phycol 15:316–321

    Google Scholar 

  • — (1988) Effects of toxicants on phytoplankton with special reference to the Laurentian great lakes. In: Evans MS (ed.) Toxic Contaminants and Ecosystem Health: A Great Lake Focus. John Wiley and Sons, NY, 19 pp

    Google Scholar 

  • Simkiss K (1979) Metal ions in cells. Endeavor 3:2–6

    Google Scholar 

  • Stokes PM (1986) Ecological effects of acidification on primary producers in aquatic systems. Water Air Soil Pollut 30:421–438

    Google Scholar 

  • Vymazal J (1987) Toxicity and accumulation of cadmium with respect to algae and cyanobacteria: a review. Toxicol Assess An Int Quat 2:387–415

    Google Scholar 

  • Whitton BA (1984) Algae as monitors of heavy metals in freshwaters. In LE Shubert (ed.) Algae as Ecological Indicators. Academic Press, NY, 257 pp

    Google Scholar 

  • Wolk CP (1973) Physiology and cytological chemistry of blue-green algae. Bacteriol Rev 37:32–101

    PubMed  Google Scholar 

  • Wong PTS, Mayfield CI, Chau YK (1980a) Cadmium toxicity to freshwater algae. Bull Environ Contam Toxicol 23:487–490

    Google Scholar 

  • — (1980b) Cadmium toxicity to phytoplankton and microorganisms. In: JO Nriagu (ed.), Cadmium in the Environment. Part I. John Wiley and Sons, NY, p 572

    Google Scholar 

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Authors and Affiliations

  1. Department of Biological Sciences, Lehman College, Bedford Park Boulevard West, 10468, Bronx, New York, USA

    L. C. Rai, Thomas E. Jensen & Joseph W. Rachlin

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  1. L. C. Rai
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  2. Thomas E. Jensen
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  3. Joseph W. Rachlin
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Rai, L.C., Jensen, T.E. & Rachlin, J.W. A morphometric and x-ray energy dispersive approach to monitoring pH-altered cadmium toxicity inAnabaena flos-aquae . Arch. Environ. Contam. Toxicol. 19, 479–487 (1990). https://doi.org/10.1007/BF01059065

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  • DOI: https://doi.org/10.1007/BF01059065

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