Transformations of arsenic in the marine environment
Tóm tắt
Từ khóa
Tài liệu tham khảo
Andreae, M.O., Arsenic speciation in seawater and interstitial waters: the influence of biological-chemical interactions on the chemistry of a trace element. Limnol. Oceanogr.24 (1979) 440–452.
Andreae, M.O., and Klumpp, D., Biosynthesis and release of organo-arsenic compounds by marine algae. Envir. Sci. Technol.13 (1979) 738–741.
Benson, A.A., Arsenic metabolism inTridacna Presented at XV Pacific Science Congress, New Zealand, February 1983.
Benson, A.A., and Summons, R.E., Arsenic accumulation in Great Barrier Reef invertebrates. Science211 (1981) 482–483.
Bisogni, J.J., Kinetics of methylmercury formation and decomposition in aquatic environments, in: The Biogeochemistry of Mercury in the Environment, pp. 211–227. Ed. J.O. Nriagu. Elsevier/North Holland, Amsterdam, New York, Oxford 1979.
Bisogni, J.J., and Lawrence, A.W., Kinetics of microbially mediated methylation of mercury in aerobic and anaerobic aquatic environments. Technical Report No. 63, Cornell University Water Resources and Marine Science Center, Ithaca, New York.
Busby, W.F., Sulfopropanediol and cysteinolic acid in the diatom. Biochim. biophys. Acta121 (1966) 160–161.
Cannon, J.R., Edmonds, J.S., Francesconi, K.A., and Langsford, J.B., Arsenic in marine fauna, in: Management and Control of Heavy Metals in the Environment, pp. 283–286. International Conference, London. CEP Consultants, Edinburgh 1979.
Cantoni, G.L., The nature of the active methyl donor formed enzymatically from L-methionine and adenosinetriphosphate. J. Am. chem. Soc.74 (1952) 2942–2943.
Challenger, F., Biological methylation. Adv. Enzym.12 (1951) 429–491.
Chapman, A.C., On the presence of compounds of arsenic in marine crustaceans and shellfish. Analyst51 (1926) 548–563.
Cooney, R.V., Mumma, R.O., and Benson, A.A., Arsoniumphospholipid in algae. Proc. natn. Acad. Sci. USA75 (1978) 4262–4264.
Cox, H.E., On certain new methods for the determination of small quantities of arsenic, and its occurrence in urine and in fish. Analyst50 (1925) 3–13.
Cullen, W.R., Froese, C.L., Lui, A., McBride, B.C., Patmore, D.J., and Reimer, M., The aerobic methylation of arsenic by microorganisms in the presence of L-methionine-methyl-d3. J. organomet. Chem.139 (1977) 61–69.
Edmonds, J.S., and Francesconi, K.A., Arseno-sugars from kelp (Ecklonia radiata) as intermediates in cycling of arsenic in a marine ecosystem. Nature289 (1981) 602–604.
Edmonds, J.S., and Francesconi, K.A., Arsenic-containing ribofuranosides: isolation from brown kelpEcklonia radiata and N.M.R. spectra. J. chem. Soc. Perkin1 (1983) 2375–2382.
Edmonds J.S., and Francesconi, K.A., Trimethylarsine oxide in estuary catfish (Cnidoglanis marcocephalus) and school whiting (Sillago bassensis) after oral administration of sodium arsenate; and as a natural component of estuary catfish. Sci. total Envir. (1987) in press.
Edmonds, J.S., and Francesconi, K.A. unpublished results.
Edmonds, J.S., Francesconi, K.A., Cannon, J.R., Raston, C.L., Skelton, B.W., and White, A.H., Isolation, crystal structure and synthesis of arsenobetaine, the arsenical constituent of the western rock lobsterPalinurus longipes cygnus George. Tetrahedron Lett. (1977) 1543–1546.
Edmonds, J.S., Francesconi, K.A., and Hansen, J.A., Dimethyloxarsylethanol from anaerobic decomposition of brown kelpEcklonia radiata: a likely precursor of arsenobetaine in marine fauna. Experientia38 (1982) 643–644.
Edmonds, J.S., Francesconi, K.A., Healy, P.C., and White, A.H., Isolation and crystal structure of an arsenic-containing sugar sulphate from the kidney of the giant clamTridacna maxima. X-ray crystal structure of (2S)-3-[5-deoxy-5-(dimethylarsinoyl)-β-D ribofuranosyloxyl]-2-hydroxypropyl hydrogen sulphate. J. chem. Soc. Perkin1 (1982) 2989–2993.
Edmonds, J.S., Morita, M., and Shibata, Y., The isolation and identification of arsenic-containing ribofuranosides and inorganic arsenic from Japanese edible seaweedHizikia fusiforme. J. chem. Soc. Perkin1 (1987) in press.
Fagerström, T., and Jernelöv, A., Biological methylation of mercury, food chain accumulation, ecological effects and routes of exposure to man. CRC Crit. Rev. envir. Control4 (1974) 296–314.
Fowler, S.W., and Ünlü, M.Y., Factors affecting bioaccumulation and elimination of arsenic in the shrimp (Lysmata seticaudata). Chemosphere7 (1978) 711–720.
GESAMP Working Group on Review of Potentially Harmful Substances. Hazard Evaluation for Arsenic. World Health Organisation, Geneva, in press.
Jongen, W.M.F., Cardinaals, J.M., Bos, P.M.J., and Hagel, P., Genotoxicity testing of arsenobetaine, the predominant form of arsenic in marine fishery products. Fd chem. Toxic.23 (1985) 669–674.
Klumpp, D.W., Characteristics of arsenic accumulation by the sea-weedsFucus spiralis andAscophyllum nodosum. Mar. Biol.58 (1980) 257–264.
Klumpp, D.W., Accumulation of arsenic from water and food byLittorina littoralis andNucella lapillus. Mar. Biol.58 (1980) 265–274.
Klumpp, D.W., and Peterson, P.J., Chemical characteristics of arsenic in a marine food chain. Mar. Biol.62 (1981) 297–305.
Lawrence, J.F., Michalik, P., Tam, G., and Conacher, H.B.S., Identification of arsenobetaine and arsenocholine in Canadian fish and shellfish by high-performance liquid chromatography with atomic absorption detection and confirmation by fast atom bombardment mass spectrometry. J. agric. Fd Chem.34 (1986) 315–319.
Lindgren, A., Vahter, M. and Dencker L., Autoradiographic studies on the distribution of arsenic in mice and hamsters administered74As-arsenite or arsenate. Pharmac. Toxic.51 (1982) 253–265.
Norin, H., and Christakopoulos, A., Evidence for the presence of arsenobetaine and another organoarsenical in shrimps. Chemosphere11 (1982) 287–298.
Norin, H., Ryhage, R., Christakopoulos, A., and Sandström, M., New evidence for the presence of arsenocholine in shrimps (Pandalus borealis) by use of pyrolysis gas chromatography-atomic absorption spectrometry/mass spectrometry. Chemosphere12 (1983) 299–315.
Olson, B.H., and Cooper, R.C., Comparison of aerobic and anaerobic methylation of mercuric chloride by San Francisco Bay sediments. Wat. Res.10 (1976) 113–116.
Pentreath, R.J., The accumulation of arsenic by the plaice and thornback ray: some preliminary observations. Int. Council Exploration of the Sea, CM 1977/E: 17 (1977).
Phillips, D.J.H., and Depledge, M.H., Metabolic pathways involving arsenic in marine organisms: a unifying hypothesis. Mar. envir. Res.17 (1985) 1–12.
Sanders, J.G., The concentration and speciation of arsenic in marine macro-algae. Estuar. Coast. mar. Sci.9 (1979) 95–99.
Schreiber, W., Mercury content of fishery products: data from the last decade. Sci. total Envir.31 (1983) 283–300.
Summons, R.E., Woolias, M., and Wild, S.B., Synthesis of β-trimethylarsonium lactate. Phosphorus Sulfur13 (1982) 133–134.
Vahter, M., Biotransformation of trivalent and pentavalent inorganic arsenic in mice and rats. Envir. Res.25 (1981) 286–293.
Vahter, M., and Marafante, E., Intracellular interaction and metabolic fate of arsenite and arsenate in mice and rabbits. Chem. biol. Interact.47 (1983) 29–44.
Vahter, M., and Norin, H., Metabolism of74As-labelled trivalent and pentavalent inorganic arsenic in mice. Envir. Res.21 (1980) 446–457.
Vahter, M., Marafante, E., Lindgren, A., and Dencker, L., Tissue distribution and subcellular binding of arsenic in marmoset monkeys after injection of74As-arsenite. Archs Toxic51 (1982) 65–77.
Vahter, M., Marafante, E., and Dencker, L. Metabolism of arsenobetaine in mice, rats and rabbits. Sci. total Envir.30 (1983) 197–211.
Welch, A.D., and Landau, R.L., The arsenic analogue of choline as a component of lecithin in rats fed arsenocholine chloride. J. biol. Chem.144 (1942) 581–588.
Welch, A.D., and Welch, M.S., Lipotropic action of certain compounds related to choline chloride. Proc. Soc. exp. Biol. Med.39 (1938) 7–9.
Yamauchi, H., and Yamamura, Y., Dynamic change of inorganic arsenic and methylarsenic compounds in human urine after oral intake of arsenic trioxide. Industr. Hlth17 (1979) 79–83.
Yamauchi, H., and Yamamura, Y., Metabolism and excretion of orally administered dimethylarsinic acid in the hamster. Toxic. appl. Pharmac.74 (1984) 134–140.