Seasonal variation in the ionic and protein content of haemolymph from seven deep-sea decapod genera from the Northeast Atlantic Ocean
暂无分享,去创建一个
[1] Bruce H. Robison,et al. Deep pelagic biology , 2004 .
[2] P. Sarradin,et al. Respiratory adaptations to the deep-sea hydrothermal vent environment: the case of Segonzacia mesatlantica, a crab from the Mid-Atlantic Ridge. , 2004, Micron.
[3] P. Sarradin,et al. Heat-shock response and temperature resistance in the deep-sea vent shrimp Rimicaris exoculata , 2003, Journal of Experimental Biology.
[4] P. Sarradin,et al. Metal bioaccumulation and storage forms in the shrimp, Rimicaris exoculata, from the Rainbow hydrothermal field (Mid-Atlantic Ridge); preliminary approach to the fluid-organism relationship , 2002 .
[5] P. Sarradin,et al. Structural and functional properties of hemocyanin from Cyanagraea praedator, a deep‐sea hydrothermal vent crab , 2001, Proteins.
[6] S. Baden,et al. Environmental hypoxia and haemocyanin between-individual variability in Norway lobsters Nephrops norvegicus (L.) , 2001 .
[7] H. Pörtner,et al. Temperature Effects on Hemocyanin Oxygen Binding in an Antarctic Cephalopod , 2001, The Biological Bulletin.
[8] H. Pörtner,et al. Haemolymph Mg(2+) regulation in decapod crustaceans: physiological correlates and ecological consequences in polar areas. , 2000, The Journal of experimental biology.
[9] R. Kaufmann,et al. Deep-sea epibenthic echinoderms and a temporally varying food supply: results from a one year time series in the N.E. Pacific , 1998 .
[10] F. Lallier,et al. Hemocyanin oxygen-binding properties of a deep-sea hydrothermal vent shrimp: Evidence for a novel cofactor , 1997 .
[11] J. Childress. Are there physiological and biochemical adaptations of metabolism in deep-sea animals? , 1995, Trends in ecology & evolution.
[12] D. Ainley,et al. Metabolism of Antarctic Micronektonic Crustacea as a Function of Depth of Occurrence and Season , 1994 .
[13] A. L. Rice,et al. The Institute Of Oceanographic Sciences Biology Programme In The Porcupine Seabight: Background And General Introduction , 1991, Journal of the Marine Biological Association of the United Kingdom.
[14] J. Childress,et al. A Comparison of the Respiratory Function of the Haemocyanins of Vertically Migrating and Non-Migrating Pelagic, Deep-Sea Oplophorid) Shrimps , 1990 .
[15] T. J. Mickel,et al. Metabolic rates of benthic deep-sea decapod crustaceans decline with increasing depth primarily due to the decline in temperature , 1990 .
[16] R. Rosenberg,et al. Effects of oxygen depletion on the ecology, blood physiology and fishery of the Norway lobster Nephrops norvegicus (L.) , 1990 .
[17] C. Hemleben,et al. Phytodetritus on the deep-sea floor in a central oceanic region of the Northeast Atlantic , 1989 .
[18] J. Childress,et al. Ion Replacement as a Buoyancy Mechanism in a Pelagic Deep-Sea Crustacean , 1988 .
[19] A. Gooday. A response by benthic Foraminifera to the deposition of phytodetritus in the deep sea , 1988, Nature.
[20] J. Childress,et al. Oxygen binding characteristics of the hemocyanins of two deep-sea hydrothermal vent crustaceans. , 1988, Respiration physiology.
[21] G. Somero,et al. Sulfide Detoxification by the Hydrothermal Vent Crab Bythograea thermydron and Other Decapod Crustaceans , 1987, Physiological Zoology.
[22] A. L. Rice,et al. Seasonal deposition of phytodetritus to the deep-sea floor , 1986 .
[23] R. Lampitt. Evidence for the seasonal deposition of detritus to the deep-sea floor and its subsequent resuspension , 1985 .
[24] J. Childress,et al. Oxygen-Binding Properties of the Blood of the Deep-Sea Shrimp Glyphocrangon vicaria , 1985, Physiological Zoology.
[25] W. Ghidalia. 5 – Structural and Biological Aspects of Pigments , 1985 .
[26] L. Hagerman. Haemocyanin concentration of juvenile lobsters (Homarus gammarus) in relation to moulting cycle and feeding conditions , 1983 .
[27] A. L. Rice,et al. Seasonal sedimentation of phytoplankton to the deep-sea benthos , 1983, Nature.
[28] L. Mantel,et al. Osmotic and ionic regulation , 1983 .
[29] T. J. Mickel,et al. Effects of Temperature, Pressure, and Oxygen Concentration on the Oxygen Consumption Rate of the Hydrothermal Vent Crab Bythograea thermydron (Brachyura) , 1982, Physiological Zoology.
[30] T. J. Mickel,et al. EFFECTS OF PRESSURE AND TEMPERATURE ON THE EKG AND HEART RATE OF THE HYDROTHERMAL VENT CRAB BYTHOGRAEA THERMYDRON (BRACHYURA) , 1982 .
[31] D. Bliss. The Biology of Crustacea , 1982 .
[32] J. Childress,et al. Functional Characteristics of the Blood of the Deep-Sea Hydrothermal Vent Brachyuran Crab , 1981, Science.
[33] J. Childress,et al. Blood function in the hydrothermal vent vestimentiferan tube worm. , 1981, Science.
[34] J. Childress. Effects of pressure, temperature and oxygen on the oxygen consumption rate of the Midwater copepod Gaussia princeps , 1976 .
[35] J. Childress. The respiratory rates of midwater crustaceans as a function of depth of occurrence and relation to the oxygen minimum layer off Southern California. , 1975, Comparative biochemistry and physiology. A, Comparative physiology.
[36] J. Childress,et al. Chemical composition and buoyancy of midwater crustaceans as function of depth of occurrence off Southern California , 1974 .
[37] K. Smith,et al. Respiration of Benthopelagic Fishes: In situ Measurements at 1230 Meters , 1974, Science.
[38] P. Mill. Respiration in the Invertebrates , 1972 .
[39] K. Nickerson,et al. A comparison of molluscan and arthropod hemocyanin—I. Circular dichroism and absorption spectra , 1971 .
[40] J. Childress. RESPIRATORY RATE AND DEPTH OF OCCURRENCE OF MIDWATER ANIMALS1 , 1971 .
[41] J. Djangmah. The effects of feeding and starvation on copper in the blood and hepatopancreas, and on blood proteins of crangon vulgaris (fabricius) , 1970 .
[42] R. Uglow. Haemolymph protein concentrations in portunid crabs—II. The effects of imposed fasting on Carcinus maenas , 1969 .
[43] Joel W. Hedgpeth,et al. The physiology of Crustacea , 1962 .
[44] J. Robertson. Ionic regulation in some marine invertebrates. , 1949, The Journal of experimental biology.