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Life in the Open Ocean. Joseph J. Torres
Читать онлайн.Название Life in the Open Ocean
Год выпуска 0
isbn 9781119840312
Автор произведения Joseph J. Torres
Жанр Биология
Издательство John Wiley & Sons Limited
44 Longhurst, A.R. (1998). Ecological Geography of the Sea. London: Academic Press.
45 Madan, J.J. and Wells, M.J. (1996). Why squid breathe easy. Nature 380: 590.
46 Meek, R.P. and Childress, J.J. (1973). Respiration and the effect of pressure in the pelagic fish Anoplogaster cornuta (Beryciformes). Deep‐Sea Research 20: 1111–1118.
47 Menzies, R.J. and Wilson, J.B. (1961). Preliminary field experiments on the relative importance of pressure and temperature on the penetration of marine invertebrates into the deep‐sea. Oikos 12: 302–309.
48 Murray, C.N. and Riley, J.P. (1969). The solubility of gases in distilled water and sea water‐II. Oxygen. Deep‐Sea Research 16: 311–320.
49 Napora, T.A. (1964). The effect of hydrostatic pressure on the prawn, Systellaspis debilis. Narragansett Marine Laboratory Occasional Publication 2: 92–94.
50 Newell, R.C. and Northcroft, H.R. (1967). Metabolic independence of temperature over limited ranges in poikilotherms. Journal of Zoology 151: 277–298.
51 Place, A.R. and Powers, D.A. (1979). Genetic variation and relative catalytic efficiencies: lactate dehydrogenase B allozymes of Fundulus heteroclitus. Proceedings of the National Academy of Sciences USA 76: 2354–2358.
52 Precht, H. (1958). Theory of temperature adaptation in cold‐blooded animals. In: Physiological Adaptation (ed. C.L. Prosser). Washington, DC: American Physiological Society.
53 Prosser, C.L. (1973). Comparative Animal Physiology. Philadelphia: Saunders.
54 Quetin, L.B. and Childress, J.J. (1976). Respiratory adaptations of Pleuroncodes planipes Stimpson to its environment off Baja California. Marine Biology 38: 327–334.
55 Rabalais, N.N., Wiseman, W.J., and Turner, R.E. (1994). Comparison of continuous records of near‐bottom dissolved oxygen from the hypoxia zone along the Louisiana coast. Estuaries 17: 850–861.
56 Regnard, P. (1884). Effect des hautes pressions sur les animaux marins. Comptes Rendus des Séances et Memoires de la Societe de Biologie 36: 394–395.
57 Regnard, P. (1891). Recherches experimentales sur les conditions physiques de la vie dans les eaux. Paris: Masson.
58 Sanders, N.K. and Childress, J.J. (1990). Adaptations to the deep‐sea oxygen minimum layer: oxygen binding by the hemocyanin of the bathypelagic mysid, Gnathophausia ingens Dohrn. Biological Bulletin 178: 286–294.
59 Scholander, P.F., Flagg, W., Walter, V., and Irving, L. (1953). Climatic adaptation in arctic and tropical poikilotherms. Physiological Zoology 26: 67–92.
60 Seibel, B.A. (2011). Critical oxygen levels and metabolic suppression in oceanic oxygen minimum zones. Journal of Experimental Biology 214: 326–336.
61 Seibel, B.A. and Drazen, J.C. (2007). The rate of metabolism in marine animals: environmental constraints, ecological demands and energetic opportunities. Philosophical Transactions of the Royal Society B 362: 1–18.
62 Seibel, B.A., Thuesen, E.V., Childress, J.J., and Gorodezky, L.A. (1997). Decline in pelagic cephalopod metabolism with habitat depth reflects differences in locomotory efficiency. Biological Bulletin 192: 262–278.
63 Seibel, B.A., Chausson, F., Lallier, F.H. et al. (1999). Vampire blood: respiratory physiology of the vampire squid (Cephalopoda:Vampyromorpha) in relation to the oxygen minimum layer. Experimental Biology Online 4: 1–10.
64 Seibel, B.A., Schneider, J.L., Kaartvedt, S. et al. (2016). Hypoxia tolerance and metabolic suppression in oxygen minimum zone euphausiids: implications for ocean deoxygenation and biogeochemical cycles. Integrative and Comparative Biology 56: 510–523.
65 Sidell, B.D., Wilson, F.R., Hazel, J., and Prosser, C.L. (1973). Time course of thermal acclimation in goldfish. Journal of Comparative Physiology 84: 119–127.
66 Siebenaller, J.F. and Somero, G.N. (1979). Pressure adaptive differences in the binding properties of the muscle‐type (M4) lactate dehydrogenases of shallow‐ and deep‐living marine fishes. Journal of Comparative Physiology 129: 295–300.
67 Smith, K.L. and Brown, N.O. (1983). Oxygen consumption of pelagic juveniles and demersal adults of the deep‐sea fish Sebastolobus altivelis, measured at depth. Science 184: 72–73.
68 Smith, D.A., Hofmann, E.E., Klinck, J.M., and Lascara, C.M. (1999). Hydrography and circulation of the West Antarctic Peninsula continental shelf. Deep Sea Research, Part I 46: 925–949.
69 Somero, G.N. (1975). The role of isozymes in adaptation to varying temperatures. In: Isozymes II: Physiological Function (ed. C.L. Markert). New York: Academic Press.
70 Somero, G.N. and Siebenaller, J.F. (1979). Inefficient lactate dehydrogenases of deep‐sea fishes. Nature 282: 100–102.
71 Spyropoulos (1957). Response of single nerve fibers at different hydrostatic pressures. American Journal of Physiology 189: 214–218.
72 Sverdrup, H.U., Johnson, M.W., and Fleming, R.H. (1942). The Oceans, Their Physics, Chemistry, and General Biology. Englewood Cliffs: Prentice‐Hall.
73 Teal, J.M. (1971). Pressure effects of the respiration of vertically migrating decapod Crustacea. American Zoologist 11: 571–576.
74 Teal, J.M. and Carey, F.G. (1967). Effects of pressure and temperature on the respiration of euphausiids. Deep‐Sea Research 14: 725–733.
75 Torres, J.J. and Somero, G.N. (1988). Metabolism, enzymic activities, and cold adaptation in Antarctic mesopelagic fishes. Marine Biology 98: 169–180.
76 Torres, J.J., Belman, B.W., and Childress, J.J. (1979). Oxygen consumption rates of midwater fishes as a function of depth of occurrence. Deep‐Sea Research 26: 185–197.
77 Torres, J.J., Aarset, A.V., Donnelly, J. et al. (1994). Metabolism of Antarctic micronektonic Crustacea as a function of depth of occurrence and season. Marine Ecology Progress Series 113: 207–219.
78 Vinogradov, M.E. (1970). Vertical Distribution of the Oceanic Zooplankton. Jerusalem: Israel program for scientific translations.
79 Wells, M.J. and Wells, J. (1983). The circulatory response to acute hypoxia in Octopus. Journal of Experimental Biology 104: 59–71.
80 Wells, M.J., Wells, J., and O’dor, R.K. (1992). Life at low oxygen tensions: the behavior and physiology of Nautilus pompilius and the biology of extinct forms. Journal of the Marine Biological Association of the United Kingdom 72: 313–328.
81 Winberg, G.G. (1956). Rate of Metabolism and Food Requirements of Fishes. Dartmouth, Nova Scotia: Fisheries Research Board of Canada.
82 Wishner, K.F., Gowing, M.M., and Gelfman, C. (2000). Living in suboxia: ecology of an Arabian Sea copepod. Limnology and Oceanography 45: 1576–1593.
83 Withers, P.C. (1992). Comparative Animal Physiology. Orlando: Saunders.
84 Wohlschlag, D.E. (1960). Metabolism of an Antarctic fish and the phenomenon of cold adaptation. Ecology 41: 287–292.
3 The Cnidaria
Introduction
The Cnidaria, or stinging jellies, include a bewildering array of groups ranging from aquarium favorites such as anemones to the infamous Portuguese man‐o‐war and to reef‐building corals, deep‐dwelling sea pansies, and sea pens. The focus in this book is the cnidarians that are large floaters and weak swimmers: the jellyfishes (the medusae) and the siphonophores. Both are important groups within the polyphyletic assemblage collectively known as the macrozooplankton. In turn, macrozooplanktonic species are important elements of the pelagic community.
The pelagic Cnidaria are particularly confusing because there are two types of medusae: the smaller and less complex hydromedusae and the larger scyphomedusae. Inshore, the scyphomedusae are far more noticeable to the casual observer and are seasonally well represented by species such as the moon jelly Aurelia and the scourge of Atlantic beaches, the