Abe, F. and Horikoshi, K. (2001). The biotechnological potential of piezophiles. Trends in Biotechnology, 19(3), 102–108.CrossRefGoogle ScholarPubMed

Abdel-Mageed, W.M,. Milne, B.F., Wagner, M. et al. (2010). Dermacozines, a new phenazine family from deep-sea dermacocci isolated from Mariana Trench sediment. Organic and Biomolecular Chemistry, 8(10), 2352–2362.CrossRefGoogle ScholarPubMed

Aertsen, A., Meersman, F., Hendrickx, M.E., Vogel, R.F. and Michiels, C.W. (2009). Biotechnology under high pressure: applications and implications. Trends in Biotechnology, 27(7), 434–441.CrossRefGoogle ScholarPubMed

Agassiz, A. and Mayer, A.G. (1902). Reports on the scientific results of the expedition to the tropical Pacific in charge of Alexander Agassiz by the US Fish Commission steamer Albatross from August 1899 to March 1900. III. The Medusae, Memoirs of the Museum of Comparative Zoology at Harvard College, 26, 139–176.Google Scholar

Aguilar, A., Ingemansson, T. and Magnien, E. (1998). Extremophile microorganisms as cell factories: support from the European Union. Extremophiles, 2, 367–373.CrossRefGoogle ScholarPubMed

Aguzzi, J., Jamieson, A.J., Fujii, T. et al. (2012). Shifting feeding behaviour of deep-sea buccinid gastropods at natural and simulated food falls. Marine Ecology Progress Series, 458, 247–253.CrossRefGoogle Scholar

Akimoto, K., Hattori, M., Uematsu, K. and Kato, C. (2001). The deepest living Foraminifera, Challenger Deep, Mariana Trench. Marine Micropaleontology, 42, 95–97.CrossRefGoogle Scholar

Albertelli, G., Amaud, P.M., Della Croce, N., Drago, N. and Elefteriou, A. (1992). The deep Mediterranean macrofauna caught by traps and its trophic significance. Comptes Rendus de l’Academie des Sciences, 315(111), 139–144.Google Scholar

Alexander, D.E. (1988). Kinematics of swimming in two species of Idotea (Isopoda: Valvifera). Journal of Experimental Biology, 138, 37–49.Google Scholar

Allen, M.J. and Jaspars, M. (2009). Realizing the potential of marine biotechnology: challenges and opportunities. Industrial Biotechnology, 5(2), 77–83.CrossRefGoogle Scholar

Allwood, A., Beaty, D., Bass, D. et al. (2013). Conference summary: life detection in extraterrestrial samples. Astrobiology, 13(2), 203–216.CrossRefGoogle ScholarPubMed

Amils, R., Blix, A., Danson, M. et al. (2007). Investigating life in extreme environments: a European perspective. European Science Foundation Position Paper.

Amstutz, A. (1951). Sur l’e´volution des structures alpines. Archive Des Sciences, 4, 323–329.Google Scholar

Anderson, M.E., Crabtree, R.E., Carter, H.J., Sulak, K.J. and Richardson, M.D. (1985). Distribution of demersal fishes of the Caribbean Sea found below 2000 meters. Bulletin of Marine Science, 37, 794–807.Google Scholar

Ando, M., Ishida, M., Nishikawa, Y., Mizuki, C. and Hayashi, Y. (2012). What caused a large number of fatalities in the Tohoko earthquake?Geophysical Research Abstracts, 14, EGU2012–5501–1.Google Scholar

Andriashev, A.P. (1953). Archaic deep-sea and secondary deep sea-fishes and their role in zoogeographical analysis. Essays on the General Problems of Ichthyology, 58–64. (In Russian; translation on-line.)

Andriashev, A.P. (1955). A new fish of the snailfish family (Pisces, Liparidae) found at a depth of more than 7 kilometers. Trudy Instituta Okeanologii im. P.P. Shirshova, 12, 340–344.Google Scholar

Andriashev, A.P. and Pitruk, D.L. (1998). A review of the ultra-abyssal (hadal) genus Pseudoliparis (Scorpaeniformes, Liparidae) with a description of a new species from the Japan Trench. Voprosy Ikhtiologii, 33, 325–330.Google Scholar

Andriashev, A.P. and Stein, D.L. (1998). Review of the snailfish genus Careproctus (Liparidae, Scorpaeniformes) in Antarctic and adjacent waters. Natural History Museum of Los Angeles County Contributions in Science, 470, 1–63.Google Scholar

Angel, M.V. (1982). Ocean trench conservation. International Union for Conservation of Nature and Natural Resources. The Environmentalist, 2, 1–17.CrossRefGoogle Scholar

Anon. (1998). Executive summary. The legendary ocean: the unexplored frontier. Year of the Ocean Discussion Papers (March 1998). Silver Spring, MD: Office of the Chief Scientist, NOAA, US Department of Commerce. p. L-12.

Anon. (2007) Investigating the Oceans. London: House of Commons Science and Technology Select Committee.Google Scholar

Aono, E., Baba, T., Ara, T. et al. (2010). Complete genome sequence and comparative analysis of Shewanella violacea, a psychrophilic and piezophilic bacterium from deep sea floor sediments. Molecular BioSystems, 6, 1216–1226.CrossRefGoogle ScholarPubMed

Archer, D.E. (1996). An atlas of the distribution of calcium carbonate in sediments of the deep sea. Global Biogeochemical Cycles, 10, 159–174.CrossRefGoogle Scholar

Armstrong, J.D., Bagley, P.M. and Priede, I.G. (1992). Photographic and acoustic tracking observations of the behaviour of the grenadier Coryphaenoides (Nemotonurus) armatus, the eel Synaphobranchus bathybius, and other abyssal demersal fish in the North Atlantic Ocean. Marine Biology, 112, 535–544.CrossRefGoogle Scholar

Arnison, P.G., Bibb, M.J., Bierbaum, G. et al. (2013). Ribosomally synthesized and post-translationally modified peptide natural products: overview and recommendations for a universal nomenclature. Natural Products Report, 30(1), 108–160.CrossRefGoogle ScholarPubMed

Arrhenius, O. (1921). Species and area. Journal of Ecology, 9(1), 95–99.CrossRefGoogle Scholar

Arzola, R.G., Wynn, R.B., Lastras, G., Masson, D.G. and Weaver, P.P.E. (2008). Sedimentary features and processes in the Nazaré and Setúbal submarine canyons, west Iberian margin. Marine Geology, 250, 64–88.CrossRefGoogle Scholar

Attrill, M.J. and Rundle, S.D. (2002). Ecotone or ecocline: ecological boundaries in estuaries. Estuarine, Coastal and Shelf Science, 55(6), 929–936.CrossRefGoogle Scholar

Bacescu, M. (1971). Mysimenzies hadalis g. n. sp. n., a benthic mysid of the Peru Trench, found during cruise XI/1965 of R/V Anton Bruun (USA). Revue Roumaine de Biologie (Zoologie), 16(1), 3–8.Google Scholar

Bagley, P.M., Priede, I.G., Jamieson, A.J. et al. (2005). Lander techniques for deep ocean biological research. Underwater Technology, 26(1), 3–11.CrossRefGoogle Scholar

Bailey, D.M. and Priede, I.G. (2002). Predicting fish behaviour in response to abyssal food-falls. Marine Biology, 141(5), 831–840.CrossRefGoogle Scholar

Bailey, D.M., King, N.J. and Priede, I.G. (2007). Camera and carcasses: historical and current methods for using artificial food falls to study deep-water animals. Marine Ecology Progress Series, 350, 179–191.CrossRefGoogle Scholar

Balmaseda, M.A., Trenberth, K.E. and Källen, E. (2013). Distinctive climate signals in reanalysis of global ocean heat content. Geophysical Research Letters, 40, 1–6.CrossRefGoogle Scholar

Barker, B.A.J., Helmond, I., Bax, N.J. et al. (1999). A vessel-towed camera platform for surveying seafloor habitats of the continental shelf. Continental Shelf Research, 19, 1161–1170.CrossRefGoogle Scholar

Barnard, J.L. (1961). Gammaridean Amphipoda from depths of 400 to 6000 meters. Galathea Report, 5, 23–128.Google Scholar

Barnard, J.L. and Ingram, C.L. (1986). The supergiant amphipod, Alicella gigantea Chevreux from the North Pacific Gyre. Journal of Crustacean Bioogy, 6, 825–839.CrossRefGoogle Scholar

Barnes, D.K.A. (2002). Biodiversity: invasions by marine life on plastic debris. Nature, 416, 808–809.CrossRefGoogle ScholarPubMed

Barnett, P.R.O., Watson, J. and Connelly, D. (1984). The multiple corer for taking virtually undisturbed samples from shelf, bathyal and abyssal sediment. Oceanologica Acta, 7, 399–408.Google Scholar

Barradas-Ortiz, C., Briones-Fourzán, P. and Lozano-Álvarez, E. (2003). Seasonal reproduction and feeding ecology of giant isopods Bathynomus giganteus from the continental slope of the Yucatán peninsula. Deep-Sea Research I, 50, 495–513.CrossRefGoogle Scholar

Barry, J.P. and Hashimoto, J. (2009). Revisiting the Challenger Deep using the ROV Kaikō. Marine Technology Society Journal, 43(5), 77–78.CrossRefGoogle Scholar

Barry, J.P., Kochevar, R.E. and Baxter, C.H. (1997). The influence of pore-water chemistry and physiology in the distribution of vesicomyid clam at cold seeps in Monterey Bay: implications for patterns of chemosynthetic community organization. Limnology and Oceanography, 42, 318–328.CrossRefGoogle Scholar

Bartlett, D.H. (2002). Pressure effects on in vivo microbial processes. Biochimica et Biophysica Acta, 1595, 367–381.CrossRefGoogle ScholarPubMed

Bartlett, D.H. (2009). Microbial life in the trenches. Marine Technology Society Journal, 43(5), 129–131.CrossRefGoogle Scholar

Beaulieu, S.E. (2002). Accumulation and fate of phytodetritus on the sea floor. Oceanography and Marine Biology Annual Review, 40, 171–232.Google Scholar

Beittel, J.S. and Margesson, R. (2010). Chile earthquake: US and international response. Congressional Research Service Report for Congress, 7–5700.

Belman, B.W. and Gordon, M.S. (1979). Comparative studies on the metabolism of shallow-water and deep-sea marine fishes. 5. Effects of temperature and hydrostatic pressure on oxygen consumption in the mesopelagic Melanostigma pammelas. Marine Biology, 50, 275–281.CrossRefGoogle Scholar

Belyaev, G.M. (1966). Bottom fauna of the ultra-abyssal depths of the world ocean. Akademia Nauka SSSR, Trudy Instituta Okeanologii, 591, 1–248.Google Scholar

Belyaev, G.M. (1975). New species of holothurians of the genus Elpidia from the southern part of Atlantic Ocean. Trudy Instituta Okeanologii, 103, 259–280. (In Russian.)Google Scholar

Belyaev, G.M. (1989). Deep-sea Ocean Trenches and Their Fauna. Moscow: Nauka.Google Scholar

Berger, W.H. (1974). Deep-sea sedimentation. In The Geology of Continental Margins, ed. Burke, C.A. and Drake, C.D.. New York: Springer, pp. 213–241.CrossRefGoogle Scholar

Berger, W.H. and Wefer, G. (1996). Late Quaternary Movement of the Angola–Benguela Front: SE Atlantic, and Implications for Advection in the Equatorial Ocean. Berlin: Springer.Google Scholar

Bergmann, M. and Klages, M. (2012). Increase of litter at the Arctic deep-sea observatory HAUSGARTEN. Marine Pollution Bulletin, 64, 2734–2741.CrossRefGoogle ScholarPubMed

Bett, B.J., Vanreusal, A., Vincx, M. et al. (1994). Sampler bias in the qualitative study of deep-sea meiobenthos. Marine Ecology Progress Series, 104, 197–203.CrossRefGoogle Scholar

Bett, B.J., Malzone, M.G., Narayanaswamy, B.E. and Wigham, B.D. (2001). Temporal variability in phytodetritus and megabenthic activity at the seabed in the deep Northeast Atlantic. Progress in Oceanography, 50, 349–368.CrossRefGoogle Scholar

Bilham, R. (2009). The seismic future of cities. Bulletin of Earthquake Engineering, 7, 839–887.CrossRefGoogle Scholar

Bilham, R. (2013). Societal and observational problems in earthquake risk assessments and their delivery to those most at risk. Tectonophysics, 584, 166–173.CrossRefGoogle Scholar

Billett, D.S.M. and Hansen, B. (1982). Abyssal aggregations of Kolga hyalina Danielssen and Koren (Echinodermata: Holothurioidea) in the northeast Atlantic Ocean: a preliminary report. Deep-Sea Research A, 29(7), 799–818.CrossRefGoogle Scholar

Billett, D.S.M., Lampitt, R.S., Rice, A.L. and Mantoura, R.F.C. (1983). Seasonal sedimentation of phytoplankton to the deep-sea benthos. Nature, 302, 520–522.CrossRefGoogle Scholar

Billett, D.S.M., Bett, B.J., Rice, A.L. et al. (2001). Long-term change in the megabenthos of the Porcupine Abyssal Plain (NE Atlantic). Progress in Oceanography, 50, 325–348.CrossRefGoogle Scholar

Billett, D.S.M., Bett, B.J., Jacobs, C.L., Rouse, I.P. and Wigham, B.D. (2006). Mass deposition of jellyfish in the deep Arabian Sea. Limnology and Oceanography, 51, 2077–2083.CrossRefGoogle Scholar

Billett, D.S.M., Bett, B., Reid, W.D.K., Boorman, B. and Priede, I.G. (2010). Long-term change in the abyssal NE Atlantic: the ‘Amperima Event’ revisited. Deep-Sea Research II, 57(15), 1406–1417.CrossRefGoogle Scholar

Birstein, J.A. (1957). Certain peculiarities of the ultra-abyssal fauna as exemplified by the genus Storthyngura (Crustacea Isopoda Asellota). Zoologichesky Zhurnal, 36, 961–985. (In Russian with English summary.)Google Scholar

Birstein, J.A. (1958). Deep-sea Malacostraca of the north-western part of the Pacific Ocean, their distribution and relations. 15th International Congress of Zoology (London), 5.Google Scholar

Birstein, J.A. (1963). Deep-sea Isopod Crustaceans of the Northwestern Pacific Ocean. Moscow: Institute of Oceanology of the USSR, Nauka. (In Russian with English summary.)Google Scholar

Birstein, J.A. and Tchindonova, J.G. (1958). Glubocovodniie Mysidii severo zapadnoi ciasti Tihogo Okeana (The deep sea Mysidacea from the north-western Pacific Ocean). Trudy Instituta Okeanologii, 27, 258–355. (In Russian.)Google Scholar

Birstein, Y.A. and Vinogradov, M.E. (1955). Pelagicheskle gammaridy (Amphipoda: Gammaridea) Kurilo-Kamchatskoi padiny. Trudy Instituta Okeanologii, 12, 210–287. (In Russian.)Google Scholar

Biscaye, P.E. and Anderson, R.F. (1994). Fluxes of particulate matter on the slope of the southern Middle Atlantic Bight: SEEP-II. Deep-Sea Research II, 41, 459–510.CrossRefGoogle Scholar

Blankenship, L.E. and Levin, L.A. (2007). Extreme food webs: foraging strategies and diets of scavenging amphipods from the ocean’s deepest five kilometres. Limnology and Oceanography, 52(4), 1685–1697.CrossRefGoogle Scholar

Blankenship, L.E., Yayanos, A.A., Cadien, D.B. and Levin, L.A. (2006). Vertical zonation patterns of scavenging amphipods from the hadal zone of the Tonga and Kermadec Trenches. Deep-Sea Research I, 53, 48–61.CrossRefGoogle Scholar

Blankenship-Williams, L.E. and Levin, L.A. (2009). Living deep: a synopsis of hadal trench ecology. Marine Technology Society Journal, 43(5), 137–143.CrossRefGoogle Scholar

Blaxter, J.H.S. (1978). Baroreception. In Sensory Ecology, ed. Ali, M.A.. New York: Plenum Publishing Corporation, pp. 375–409.CrossRefGoogle Scholar

Blaxter, J.H.S. (1980). The effect of hydrostatic pressure on fishes. In Environmental Physiology of Fishes, ed. Ali, M.A.. New York: Plenum Publishing Corporation, pp. 369–386.CrossRefGoogle Scholar

Blunt, J.W., Copp, B.R., Hu, W.P. et al. (2009). Marine natural products. Natural Product Reports, 26(2), 170–244.CrossRefGoogle ScholarPubMed

Bostock, H.C., Hayward, B.W., Neil, H.L., Currie, K.I. and Dunbar, G.B. (2011). Deep-water carbonate concentrations in the southwest Pacific. Deep-Sea Research I, 58, 72–85.CrossRefGoogle Scholar

Boulègue, J., Benedetti, E.L., Dron, D., Mariotti, A. and Létolle, R. (1987). Geochemical and biogeochemical observations on the biological communities associated with fluid venting in Nankai Trough and Japan Trench subduction zones. Earth and Planetary Science Letters, 83, 343–355.CrossRefGoogle Scholar

Boutan, L. (1900). La Photographie Sous-marine et les Progrés de la Photographie. Paris: Schleicher Frères.Google Scholar

Bouvier, E.L. (1908). Crustaces decapodes (peneides) provenant des campagnes de ‘Hirondelle’ et de la ‘Princess Alice’ (1886–1907). Resultants des Campagnes Scientifiques Acomplies sur son Yacht Prince Albert I, 33, 1–122.Google Scholar

Bowen, A.D., Yoerger, D.R., Taylor, C. et al. (2008). The Nereus hybrid underwater robotic vehicle for global ocean science operations to 11,000 m depth. OCEANS ’08, IEEE/MTS Conference Proceedings, Quebec.

Bowen, A.D., Yoerger, D.R., Taylor, C. et al. (2009a). The Nereus hybrid underwater robotic vehicle. Underwater Technology, 28(3), 79–89.CrossRefGoogle Scholar

Bowen, A.D., Yoerger, D.R., Taylor, C. et al. (2009b). Field trials of the Nereus hybrid underwater robotic vehicle in the Challenger Deep of the Mariana Trench. OCEANS ’09, IEEE/MTS Conference Proceedings, Biloxi, MS.

Bowman, J.P., Gosink, J.J., McCammon, S.A. et al. (1998). Colwellia demingiae sp. nov., Colwellia hornerae sp. nov., Colwellia rossensis sp. nov. and Colwellia psychrotropica sp. nov.: psychrophilic Antarctic species with the ability to synthesize docosahexaenoic acid (22:6o3). International Journal of Systematic Bacteriology, 48, 1171–1180.CrossRefGoogle Scholar

Brady, H.B. (1884). Report on the Foraminifera dredged by H.M.S. Challenger during the years 1873–1876. Reports on the Scientific Results of the Voyage of the H.M.S. Challenger During the Years 1873–1876, Zoology, 9, 1–814.Google Scholar

Brandt, A., Malyutina, M., Borowski, C., Schriever, G. and Thiel, H. (2004). Munnopsidid isopod attracted to bait in the DISCOL area, Pacific Ocean. Mitteilungen Hamburgisches Zoologisches Museum Institut, 101, 275–279.Google Scholar

Brehan, M.K., MacDonald, A.G., Jones, G.R. and Cossins, A.R. (1992). Homeoviscous adaptation under pressure: the pressure dependence of membrane order in brain myelin membranes of deep-sea fish. Biochimica et Biophysica Acta, 1103, 317–323.CrossRefGoogle Scholar

Britton, J.C. and Morton, B. (1994). Marine carrion and scavengers, Oceanography and Marine Biology Annual Review, 32, 369–434.Google Scholar

Broecker, W.S. (1991). The Great Ocean Conveyer. Oceanography, 4(2), 79–89.CrossRefGoogle Scholar

Broecker, W.S. and Peng, T.-H. (1982). Tracers in the Sea. Palisades, New York: Eldigio Press.Google Scholar

Broecker, W.S., Takahashi, T. and Stuiver, M. (1980). Hydrography of the central Atlantic, II: waters beneath the two degree discontinuity. Deep-Sea Research, 27(6A), 397–420.CrossRefGoogle Scholar

Brown, A. and Thatje, S. (2011). Respiratory response of the deep-sea amphipod Stephonyx biscayensis indicates bathymetric range limitation by temperature and hydrostatic pressure. PLoS ONE, 6(12), e28562–[6pp].CrossRefGoogle ScholarPubMed

Brown, A.D. and Simpson, J. (1972). Water relations of sugar-tolerant yeasts: the role of intracellular polyols. Journal of General Microbiology, 72, 589–591.CrossRefGoogle ScholarPubMed

Bruun, A.F. (1956a). Animal life of the deep-sea bottom. In The Galathea Deep Sea Expedition 1950–1952, ed. Bruun, A.F., Greve, S., Mielche, H. and Spärk, R.. London: George, Allen and Unwin, pp.149–195.Google Scholar

Bruun, A.F. (1956b). The abyssal fauna: its ecology distribution and origin. Nature, 177, 1105–1108.CrossRefGoogle Scholar

Bruun, A.F. (1957). General introduction to the reports and list of deep-sea station. Galathea Report, 1, 7–48.Google Scholar

Bryden, H.L. (1973). New polynomials for thermal expansion, adiabatic temperature gradient and potential temperature of sea water. Deep-Sea Research, 20, 410–408.Google Scholar

Bucklin, A., Wilson, R.R. and Smith, K.L. (1987). Genetic differentiation of seamount and basin populations of the deep-sea amphipod Eurythenes gryllus. Deep-Sea Research, 34, 1795–1810.CrossRefGoogle Scholar

Buesseler, K.O. and Boyd, P.W. (2009). Shedding light on processes that control particle export and flux attenuation in the twilight zone of the open ocean. Limnology and Oceanography, 54, 1210–1232.CrossRefGoogle Scholar

Buesseler, K.O., Livingston, H.D., Honjo, S. et al. (1990). Scavenging and particle deposition in the southwestern Black Sea – evidence from Chernobyl radiotracers. Deep–Sea Research, 7, 413–430.CrossRefGoogle Scholar

Bühring, S.I. and Christiansen, B. (2001). Lipids in selected abyssal benthopelagic animals: links to the epipelagic zone?Progress in Oceanography, 50, 369–382.CrossRefGoogle Scholar

Burton, A. (2012). Way down deep. Frontiers in Ecology and the Environment, 10, 112.CrossRefGoogle Scholar

Cairns, S.D., Bayer, F.M. and Fautin, D.G. (2007). Galatheanthemum profundale (Anthozoa: Actinaria) in the Western Atlantic. Bulletin of Marine Science, 80(1), 191–200.Google Scholar

Caldeira, K. and Wickett, M.E. (2003). Anthropogenic carbon and ocean pH. Nature, 425, 365.CrossRefGoogle ScholarPubMed

Campenot, R.B. (1975). The effects of high hydrostatic pressure on transmission at the crustacean neuromuscular junction. Comparative Biochemistry and Physiology B, 52, 133–140.CrossRefGoogle ScholarPubMed

Canals, M., Puig, P., Durrieu de Madron, X. et al. (2006). Flushing submarine canyons. Nature, 444, 354–357.CrossRefGoogle ScholarPubMed

CAREX (2011). CAREX roadmap for research on life in extreme environment. CAREX Publication, 9, 1–48.Google Scholar

Carey, S.W. (1958). The tectonic approach to continental drift. In Continental Drift: A Symposium, ed. Carey, S.W.. Hobart: University of Tasmania, pp. 177–363.Google Scholar

Carney, R.S. (2005). Zonation of deep biota on continental margins. Oceanography and Marine Biology Annual Review, 43, 211–278.Google Scholar

Carruthers, J.N. and Lawford, A.L. (1952). The deepest oceanic sounding. Nature, 169, 601–603.CrossRefGoogle Scholar

Carter, H.J. (1983). Apagesoma edentatum, a new genus and species of Ophidiid fish from the western north Atlantic. Bulletin of Marine Science, 33, 94–101.Google Scholar

Castellini, M.A., Castellini, J.M. and Rivera, P.M. (2001). Adaptations to pressure in the RBC metabolism of diving animals. Comparative Biochemistry and Physiology A, 129, 751–757.CrossRefGoogle Scholar

Catalano, R., Yorifuji, T. and Kawachi, I. (2013). Natural selection in utero: evidence from the Great East Japan Earthquake. American Journal of Human Biology, 25, 555–559.CrossRefGoogle ScholarPubMed

Chapelle, G. and Peck, L.S. (1999). Polar gigantism dictated by oxygen availability. Nature, 399, 114–115.CrossRefGoogle Scholar

Chapelle, G. and Peck, L.S. (2004). Amphipod crustacean size spectra: new insights in the relationship between size and oxygen. Oikos, 106, 167–175.CrossRefGoogle Scholar

Charmasson, S.S. and Calmet, D.P. (1987). Distribution of scavenging Lysianassidae amphipods Eurythenes gryllus in the northeast Atlantic: comparison with studies held in the Pacific. Deep-Sea Research, 34(9), 1509–1523.CrossRefGoogle Scholar

Chastain, R.A. and Yayanos, A.A. (1991). Ultrastructural changes in an obligatory barophilic marine bacterium after decompression. Applied and Environmental Microbiology, 57(5), 1489–1497.Google Scholar

Chernova, N.V., Stein, D.L. and Andriashev, A.P. (2004). Family Liparidae Scopoli 1777, annotated checklists of fishes. California Academy of Science, 31, 1–82.Google Scholar

Chevreux, E. (1899). Sur deux espèces géantes d’amphipodes provenant des campagnes du yacht Princesse Alice. Bulletin de la Société of Zoologique de France, 24, 152–158.CrossRefGoogle Scholar

Childress, J.J. (1971). Respiratory rate and depth of occurrence of midwater animals. Limnology and Oceanogaphy, 16, 104–106.CrossRefGoogle Scholar

Childress, J.J. (1977). Effects of pressure, temperature and oxygen on the oxygen-consumption rate of the midwater copepod Gausia princeps. Marine Biology, 39, 19–24.CrossRefGoogle Scholar

Childress, J.J. (1995). Are there physiological and biochemical adaptations of metabolism in deep-sea animals?Trends in Ecology and Evolution, 10, 30–36.CrossRefGoogle ScholarPubMed

Childress, J.J. and Fisher, C. (1992). The biology of hydrothermal vent animals; physiology, biochemistry and autotrophic symbioses. Oceanography and Marine Biology Annual Review, 30, 337–442.Google Scholar

Childress, J.J. and Somero, G.N. (1979). Depth-related enzymatic activities in muscle, brain, and heart of deep-living pelagic teleosts. Marine Biology, 52, 273–283.CrossRefGoogle Scholar

Childress, J.J. and Thuesen, E.V. (1995). Metabolic potentials of deep-sea fishes: a comparative approach. In Biochemistry and Molecular Biology of Fishes, ed. Hochachka, P.W. and Mommsen, T.P.. Berlin: Elsevier Science, pp. 175–195.Google Scholar

Chiswell, S.M. and Moore, M.I. (1999). Internal tides near the Kermadec Ridge. Journal of Physical Oceanography, 29, 1019–1035.2.0.CO;2>CrossRefGoogle Scholar

Christiansen, B. and Diel-Christiansen, D. (1993). Respiration of lysianassoid amphipods in a subarctic fjord and some implications on their feeding ecology. Sarsia, 78, 9–15.CrossRefGoogle Scholar

Christiansen, B., Pfannkuche, O. and Thiel, H. (1990). Vertical distribution and population structure of the necrophagous amphipod Eurythenes gryllus in the West European basin. Marine Ecology Progress Series, 66, 35–45.CrossRefGoogle Scholar

Christiansen, B., Beckmann, W. and Weikert, H. (2001). The structure and carbon demand of the bathyal benthic boundary layer community: a comparison of two oceanic locations in the NE-Atlantic. Deep-Sea Research II, 48, 2409–2424.CrossRefGoogle Scholar

Cohen, D.M., Inada, T., Iwamoto, T. and Scialabba, N. (1990). Gadiform fishes of the world (Order Gadiformes). An annotated and illustrated catalogue of cods, hakes, grenadiers and other gadiform fishes known to date. FAO Fisheries Synopsis, 10(125), 442.Google Scholar

Collins, M.A., Priede, I.G. and Bagley, P.M. (1999). In situ comparison of activity in two deep-sea scavenging fishes occupying different depth zones. Proceedings of the Royal Society London B, 266, 2011–2016.CrossRefGoogle Scholar

Conan, G., Roux, M. and Sibuet, M. (1980). A photographic survey of a population of the stalked crinoid Diplocrinus (Annacrinus) wyvillethomsoni (Echinodermata) from the bathyal slope of the Bay of Biscay. Deep-Sea Research, 28, 441–453.CrossRefGoogle Scholar

Connerney, J.E.P., Acuna, M.H., Wasilewski, P.J. et al. (1999). Magnetic lineations in the ancient crust of Mars. Science, 284, 794–798.CrossRefGoogle ScholarPubMed

Connor, E.F. and McCoy, E.D. (1979). The statistics and biology of the species area relationship. American Naturalist, 113(6) 791–833.CrossRefGoogle Scholar

Cook-Anderson, G. and Beasley, D. (2005). NASA details earthquake effects on the Earth. NASA Press Release, 10 January 2005.

Cossins, A.R., and MacDonald, A.G. (1984). Homeoviscous theory under pressure: II. The molecular order of membranes from deep-sea fish. Biochimica et Biophysica Acta (BBA)-Biomembranes, 776(1), 144–150.CrossRefGoogle Scholar

Cossins, A.R. and MacDonald, A.G. (1989). The adaptation of biological membranes to temperature and pressure: fish from the deep and cold. Journal of Bioenergetics and Biomembranes, 21(1), 15–35.CrossRefGoogle Scholar

Cousteau, J.-Y. (1958). Calypso explores an undersea canyon. National Geographic Magazine, 113, 373–396.Google Scholar

Craig, J., Jamieson, A.J, Heger, A. and Priede, I.G. (2009). Distribution of bioluminescent organisms in the Mediterranean Sea and predicted effects on a deep-sea neutrino telescope. Nuclear Instruments and Methods in Physics Research A, 602, 224–226.CrossRefGoogle Scholar

Craig, J., Jamieson, A.J., Bagley, P.M. and Priede, I.G. (2011a). Seasonal variation of deep-sea bioluminescence in the Ionian Sea. Nuclear Instruments and Methods in Physics Research A, 626, S115–S117.CrossRefGoogle Scholar

Craig, J, Jamieson, A.J., Bagley, P.M. and Priede, I.G. (2011b). Naturally occurring bioluminescence on the deep-sea floor. Journal of Marine Systems, 88, 563–567.CrossRefGoogle Scholar

Dahl, E. (1959). Amphipoda from depths exceeding 6000 meters. Galathea Report, 1, 211–241.Google Scholar

Dahl, E. (1977). The amphipod functional model and its bearing upon systematics and phylogeny. Zoologica Scripta, 6, 221–228.CrossRefGoogle Scholar

Dahl, E. (1979). Deep-sea carrion feeding amphipods: evolutionary patterns in niche adaptation. Oikos, 33, 167–175.CrossRefGoogle Scholar

Dahlgren, T., Glover, A.G., Smith, C.R. and Baco, A. (2004). Fauna of whale falls: systematics and ecology of a new polychaete (Annelida: Chrysopetalidae) from the deep Pacific Ocean. Deep-Sea Research I, 51, 1873–1887.CrossRefGoogle Scholar

Daito, H., Suzuki, M., Shiihara, J. et al. (2012). Impact of the Tohoku earthquake and tsunami on pneumonia hospitalisations and mortality among adults in northern Miyagi, Japan: a multicentre observational study. Thorax, 68, 544–550.CrossRefGoogle Scholar

Dalsgaard, J., John, M., Kattner, G., Müller-Navarra, D. and Hagen, W. (2003). Fatty acid trophic markers in the pelagic marine environment. Advances in Marine Biology, 46, 225–340.CrossRefGoogle ScholarPubMed

Danovaro, R., Gambi, C. and Della Croce, N. (2002). Meiofauna hotspot in the Atacama Trench (Southern Pacific Ocean). Deep-Sea Research I, 49, 843–857.CrossRefGoogle Scholar

Danovaro, R., Della Croce, N., Dell’Anno, A. and Pusceddu, A. (2003). A depocenter of organic matter at 7800m depth in SE Pacific Ocean. Deep-Sea Research I, 50, 1411–1420.CrossRefGoogle Scholar

Danovaro, R., Dell’Anno, A. and Pusceddu, A. (2004). Biodiversity response to climate change in a warm deep sea. Ecology Letters, 7, 821–828.CrossRefGoogle Scholar

DaSilva, E.J. (2004). The colours of biotechnology: science, development and humankind. Electronic Journal of Biotechnology, 7(3), 01–02.Google Scholar

De Broyer, C. and Thurston, M.H. (1987). New Atlantic material and redescription of the type specimens of the giant abyssal amphipod Alicella gigantea Chevreux (Crustacea). Zoologica Scripta, 16(4), 335–350.CrossRefGoogle Scholar

De Broyer, C., Nyssen, F. and Dauby, P. (2004). The crustacean scavenger guild in Antarctic shelf, bathyal and abyssal communities. Deep-Sea Research II, 51(14–16), 1733–1752.CrossRefGoogle Scholar

De La Rocha, C.L. and Passow, U. (2007). Factors influencing the sinking of POC and the efficiency of the biological carbon pump. Deep-Sea Research I, 54, 639–658.CrossRefGoogle Scholar

De Leo, F.C., Smith, C.R., Rowden, A.A., Bowden, D.A. and Clarke, M.R. (2010). Submarine canyons: hotspots of benthic biomass and productivity in the deep sea. Proceedings of the Royal Society London B, 277, 2783–2792.CrossRefGoogle ScholarPubMed

DeLong, E.F. (1986). Adaptations of deep-sea bacteria to the abyssal environment. PhD thesis, University of California, San Diego.

DeLong, E.F. and Yayanos, A.A. (1985). Adaptation of the membrane lipids of a deep-sea bacterium to changes in hydrostatic pressure. Science, 228, 1101–1103.CrossRefGoogle ScholarPubMed

DeLong, E.F. and Yayanos, A.A. (1986). Biochemical function and ecological significance of novel bacterial lipids in deep-sea procaryotes. Applied Environmental Microbiology, 51, 730–737.Google ScholarPubMed

Demhardt, I.J. (2005). Alfred Wegener’s hypothesis on continental drift and its discussion in Petermanns Geographishe Mitteilungen (1912–1942). Polarforschung, 75, 29–35.Google Scholar

Deming, J.W., Somers, L.K., Straube, W.L., Swartz, , , D.G. and MacDonell, M.T. (1988). Isolation of an obligately barophilic bacterium and description of a new genus, Colwellia gen. nov. Systematic and Applied Microbiology, 10, 152–160.CrossRefGoogle Scholar

Denton, E.J. (1990). Light and vision at depths greater than 200 metres. In Light and Life in the Sea, ed. Herring, P.J., Campbell, A.K., Whitfield, M. and Maddock, L.. Cambridge: Cambridge University Press, pp. 127–148.Google Scholar

Deuser, W.G. and Ross, E.H. (1980). Seasonal change in the flux of organic carbon to the deep Sargasso Sea. Nature, 283, 364−365.CrossRefGoogle Scholar

Dietz, R.S. (1961). Continent and ocean basin evolution by spreading of the sea floor. Nature, 190, 854–857.CrossRefGoogle Scholar

Dobzhansky, T. (1951). Genetics and the Origin of Species, 3rd edn. New York: Columbia University Press.Google Scholar

Doebeli, M. and Dieckmann, U. (2003). Speciation along environmental gradients. Nature, 421, 259–264.CrossRefGoogle ScholarPubMed

Domanski, P. (1986). The near-bottom shrimp faunas (Decapoda: Natantia) at two abyssal sites in the Northeast Atlantic Ocean. Marine Biology, 93, 171–180.CrossRefGoogle Scholar

Drazen, J.C. and Seibel, B.A. (2007). Depth-related trends in metabolism of benthic and benthopelagic deep-sea fishes. Limnology and Oceanography, 52, 2306–2316.CrossRefGoogle Scholar

Drazen, J.C., Yeh, J., Friedman, J. and Condon, N. (2011). Metabolism and enzyme activities of hagfish from shallow and deep water of the Pacific Ocean. Comparative Biochemistry and Physiology A, 159(2), 182–187.CrossRefGoogle ScholarPubMed

Duarte, C.M., Middelburg, J.J. and Caraco, N. (2005). Major role of marine vegetation on the oceanic carbon cycle, Biogeosciences, 2(1), 1–8.CrossRefGoogle Scholar

Duineveld, G, Lavaleye, M., Berghuis, E. and de Wilde, P. (2001). Activity and composition of the benthic fauna in the Whittard Canyon and the adjacent continental slope (NE Atlantic). Oceanologica Acta, 24, 69–83.CrossRefGoogle Scholar

Dunn, D.F. (1983). Some Antarctic and Sub-Antarctic sea anemones (Coelenterata: Ptychodactiaria and Actiniaria). Antarctic Research Series, 39, 1–67.CrossRefGoogle Scholar

Eckman, J.E. and Thistle, D. (1991). Effects of flow about a biologically produced structure on harpacticoid copepods in San Diego Trough. Deep-Sea Research A, 38(11), 1397–1416.CrossRefGoogle Scholar

Eleftheriou, A. and McIntyre, A.D. (2005). Methods for the Study of the Marine Benthos. 3rd edn. Oxford: Blackwell Scientific Publications.CrossRefGoogle Scholar

Eliason, A. (1951). Polychaeta. Reports of the Swedish Deep-Sea Expedition, 2, Zoology, 11, 131–148.Google Scholar

Elliott, A.J. and Thorpe, S.A. (1983). Benthic observations on the Madeira Abyssal Plain. Oceanologica Acta, 6, 463–466.Google Scholar

Ellis-Evans, C. and Walter, N. (2008). Coordination Action for Research activities on life in EXtreme environments: the CAREX project. Journal of Biological Research-Thessaloniki, 9, 11–15.Google Scholar

Eloe, E.A., Shulse, C.N., Fadrosh, D.W. et al. (2010). Compositional differences in particle-associated and free-living microbial assemblages from an extreme deep-ocean environment. Environmental Microbiology Reports, 3(4), 449–458.CrossRefGoogle ScholarPubMed

Eloe, E.A., Malfatti, F., Gutierrez, J. et al. (2011). Isolation and characterization of a psychropiezophilic alphaproteobacterium. Applied and Environmental Microbiology, 77(22), 8145–8153.CrossRefGoogle ScholarPubMed

Emery, K.O. (1952). Submarine photography with the benthograph. Science Monthly, 75, 3–11.Google Scholar

Emery, K.O., Merrill, A.S. and Trumbull, J.V.A. (1965). Geology and biology of the sea floor as deduced from simultaneous photographs and samples. Limnology and Oceanography, 10(1), 1–21.CrossRefGoogle Scholar

Emiliani, C. (1961). The temperature decrease of surface sea-water in high latitudes and of abyssal-hadal water in open oceanic basins during the past 75 million years. Deep-Sea Research, 8(2), 144–147.CrossRefGoogle Scholar

Endo, H. and Okamura, O. (1992). New records of the abyssal grenadiers Coryphaenoides armatus. Japanese Journal of Ichthyology, 38, 433–437.Google Scholar

England, P. and Jackson, J. (2011). Uncharted seismic risk. Nature Geoscience, 4, 348–349.CrossRefGoogle Scholar

Eustace, R.M., Kilgallen, N.M., Lacey, N.C. and Jamieson, A.J. (2013). Population structure of the hadal amphipod Hirondellea gigas from the Izu-Bonin Trench (NW Pacific; 8173–9316 m). Journal of Crustacean Biology, 33(6), 793–801.CrossRefGoogle Scholar

Ewing, M. and Heezen, B.C. (1955). Puerto-Rico Trench topographic and geophysical data. Special Paper: Geological Society of America, 62, 255–267.Google Scholar

Ewing, M., Vine, A. and Worzel, J.L. (1946). Photography of the ocean bottom. Journal Optical Society of America, 36, 307–321.CrossRefGoogle Scholar

Fabiano, M., Pusceddu, A., Dell’Anno, A. et al. (2001). Fluxes of phytopigments and labile organic matter to the deep ocean in the NE Atlantic Ocean. Progress in Oceanography, 50, 89–104.CrossRefGoogle Scholar

Faccenna, C., Becker, T.W., Pio Lucente, F., Jolivet, L. and Rossetti, F. (2001). History of subduction and back-arc extension in the central Mediterranean. Geophysical Journal International, 145, 809–820.CrossRefGoogle Scholar

Fang, J. and Kato, C. (2010). Deep-sea piezophilic bacteria: geomicrobiology and biotechnology. In Geomicrobiology: Biodiversity and Biotechnology, ed. Jain, S.K., Khan, A.A. and Rai, M.K.. Boca Raton, FL: CRC Press, pp. 47–77.CrossRefGoogle Scholar

Fang, J., Barcelona, M.J., Nogi, Y. and Kato, C. (2000). Biochemical implications and geochemical significance of novel phospholipids of the extremely barophilic bacteria from the Marianas Trench at 11 000 m. Deep-Sea Research I, 47, 1173–1182.CrossRefGoogle Scholar

Feely, R.A., Sabine, C.L., Lee, K. et al. (2004). Impact of anthropogenic CO2 on the CaCO3 system in the oceans. Science, 305, 362–366.CrossRefGoogle ScholarPubMed

Fisher, C.R. (1990). Chemoautotrophic and methanotrophic symbioses in marine invertebrates. Review of Aquatic Science, 2, 399–436.Google Scholar

Fisher, R.L. (1954). On the sounding of trenches. Deep-Sea Research, 2, 48–58.CrossRefGoogle Scholar

Fisher, R.L. (2009). Meanwhile, back on the surface: further notes on the sounding of trenches. Marine Technology Society Journal, 43(5), 16–19.CrossRefGoogle Scholar

Fisher, R.L. and Hess, H.H. (1963). Trenches. In The Sea, ed. Hill, M.N.. New York: Wiley, pp. 411–436.Google Scholar

Fletcher, B., Bowen, A., Yoerger, D.R. and Whitcomb, L.L. (2009). Journey to the Challenger Deep: 50 years later with the Nereus Hybrid remotely operated vehicle. Marine Technology Society Journal, 43(5), 65–76.CrossRefGoogle Scholar

Fluery, A.G. and Drazen, J.C. (2013). Abyssal scavenging communities attracted to Sargassum and fish in the Sargasso Sea. Deep-Sea Research I, 72, 141–147.CrossRefGoogle Scholar

Fofonoff, N.P. (1977). Computation of potential temperature of seawater for an arbitrary reference pressure. Deep-Sea Research, 24, 489–491.CrossRefGoogle Scholar

Fofanoff, N.P. and Millard, R.C. (1983). Algorithms for computation of fundamental properties of seawater. UNESCO Technical Papers in Marine Science, 44, 53.Google Scholar

Forbes, E. (1844). Report on the Mollusca and Radiata of the Aegean Sea, and their distribution, considered as bearing on geology. Report (1843) to the 13th Meeting of the British Association for the Advancement of Science, pp. 30–193.

France, S.C. (1993). Geographic variation among three isolated populations of the hadal amphipod Hirondellea gigas (Crustacea: Amphipoda: Lysianassoidea). Marine Ecology Progress Series, 92, 277–287.CrossRefGoogle Scholar

France, S.C. (1994). Genetic population structure and gene flow among deep-sea amphipods, Abyssorchomene spp., from six California continental Borderland basins. Marine Biology, 118, 67–77.CrossRefGoogle Scholar

France, S.C. and Kocher, T.D. (1996). Geographic and bathymetric patterns of mitochondrial 16S rRNA sequence divergence among deep-sea amphipods, Eurythenes gryllus. Marine Biology, 126, 633–643.CrossRefGoogle Scholar

Frankenberg, D. and Menzies, R.J. (1968). Some quantitative analyses of deep-sea benthos off Peru. Deep-Sea Research, 15(5), 623–626.Google Scholar

Fraser, P.J. (2001). Statocysts in crabs: short-term control of locomotion and long-term monitoring of hydrostatic pressure. Biological Bulletin, 200, 155–159.CrossRefGoogle ScholarPubMed

Fraser, P.J. (2006). Review. Depth, navigation and orientation in crabs: angular acceleration, gravity and hydrostatic pressure sensing during path integration. Marine and Freshwater Behaviour and Physiology, 39(2), 87–97.CrossRefGoogle Scholar

Fraser, P.J. and MacDonald, A.G. (1994). Crab hydrostatic pressure sensors. Nature, 371, 383–384.CrossRefGoogle Scholar

Fraser, P.J. and Shelmerdine, R.L. (2002). Fish physiology: dogfish hair cells sense hydrostatic pressure. Nature, 415, 495–496.CrossRefGoogle ScholarPubMed

Fraser, P.J., MacDonald, A.G., Cruickshank, S.F. and Schraner, M.P. (2001). Integration of hydrostatic pressure information by identified interneurones in the crab Carcinus maenas (L.); long-term recordings. Journal of Navigation, 54, 71–79.CrossRefGoogle Scholar

Fraser, P.J., Cruickshank, S.F. and Shelmerdine, R.L. (2003). Hydrostatic pressure effects on vestibular hair cell afferents in fish and crustacea. Journal of Vestibular Research, 13, 235–242.Google ScholarPubMed

Froese, R. and Pauly, D. (2009). FishBase. Available at: . Accessed 28 August 2009.

Fryer, P., Becker, N., Applegate, B. et al. (2002). Why is Challenger Deep so deep?Earth and Planetary Science Letters, 211, 259–269.CrossRefGoogle Scholar

Forman, W. (2009). From Beebe and Barton to Piccard and Trieste. Marine Technology Society Journal, 43(5), 27–36.CrossRefGoogle Scholar

Fujii, T., Jamieson, A.J., Solan, M., Bagley, P.M. and Priede, I.G. (2010). A large aggregation of liparids at 7703 m depth and a reappraisal of the abundance and diversity of hadal fish. BioScience, 60(7), 506–515.CrossRefGoogle Scholar

Fujii, T., Kilgallen, N.M., Rowden, A.A. and Jamieson, A.J. (2013). Amphipod community structure across abyssal to hadal depths in the Peru–Chile and the Kermadec Trenches. Marine Ecology Progress Series, 492, 125–138.CrossRefGoogle Scholar

Fujikura, K., Kojima, S., Tamaki, K. et al. (1999). The deepest chemosynthesis-based community yet discovered from the hadal zone, 7326 m deep, in the Japan Trench. Marine Ecology Progess Series, 190, 17–26.CrossRefGoogle Scholar

Fujimoto, H., Fujiwara, T., Kong, L. and Igarashi, C. (1993). Sea-beam survey over the Challenger Deep, revisited. In Preliminary Report of the Hakuho-Maru Cruise (KH-92–1). Tokyo: Ocean Research Institute, University of Tokyo, pp. 26–27.Google Scholar

Fujio, S. and Yanagimoto, D. (2005). Deep current measurements at 38ºN east of Japan. Journal of Geophysical Research C, 110(C2), C02010.CrossRefGoogle Scholar

Fujio, S., Yanagimoto, D. and Taira, K. (2000). Deep current structure above the Izu-Ogasawara Trench. Journal of Geophysical Research, 105(C3), 6377–6386.CrossRefGoogle Scholar

Fujioka, K., Takeuchi, A., Horiuchi, K. et al. (1993). Constrated nature between landward and seaward slopes of the Japan Trench off Miyako, Northern Japan. Proceedings of JAMSTEC Symposium of Deep-Sea Research, 9, 1–26.Google Scholar

Fujioka, K., Okino, K., Kanamatsu, T. and Ohara, Y. (2002). Morphology and origin of the Challenger Deep in the southern Mariana Trench. Geophysical Research Letters, 19, 1–4.Google Scholar

Fujiwara, T., Kodaira, S., No, T. et al. (2011). The 2011 Tohoku-Oki earthquake: displacement reaching the trench axis. Science, 334, 1240.CrossRefGoogle ScholarPubMed

Fujiwara, Y., Dato, C., Masui, N., Fujikura, K. and Kojima, S. (2001). Dual symbiosis in the cold-seep thyasirid clam Maorithyas hadalis from the hadal zone in the Japan Trench, western Pacific. Marine Ecology Progress Series, 214, 151–159.CrossRefGoogle Scholar

Fulton, J. (1973). Some aspects of the life history of Calanus plumchrus in the Strait of Georgia. Journal of the Fisheries Research Board of Canada, 30, 811–815.CrossRefGoogle Scholar

Furlong, R.R. and Wahlquist, E.J. (1999). US space missions using radioisotope power systems. Nuclear News, April, 26–34.

Gage, J.D. (2003). Food inputs, utilization, carbon flow and energetics. In Ecosystems of the World 28, Ecosystems of the Deep Sea, ed. Tyler, P.A.. Amsterdam: Elsevier, pp. 315–382.Google Scholar

Gage, J.D. and Bett, B.J. (2005). Deep-sea benthic sampling. In Methods for the Study of the Marine Benthos, 3rd edn, ed. Eleftheriou, A. and McIntyre, A.D.. Oxford: Blackwell Scientific Publications, pp. 273–325.CrossRefGoogle Scholar

Gage, J.D. and Tyler, P.A. (1991). Deep-sea Biology: A Natural History of Organisms at the Deep-sea Floor. Cambridge: Cambridge University Press.CrossRefGoogle Scholar

Galgani, F., Leaute, J.P., Moguedet, P. et al. (2000). Litter on the sea floor along European coasts. Marine Pollution Bulletin, 40, 516.CrossRefGoogle Scholar

Gambi, C., Vanreusal, A. and Danovaro, R. (2003). Biodiversity of nematode assemblages from deep-sea sediments of the Atacama Slope and Trench (South Pacific Ocean). Deep-Sea Research I, 50, 103–117.CrossRefGoogle Scholar

Gamô, S. (1984). A new remarkably giant tanaid, Gigapseudes maximus sp.nov. (Crustacea) from abyssal depths far off southeast of Mindanao, the Philippines. Scientific Reports of Yokahoma Natural University Series, 11, 1–12.Google Scholar

Garfield, N., Rago, T.A., Schnebele, K.J. and Collins, C.A. (1994). Evidence of a turbidity current in Monterey submarine canyon associated with the 1989 Loma Prieta earthquake. Continental Shelf Research, 14, 673–686.CrossRefGoogle Scholar

Gartner, J.V. (1983). Sexual dimorphism in the bathypelagic gulper eel Eurypharynx pelecanoides (Lyomeri: Eurypharyngidae), with comments on reproductive strategy. Copia, 2, 560–563.CrossRefGoogle Scholar

Gaskell, T.F., Swallow, J.C. and Ritchie, G.S. (1953). Further notes on the greatest oceanic sounding and the topography of the Marianas Trench. Deep-Sea Research, 1, 60–63.CrossRefGoogle Scholar

Gebruk, A.V. (1993). New records of elasipodid holothurians in the Atlantic sector of Antarctic and Subantarctic. Transactions of the P.P. Shirshov Institute of Oceanology, 127, 228–244.Google Scholar

Genin, A., Dayton, P.K., Lonsdale, P.F. and Speiss, F.N. (1986). Corals on seamount peaks provide evidence of current acceleration over deep-sea topography. Nature, 323, 59–61.CrossRefGoogle Scholar

George, R.Y. (1979). What adaptive strategies promote immigration and speciation in deep-sea environments. Sarsia, 64(1–2), 61–65.CrossRefGoogle Scholar

George, R.Y. and Higgins, R.P. (1979). Eutrophic hadal benthic community in the Puerto-Rico Trench. Ambio Special Report, 6, 51–58.Google Scholar

Gerdes, D. (1990). Antarctic trials of the multi-box corer, a new device for benthos sampling. Polar Record, 26(156), 35–38.CrossRefGoogle Scholar

Giere, O. (2009). Meiobenthology, 2nd edn. Berlin: Springer.Google Scholar

Gislén, T. (1956). Crinoids from depths exceeding 6000 meters. Galathea Report, 2, 61–62.Google Scholar

Gilchrist, I. and MacDonald, A.G. (1980). Techniques for experiments with deep-sea organisms at high pressure. In Experimental Biology at Sea, ed. MacDonald, A.G. and Priede, I.G.. London: Academic Press, pp. 234–276.Google Scholar

Gillett, M.B., Suko, J.R. Santoso, F.O. and Yancey, P.H. (1997). Elevated levels of trimethylamine oxide in muscles of deep-sea gadiform teleosts: a high-pressure adaptation?Journal of Experimental Zoology, 279, 386–391.3.0.CO;2-K>CrossRefGoogle Scholar

Gillibrand, E.J.V., Jamieson, A.J., Bagley, P.M., Zuur, A.F. and Priede, I.G. (2007a). Seasonal development of a deep pelagic bioluminescent layer in the temperate northeast Atlantic Ocean. Marine Ecology Progress Series, 341, 37–44.CrossRefGoogle Scholar

Gillibrand, E.J.V., Bagley, P.M., Jamieson, A.J. et al. (2007b). Deep sea benthic bioluminescence at artificial food falls, 1000 to 4800m depth, in the Porcupine Seabight and Abyssal Plain, North East Atlantic Ocean. Marine Biology, 150, 1053–1060.CrossRefGoogle Scholar

Glover, A.G., Wiklund, H., Taboada, S. et al. (2013). Bone-eating worms from the Antarctic: the contrasting fate of whale and wood remains on the Southern Ocean seafloor. Proceedings of the Royal Society London B, 280, 20131390.CrossRefGoogle Scholar

Glud, R.N., Ståhl, H., Berg, P., Wenzhöfer, F., Oguri, K. and Kitazato, H. (2009). In situ microscale variation in distribution and consumption of O2: a case study from a deep ocean margin sediment (Sagami Bay, Japan). Limnology and Oceanography, 54(1), 1–12.CrossRefGoogle Scholar

Glud, R.N., Wenzhöfer, F., Middelboe, M. et al. (2013). High rates of microbial carbon turnover in sediments in the deepest oceanic trench on Earth. Nature Geoscience, 6, 284–288.CrossRefGoogle Scholar

Godbold, J.A., Rosenberg, R. and Solan, M. (2009). Species-specific traits rather than resource partitioning mediate diversity effects on resource use. PLoS ONE, 4, e7423.CrossRefGoogle ScholarPubMed

Godbold, J.A., Bulling, M.T. and Solan, M. (2011). Habitat structure mediates biodiversity effects on ecosystem properties. Proceedings of the Royal Society London B, 278, 1717–2510.CrossRefGoogle ScholarPubMed

Gooday, A.J., Holzmann, M., Cornelius, N. and Pawlowski, J. (2004). A new monothalamous foraminiferan from 1000–6300 m water depth in the Weddell Sea: morphological and molecular characterisation. Deep-Sea Research II, 51, 1603–1616.CrossRefGoogle Scholar

Gooday, A.J., Cedhagen, T., Kamenskaya, O.E. and Cornelius, N. (2007). The biodiversity and biogeography of komokiaceans and other enigmatic foraminiferan-like protists in the deep Southern Ocean. Deep-Sea Research II: Topical Studies in Oceanography, 54(16), 1691–1719.CrossRefGoogle Scholar

Gooday, A.J., Todo, Y., Uematsu, K. and Kitazato, H. (2008). New organic-walled Foraminifera (Protista) from the ocean’s deepest point, the Challenger Deep (western Pacific Ocean). Zoological Journal of the Linnean Society, 153, 399–423.CrossRefGoogle Scholar

Gooday, A.J., Uematsu, K., Kitazato, H., Toyofuku, T. and Young, J.R. (2010). Traces of dissolved particles, including coccoliths, in the tests of agglutinated Foraminifera from the Challenger Deep (10 897 m water depth, western equatorial Pacific). Deep-Sea Research I, 57(2), 239–247.CrossRefGoogle Scholar

Gonzalez-Leon, J.A., Acar, M.H., Ryu, S.-W., Ruzette, A.-V.J. and Mayes, A.M. (2003). Low-temperature processing of ‘baroplastics’ by pressure-induced flow. Nature, 426, 424–428.CrossRefGoogle ScholarPubMed

Gore, R.H. (1985a). Abyssobenthic and abyssopelagic penaeoidean shimp (families Aristaeidae and Penaeidae) from the Venezuela Basin, Carribean Sea. Crustaceana, 49, 119–138.CrossRefGoogle Scholar

Gore, R.H. (1985b). Bright colours in the realm of eternal light. Sea Frontiers, 31, 264–271.Google Scholar

Gould, W.J. and McKee, W.D. (1973). Vertical structure of semi-diurnal currents in the Bay of Biscay. Nature, 244, 88–91.CrossRefGoogle Scholar

Gracia, A., Ardila, N.E., Rachello, P. and Diaz, J.M. (2005). Additions to the scaphopod fauna (Mollusca: Scaphopoda) of the Colombian Caribbean. Caribbean Journal of Science, 41(2), 328–334.Google Scholar

Graeve, M., Hagen, W. and Kattner, G. (1994). Herbivorous or omnivorous? On the significance of lipid compositions as trophic markers in Antarctic copepods. Deep-Sea Research, 41, 915–924.CrossRefGoogle Scholar

Graeve, M., Kattner, G. and Piependurgo, D. (1997). Lipids in Arctic benthos: does the fatty acid and alcohol composition reflect feeding and trophic interactions?Polar Biology, 18, 53–61.CrossRefGoogle Scholar

Grimes, D.J., Singleton, F.L., Stemmler, J. et al. (1984). Microbiological effects of wastewater effluent discharge into coastal waters of Puerto Rico. Water Research, 18, 613–619.CrossRefGoogle Scholar

Guennegan, Y. and Rannou, M. (1979). Semi-diurnal rhythmic activity in deep sea benthic fishes in the Bay of Biscay. Sarsia, 64, 113–116.CrossRefGoogle Scholar

Gupta, N., Woldesenbet, E. and Sankaran, S. (2001). Studies on compression failure features in syntactic foam material. Journal of Materials Science, 36, 4485–4491.CrossRefGoogle Scholar

Haddock, S.H.D., Moline, M.A. and Case, J.F. (2010). Bioluminescence in the sea. Annual Review of Marine Science, 2, 443–493.CrossRefGoogle Scholar

Haedrich, R.L., Rowe, G.T. and Polloni, P.T. (1980). The megabenthic fauna in the deep sea south of New England, USA. Marine Biology, 57, 165–179.CrossRefGoogle Scholar

Haefner, B. (2003). Drugs from the deep: marine natural products as drug candidates. Drug Discovery Today, 8(2), 536–544.CrossRefGoogle ScholarPubMed

Hahn, J. (1950). Some aspects of deep sea underwater photography. Photographic Society of America Journal, Section B, 16(6), 27–29.Google Scholar

Hallock, Z.R. and Teague, W.J. (1996). Evidence for a North Pacific deep western boundary current. Journal of Geophysical Research, 101, 6617–6624.CrossRefGoogle Scholar

Hansen, B. (1957). Holothurioidea from depths exceeding 6000 metres. Galathea Report, 2, 33–54.Google Scholar

Hansen, B. (1972). Photographic evidence of a unique type of walking in deep-sea holothurians. Deep-Sea Research, 19, 461–462.Google Scholar

Hanson, P.P., Zenkevich, N.L., Sergeev, U.V. and Udintsev, G.B. (1959). Maximum depths of the Pacific Ocean. Priroda, 6, 84–88. (In Russian.)Google Scholar

Hardy, K., Olsson, M., Yayanos, A.A., Prsha, J. and Hagey, W. (2002). Deep ocean visualisation experimenter (DOVE): low cost 10 km camera and instrument platform. OCEANS’02 MTS/IEEE, 4, 2390–2394.CrossRefGoogle Scholar

Hargrave, B.T., Phillips, G.A., Prouse, N.J. and Cranford, P.J. (1995). Rapid digestion and assimilation of bait by the deep-sea amphipod Eurythenes gryllus. Deep-Sea Research I, 42(11/12), 1905–1921.CrossRefGoogle Scholar

Harper, A.A., MacDonald, A.G., Wardle, C.S. and Pennec, J.-P. (1987). The pressure tolerance of deep-sea fish axons: results of Challenger cruise 6B/85. Comparative Biochemistry and Physiology Part A, 88A, 647–653.CrossRefGoogle Scholar

Harrison, C.S., Hida, T.S. and Seki, M.P. (1983). Hawaiian seabird feeding ecology. Wildlife Monographs, 85, 1–71.Google Scholar

Hartmann, A.C. and Levin, L.A. (2012). Conservation concerns in the deep. Science, 336, 667–668.CrossRefGoogle ScholarPubMed

Hasegawa, M., Kurohiji, Y., Takayanagi, S., Sawadaishi, S. and Yao, M. (1986). Collection of fish and amphipoda from abyssal sea-floor at 30ºN-147ºE using traps tied to 10000m wire of research vessel. Bulletin of the Tokai Regional Fishery Research Laboratory/TOKAISUIKENHO, 119, 65–75. (In Japanese.)Google Scholar

Hashimoto, J. (1998). Onboard Report of KR98–05 Cruise in the Challenger Deep. RV KAIREI/ROV KAIKO. Yokosuka, Japan: JAMSTEC.Google Scholar

Havermans, C., Nagy, Z.T., Sonet, G., De Broyer, C. and Martin, P. (2010). Incongruence between molecular phylogeny and morphological classificationin amphipod crustaceans: a case study of Antarctic lysianassoids. Molecular Phylogenetics and Evolution, 55, 202–209.CrossRefGoogle ScholarPubMed

Hay, W.W., Sloan, J.L. and Wold, C.N. (1988). Mass/age distribution and composition of sediments on the ocean floor and the global rate of sediment subduction. Journal of Geophysical Research: Solid Earth (1978–2012), 93(B12), 14933–14940.CrossRefGoogle Scholar

Hazel, J.R. and Williams, E.E. (1990). The role of alterations in membrane lipid composition in enabling physiological adaptation of organisms to their physical environment. Progress in Lipid Research, 29, 167–227.CrossRefGoogle ScholarPubMed

Heezen, B.C. (1960). The rift in the ocean floor. Scientific American, 203(4), 98–110.CrossRefGoogle Scholar

Heezen, B.C. and Ewing, M. (1952). Turbidity currents and submarine slumps and the 1929 Grand Banks earthquake. American Journal of Science, 250, 849–878.CrossRefGoogle Scholar

Heezen, B.C. and Hollister, C.D. (1971). The Face of the Deep. Oxford: Oxford University Press.Google Scholar

Heezen, B.C. and Johnson, G.L. (1965). The South Sandwich Trench. Deep-Sea Research, 12, 185–197.Google Scholar

Heezen, B.C. and McGregor, I.D. (1973). The evolution f the Pacific. Scientific American, 229, 102–112.CrossRefGoogle Scholar

Heezen, B.C., Bunce, E.T., Hersey, J.B. and Tharp, M. (1964). Chain and Romanche fracture zones. Deep-Sea Research, 11, 11–33.Google Scholar

Henriques, C., Priede, I.G. and Bagley, P.M. (2002). Baited camera observations of deep-sea demersal fishes of the northeast Atlantic Ocean at 15–28ºN off West Africa. Marine Biology, 141, 307–314.Google Scholar

Herdman, H.F.P., Wiseman, J.D.H. and Ovey, C.D. (1956). Proposed names of features on the deep-sea floor, 3. Southern or Antarctic Ocean. Deep-Sea Research, 3, 258–261.Google Scholar

Herring, P.J. (2002). The Biology of the Deep Ocean. Oxford: Oxford University Press.Google Scholar

Hess, H.H. and Buell, H.W. (1950). The greatest depth in the oceans. Transactions of the American Geophysics Union, 31, 401–405.CrossRefGoogle Scholar

Hessler, R.R. and Jumars, P.A. (1974). Abyssal community analysis from replicate box cores in the central North Pacific. Deep-Sea Research, 21, 185–209.Google Scholar

Hessler, R.R. and Sanders, H.L. (1967). Faunal diversity in the deep-sea. Deep-Sea Research, 14, 65–78.Google Scholar

Hessler, R.R. and Strömberg, J.-O. (1989). Behavior of Janiroidean isopods (Asellota), with special reference to deep-sea genre. Sarsia, 74, 145–159.CrossRefGoogle Scholar

Hessler, R.R., Isaacs, J.D. and Mills, E.L. (1972). Giant amphipod from the abyssal Pacific Ocean. Science, 175(4022), 636–637.CrossRefGoogle ScholarPubMed

Hessler, R.R., Ingram, C.L., Yayanos, A.A. and Burnett, B.R. (1978). Scavenging amphipods from the floor of the Philippine Trench. Deep-Sea Research, 25, 1029–1047.CrossRefGoogle Scholar

HessIer, R.R., Wilson, G.D.F. and Thistle, D. (1979). The deep-sea isopods: a biogeographic and phylogenetic overview. Sarsia, 64, 67–75.CrossRefGoogle Scholar

Hinrichs, K.U. and Inagaki, F. (2012). Downsizing the deep biosphere. Science, 338(6104), 204–205.CrossRefGoogle ScholarPubMed

Hochachka, P.W. and Somero, G.N. (1984). Temperature adaptation. In Biochemical Adaptation: Mechanism and Process in Physiological Evolution. ed. Hochachka, P.W. and Somero, G.N.. Oxford: Oxford University Press, pp. 355–449.Google Scholar

Hochachka, P.W. and Somero, G.N. (2002). Biochemical Adaptation: Mechanism and Process in Physiological Evolution. Oxford: Oxford University Press.Google Scholar

Hollister, C.D. and McCave, I.N. (1984). Sedimentation under deep sea storms. Nature, 309, 220–225.CrossRefGoogle Scholar

Holt, R.D. (2010). 2020 visions: ecology. Nature, 463, 32.Google Scholar

Holzer, T.L. and Savage, J.C. (2013). Global earthquake fatalities and population. Earthquake Spectra, 29(1), 155–175.CrossRefGoogle Scholar

Honda, C.M., Kusakabe, M., Nakabayashi, S., Manganini, S.J. and Honjo, S. (1997). Change in pCO2 through biological activity in the marginal seas of the western North Pacific: the efficiency of the biological pump estimated by a sediment trap experiment. Journal of Oceanography, 53, 645–662.Google Scholar

Horibe, S. (1982). Technique and studies of marine environmental assessment. Results of tests of automatic floating deep-sea sampling device in deep water (6000 m). Biological and collecting experiments. Special Report of the Ocean Research Institute, Tokyo University, March, p. 23.

Horikoshi, K. and Bull, A.T. (2011). Prologue: definition, categories, distribution, origin and evolution, pioneering studies, and emerging fields of extremophiles. In Extremophiles Handbook, ed. Horikoshi, K., Antranikian, G., Bull, A.T., Robb, F.T. and Stetter, K.O.. London: Springer, pp. 4–14.CrossRefGoogle Scholar

Horikoshi, K. and Grant, W.D. (1998). Extremophiles. Microbial Life in Extreme Environments. New York: Wiley-Liss.Google Scholar

Horikoshi, K., Antranikian, G., Bull, A.T., Robb, F.T. and Stetter, K.O. (2011). Extremophiles Handbook. London: Springer.CrossRefGoogle Scholar

Horikoshi, M., Fujita, T. and Ohta, S. (1990). Benthic associations in bathyal and hadal depths off the Pacific coast of north eastern Japan: physiognomies and site factors. Progress in Oceanography, 24, 331–339.CrossRefGoogle Scholar

Horne, D.J. (1999). Ocean circulation modes of the Phanaerozoic: implications for the antiquity of deep-sea benthonic invertebrates. Crustaceana, 72, 999–1018.CrossRefGoogle Scholar

Hoskin, C.J., Higgie, M., McDonald, K.R. and Moritz, C. (2005). Reinforcement drives rapid allopatric speciation. Nature, 437(27), 1353–1356.CrossRefGoogle ScholarPubMed

Howell, D.G. (1989). Tectonics of Suspect Terranes: Mountain Building and Continental Growth. London: Chapman and Hall.Google Scholar

Howell, D.G. and Murray, R.W. (1986). A budget for continental growth and denudation. Science, 233(4762), 446–449.CrossRefGoogle ScholarPubMed

Hsu, K.J. (1992). Challenger at Sea: A Ship that Revolutionized Earth Science. Princeton, NJ: Princeton University Press.CrossRefGoogle Scholar

Huber, J.A., Mark Welch, D.B., Morrison, H.G. et al. (2007). Microbial population structures in the deep marine biosphere. Science, 318, 97–100.CrossRefGoogle ScholarPubMed

Hudson, I.R., Pond, D.W., Billett, D.S.M. et al. (2004). Temporal variations in fatty acid composition of deep-sea holothurians: evidence of bentho-pelagic coupling. Marine Ecology Progress Series, 281, 109–120.CrossRefGoogle Scholar

Humphris, S.E. (2010). Vehicles for deep sea exploration. In Marine Ecological Processes: A Derivative of the Encyclopedia of Ocean Sciences, ed. Steele, J.H., Thorpe, S.A. and Turekian, K.K.. London: Academic Press, pp. 197–209.Google Scholar

Hydrographic Department, Japan Marine Safety Agency (1984). Mariana Trench survey by the ‘Takuyo’. International Hydrographic Bulletin, 351–352.

Imai, E., Honda, H., Hatori, K., Brack, A. and Matsuno, K. (1999). Elongation of oligopeptides in a simulated submarine hydrothermal system. Science, 283, 831–833.CrossRefGoogle Scholar

Ingram, C.L. and Hessler, R.R. (1983). Distribution and behavior of scavenging amphipods from the central North Pacific. Deep-Sea Research, 30(7A), 683–706.CrossRefGoogle Scholar

Ingram, C.L. and Hessler, R.R. (1987). Population biology of the deep-sea amphipod Eurythenes gryllus inferences from instar analyses. Deep-Sea Research A, 34(12) 1889–1910.CrossRefGoogle Scholar

Isaacs, J.D. and Schick, G.B. (1960). Deep-sea free instrument vehicle. Deep-Sea Research, 7(1), 61–67.CrossRefGoogle Scholar

Isaacs, J.D. and Schwartzlose, R.A. (1975). Active animals of the deep sea floor. Scientific American, 233(4), 84–91.CrossRefGoogle Scholar

Itoh, K., Inoue, T., Tahara, J. et al. (2008). Sea trials of the new ROV ABISMO to explore the deepest parts of oceans. Proceedings of the Eighth ISOPE Pacific/Asia Offshore Mechanics Symposium.

Itou, M., Matsumura, I. and Noriki, S. (2000). A large flux of particulate matter in the deep Japan Trench observed just after the 1994 Sanriku-Oki earthquake. Deep-Sea Research I, 47, 1987–1998.CrossRefGoogle Scholar

Itoh, M., Kawamura, K., Kitahashi, T. et al. (2011). Bathymetric patterns of meiofaunal abundance and biomass associated with the Kuril and Ryukyu trenches, western North Pacific Ocean. Deep-Sea Research, 58, 86–97.CrossRefGoogle Scholar

Ivanov, A.V. (1963). Vertical and geographical dissemination of Pogonophora. Proceedings of the XVI International Congress on Zoology, Washington, DC, 1, 97.Google Scholar

Iwamoto, T. and Stein, D.L. (1974). A systematic review of the rattail fishes (Macrouridae: Gadiformes) from Oregon and adjacent waters. Occasional Papers of the California Academy of Sciences, 111, 1–79.CrossRefGoogle Scholar

Jacobs, D.K. and Lindberg, D.R. (1998). Oxygen and evolutionary patterns in the sea: onshore/offshore trends and recent recruitment of deep-sea faunas. Proceedings of the National Academy of Sciences, USA, 95, 9396–9401.CrossRefGoogle ScholarPubMed

Jamieson, A.J. and Fujii, T. (2011). Trench connection. Biology Letters, 7, 641–643.CrossRefGoogle ScholarPubMed

Jamieson, A.J. and Yancey, P.H. (2012). On the validity of the Trieste flatfish; dispelling the myth. Biological Bulletin, 222, 171–175.CrossRefGoogle ScholarPubMed

Jamieson, A.J., Fujii, T., Solan, M. et al. (2009a). Liparid and Macrourid fishes of the hadal zone: in situ observations of activity and feeding behaviour. Proceedings of the Royal Society of London B, 276, 1037–1045.CrossRefGoogle ScholarPubMed

Jamieson, A.J., Fujii, T., Solan, M. et al. (2009b). First findings of decapod crustacea in the hadal-zone. Deep-Sea Research I, 56, 641–647.CrossRefGoogle Scholar

Jamieson, A.J., Fujii, T., Solan, M. and Priede, I.G. (2009c). HADEEP: free-falling landers to the deepest places on Earth. Marine Technology Society Journal, 43(5), 151–159.CrossRefGoogle Scholar

Jamieson, A.J., Solan, M. and Fujii, T. (2009d). Imaging deep-sea life beyond the abyssal zone. Sea Technology, 50(3), 41–46.Google Scholar

Jamieson, A.J., Fujii, T., Mayor, D.J., Solan, M. and Priede, I.G. (2010). Hadal trenches: the ecology of the deepest places on Earth. Trends in Ecology and Evolution, 25(3), 190–197.CrossRefGoogle ScholarPubMed

Jamieson, A.J., Kilgallen, N.M., Rowden, A.A. et al. (2011a). Bait-attending fauna of the Kermadec Trench, SW Pacific Ocean: evidence for an ecotone across the abyssal-hadal transition zone. Deep-Sea Research I, 58, 49–62.CrossRefGoogle Scholar

Jamieson, A.J., Gebruk, A., Fujii, T. and Solan, M. (2011b). Functional effects of the hadal sea cucumber Elpidia atakama (Holothuroidea, Elasipodida) reflect small-scale patterns of resource availability. Marine Biology, 158(12), 2695–2703.CrossRefGoogle Scholar

Jamieson, A.J., Fujii, T., Bagley, P.M. and Priede, I.G. (2011c). The scavenging dependency of the deepwater eel Synaphobranchus kaupii on the Portuguese dogfish Centroscymnus coelolepis. Journal of Fish Biology, 79, 205–216.CrossRefGoogle Scholar

Jamieson, A.J., Lörz, A.-N., Fujii, T. and Priede, I.G. (2012a). In situ observations of trophic behaviour and locomotion of Princaxelia amphipods (Crustacea, Pardaliscidae) at hadal depths in four West Pacific trenches. Journal of the Marine Biology Association of the United Kingdom, 91(1), 143–150.Google Scholar

Jamieson, A.J., Fujii, T. and Priede, I.G. (2012b). Locomotory activity and feeding strategy of the hadal munnopsid isopod Rectisura cf. herculea (Crustacea: Asellota) in the Japan Trench. Journal of Experimental Biology, 215, 3010–3017.CrossRefGoogle ScholarPubMed

Jamieson, A.J., Priede, I.G. and Craig, J. (2012c). Distinguishing between the abyssal macrourids Coryphaenoides yaquinae and C. armatus from in situ photography. Deep-Sea Research I, 64, 78–85.CrossRefGoogle Scholar

Jamieson, A.J., Lacey, N.C., Lörz, A.-N., Rowden, A.A. and Piertney, S.B. (2013). The supergiant amphipod Alicella gigantea (Crustacea: Alicellidae) from hadal depths in the Kermadec Trench, SW Pacific Ocean. Deep-Sea Research II. 92, 107–113.CrossRefGoogle Scholar

Jannasch, H.W. and Taylor, C.D. (1984). Deep-sea microbiology. Annual Review of Microbiology, 38, 487–514.CrossRefGoogle ScholarPubMed

Janβen, F., Treude, T. and Witte, U. (2000). Scavenger assembleges under differing trophic conditions: a case study in the deep Arabian Sea. Deep-Sea Research II, 47, 2999–3026.Google Scholar

Jenik, J. (1992). Ecotone and ecocline: two questionable concepts in ecology. Ekologia, 11(3), 243–250.Google Scholar

Jones, D.O.B., Bett, B.J., Wynn, R.B. and Masson, D.G. (2009). The use of towed camera platforms in deep-water science. Underwater Technology, 28(2), 41–50.CrossRefGoogle Scholar

Johnson, G.C. (1998). Deep water properties, velocities, and dynamics over ocean trenches. Journal of Marine Research, 56(2), 239–347.CrossRefGoogle Scholar

Jørgensen, B.B. (2012). Shrinking majority of the deep biosphere. Proceedings of the National Academy of Sciences, USA, 109(40), 15976–15977.CrossRefGoogle ScholarPubMed

Jørgensen, B.B. and D’Hondt, S. (2006). A starving majority deep beneath the seafloor. Science, 314, 932–934.CrossRefGoogle ScholarPubMed

Jumars, P.A. (1975). Environmental grain and polychaete species’ diversity in a bathyal benthic community. Marine Biology, 30(3), 253–266.CrossRefGoogle Scholar

Jumars, P.A. and Hessler, R.R. (1976). Hadal community structure: implications from the Aleutian Trench. Journal of Marine Research, 34, 547–560.Google Scholar

Kaartvedt, S., Van Dover, C.L., Mullineaux, L.S. Wiebe, P.H. and Bollens, S.M. (1994). Amphipods on a deep-sea hydrothermal treadmill. Deep-Sea Research I, 41(1), 179–195.CrossRefGoogle Scholar

Kaiser, M.J. and Moore, P.G. (1999). Obligate marine scavengers: do they exist?Journal of Natural History, 33, 475–481.CrossRefGoogle Scholar

Kamenskaya, O.E. (1981). The amphipods (Crustacea) from deep-sea trenches in the western part of the Pacific Ocean. Transactions of the P.P. Shirshov Institute of Oceanology, 115, 94–107. (In Russian.)Google Scholar

Kamenskaya, O.E. (1989). Peculiarities of the vertical distribution of komokiaceans in the Pacific Ocean. Transactions of the P.P. Shirshov Institute of Oceanology, 123, 55–58.Google Scholar

Karan, P.P. and Mather, Cotton (1985). Tourism and environment in the Mount Everest region. Geographical Review, 75(1), 93–95.CrossRefGoogle Scholar

Karig, D.E. and Sharman, G.F. (1975). Subduction and accretion in trenches. Earth Planetary Science Letters, 86, 377–389.Google Scholar

Kato, C. (2011). Distribution of piezophiles. In Extremophiles Handbook, ed. Horikoshi, K., Antranikian, G., Bull, A.T., Robb, F.T. and Stetter, K.O.. London: Springer, pp. 644–653.Google Scholar

Kato, C. and Bartlett, D.H. (1997). The molecular biology of barophilic bacteria. Extremophiles, 1, 111–116.CrossRefGoogle ScholarPubMed

Kato, C. and Horikoshi, K. (1996). Gene expression under high pressure. In Progress in Biotechnology 13, High Pressure Bioscience and Biotechnology, ed. Hayashi, R. and Balny, C.. Amsterdam: Elsevier Science, pp. 59–66.CrossRefGoogle Scholar

Kato, C. and Nogi, Y. (2001). Correlation between phylogenetic structure and function: examples from deep-sea Shewanella. FEMS Microbiology Ecology, 35(3), 223–230.CrossRefGoogle ScholarPubMed

Kato, C. and Qureshi, M.H. (1999). Pressure response in deep-sea piezophilic bacteria. Journal of Molecular Microbiology and Biotechnology, 1(1), 87–92.Google ScholarPubMed

Kato, C., Sato, T. and Horikoshi, K. (1995a). Isolation and properties of barophilic and barotolerant bacteria from deep-sea mud samples. Biodiversity and Conservation, 4, 1–9.CrossRefGoogle Scholar

Kato, C., Smorawinska, M., Sato, T. and Horikoshi, K. (1995b). Cloning and expression in Escherichia coli of a pressure-regulated promoter region from a barophilic bacterium, stain DB6705. Journal of Marine Biotechnology, 2, 125–129.Google Scholar

Kato, C., Suzuki, S., Hata, S., Ito, T. and Horikoshi, K. (1995c). The properties of a protease activated by high pressure from Sprosarcina sp. strain DSK25 isolated from deep-sea sediment. JAMSTEC Research, 32, 7–13.Google Scholar

Kato, C., Masui, N. and Horikoshi, K. (1996). Properties of obligately barophilic bacteria isolated from a sample of deep-sea sediment from the Izu-Bonin Trench. Journal of Marine Biotechnology, 4, 96–99.Google Scholar

Kato, C., Li, L., Tamaoka, J. and Horikoshi, K. (1997). Molecular analyses of the sediment of the 11000-m deep Mariana Trench. Extremophiles, 1, 117–123.CrossRefGoogle Scholar

Kato, C., Li, L., Nogi, Y. et al. (1998). Extremely barophilic bacteria isolated from the Mariana Trench, Challenger Deep, at a depth of 11,000 meters. Applied Environmental Microbiology, 64, 1510–1513.Google Scholar

Kaufmann, R.S. (1994). Structure and function of chemoreceptors in scavenging lysianassoid amphipods. Journal of Crustacean Biology, 14(1), 54–71.CrossRefGoogle Scholar

Kaufmann, R.S. and Smith, K.L. (1997). Activity patterns of mobile epibenthic megafauna at an abyssal site in the eastern North Pacific: results from a 17-month time-lapse photographic study. Deep-Sea Research, 44, 559–579.CrossRefGoogle Scholar

Kawabe, M. (1993). Deep water properties and circulation in the western North Pacific. In Deep Ocean Circulation: Physical and Chemical Aspects, ed. Teramoto, T.. Amsterdam: Elsevier, pp. 17–37.CrossRefGoogle Scholar

Kawabe, M. and Fujio, S. (2010). Pacific Ocean circulation based on observation. Journal of Oceanography, 66, 389–403.CrossRefGoogle Scholar

Kawabe, M., Fujio, S. and Yanagimoto, D. (2003). Deep-water circulation at low latitudes in the western North Pacific. Deep-Sea Research I, 50(5), 631–656.CrossRefGoogle Scholar

Kearey, P. and Vine, F.J. (1990). Global Tectonics. Oxford: Blackwell Science.Google Scholar

Keller, N., Naumov, D. and Pasternak, F. (1975). Bottom deep-sea Coelenterata from the Gulf and Caribbean. Trudy Instituta Okeanologii, 100, 147–159.Google Scholar

Kelly, R.H. and Yancey, P.H. (1999). High contents of trimethylamine oxide correlating with depth in deep-sea teleost fishes, skates, and decapod crustaceans. Biological Bulletin, 196, 18–25.CrossRefGoogle ScholarPubMed

Kemp, K.M., Jamieson, A.J., Bagley, P.M. et al. (2006). Consumption of a large bathyal food fall, a six month study in the north-east Atlantic. Marine Ecology Progress Series, 310, 65–76.CrossRefGoogle Scholar

Kendall, V.J. and Haedrich, R.L. (2006). Species richness in Atlantic deep-sea fishes assessed in terms of themed-domain effect and Rapoport’s rule. Deep-Sea Research I, 53(3), 506–515.CrossRefGoogle Scholar

Kennedy, H., Beggins, J., Duarte, C.M. et al. (2010). Seagrass sediments as a global carbon sink: isotopic constraints. Global Biogeochemical Cycles, 24, GB4026.CrossRefGoogle Scholar