Received date: 2009-04-28
Revised date: 2010-03-08
Online published: 2010-05-10
ChEss is a pilot project within the Census of Marine Life (CoML) initiative. The main objective of ChEss was to determine the biogeography and biodiversity of deep-water chemosynthetic ecosystems and to understand the processes driving them. Chemosynthetic ecosystems include hydrothermal vents, cold seeps, whale fall and other highly reduced ecosystems. To assess the biogeography and biodiversity of chemosynthetic ecosystems it is essential that all the above systems be studied in combination. Determining the evolutionary and ecological relationships among their fauna is crucial to understanding the processes that shape the distribution of species from chemosynthetic ecosystems at the global scale. The background, content, goal, research area, technique, methods, progress and future plan are introduced in this paper, which is expected to be useful for the study of biodiversity and biogeography in deep sea chemosynthetic systems and other extreme environment in China.
XUN Xiao-Xia , XUN Song- . Research Progress of Deep Sea Chemosynthetic Ecosystems[J]. Advances in Earth Science, 2010 , 25(5) : 552 -560 . DOI: 10.11867/j.issn.1001-8166.2010.05.0552
[1] Sibuet M, Olu K. Biogeography, biodiversity and fluid dependence of deep-sea cold-seep communities at active and passive margins[J].Deep-Sea Research II,1998, 45: 517-567.
[2] Smith C R, Kukert H, Wheatcroft R A,et al. Vent fauna on whale remains[J]. Nature, 1989, 341: 27-28.
[3] Smith C R, Baco A R. The ecology of whale falls at the deep-sea floor[J].Oceanography and Marine Biology Annual Review, 2003, 41: 311-354.
[4] Levin L A. Oxygen minimum zone benthos: Adaptation and community response to hypoxia[J].Oceanography and Marine Biology: An Annual Review,2003, 41: 1-45.
[5] ChEss steering committee. Developing a Long Term Field Phase for Understanding the Biogeography of Deep-water Chemosynthetic Ecosystems at the Global Scale[R].ChEss, Biogeo-graphy of Deep-Water Chemosynthetic Tcosystems Science Plan, 2005:1-10.
[6] Edmonds H N, Michael P J, Baker E T,et al. Discovery of abundant hydrothermal venting on the ultraslow-spreading Gakkel ridge in the Arctic Ocean[J].Nature,2003, 421: 252-256.
[7] Pedersen R, Kelly D, Thorseth I,et al. ROV exploration of the Kolbeinsey Ridge: preliminary results of the SUBMAR-99 cruise[J].InterRidge News,1999, 8: 32-34.
[8] Connelly D P, German C R. Total dissolvable manganese anomalies over the Knipovich Ridge: Evidence for hydrothermal activity[J]. EOS, Transactions, American Geophysical Union, 2002, 83:205-206.
[9] Domaneschi O, Lopes S.Calyptogena (Calyptogena) birmani, a new species of Vesicomyidae (Mollusca-Bivalvia) from Brazil[J].Malacologia,1990, 31: 363-370.
[10] German C R, Livermore R A, Baker E T,et al.Hydrothermal plumes above the East Scotia Ridge: An isolated high-latitude back arc spreading centre[J].Earth and Planetary Science Letters,2001, 184: 241-250.
[11] Klinkhammer G, Chin C, Keller R,et al. Discovery of new hydrothermal vent sites in Bransfield Strait, Antarctica[J].Earth and Planetary Science Letters,2001, 193: 395-407.
[12] German C R, Baker E T, Mevel C,et al. Hydrothermal activity along the southwest Indian ridge[J].Nature,1998, 395: 490-493.
[13] Bach W, Alt J C, Niu Y,et al. The geochemical consequences of late-stage low-grade alteration of lower ocean crust at the SW Indian Ridge: Results from ODP Hole 735B (Leg 176)[J].Geochimica et Cosmochimica Acta,2001,65:3 267-3 287.
[14] Baker M, Ramírez-Llodra E,Tyler P,et al. ChEss Protocols: Exploration and investigation of deep-water chemosynthetic ecosystems[R/OL].http//www.noc.soton.ac.uk/chess,2005.
[15] German C R, Richards K J, Rudnicki M D,et al. Topographic control of a dispersing hydrothermal plume[J].Earth Planetary Science Letters,1998,156:267-273.
[16] Cave R R, German C R. Hydrothermal plume detection in the deep ocean—A combination of technologies[J].Journal of Society Underwater Technology,1998, 23: 71-75.
[17] Baker E T, Hey R N, Lupton J E,et al. Hydrothermal venting along earth′s fastest spreading center: East Pacific Rise, 27.5 degrees-32.3 degrees[J].Journal of Geophysical Research,107 (B7): EPM21-EPM2.14.
[18] Gamo T, Chiba H, Yamanaka T,et al. Chemical characteristics of newly discovered black smoker fluids and associated hydrothermal plumes at the Rodriguez Triple Junction, Central Indian Ridge[J].Earth Planetary Science Letters,2001, 193: 371-379.
[19] Van Dover C L. Community structure of mussel beds at deep-sea hydrothermal vents[J].Marine Ecology Progress Series,2002, 230: 137-158.
[20] German C R, Yoergera D R, Jakubaa M,et al. Hydrothermal exploration with the Autonomous Benthic Explorer[J].Deep-Sea Research I,2008, 55: 203-219.
[21] MacDonald I R, Guinasso N L, Ackleson S G,et al. Natural oil slicks in the Gulf of Mexico visible from space[J]. Journal of Geophysical Research,1993, 98(C9):16 351-16 364.
[22] MacDonald I R, Reilly J F, Best S E,et al. A remote-sensing inventory of active oil seeps and chemosynthetic communities in the northern Gulf of Mexico[C]//Schumacher D, Abrams M A.Hydrocarbon Migration and Its Near-surface Expression. American Association of Petroleum Geologists,1996,66:27-37.
[23] MacDonald I R, Arvidson R, Carney R S,et al. Stability and Change in Gulf of Mexico Chemosynthetic Communities: Final Report[R]. New Orleans, LA, US Deptartment of the Interior, Minerals Management Service, Gulf of Mexico OCS Region, 2002, Contract 14-35-001-31813.
[24] Sellanes J, Quiroga E, Gallardo V A. First direct evidence of methane seepage and associated chemosynthetic communities in the bathyal zone off Chile[J].Journal of the Marine Biological Association of the United Kingdom,2004, 84: 1 065-1 066.
[25] Ramirez-Llodra E, Shank T M, German C R. Biodiversity and biogeography of hydrothermal vent species: Thirty years of discovery and investigations[J].Oceanography,2001, 20(1): 31-40.
[26] Urcuyo I A, Massoth G J, Julian D, et al. Habitat, growth and physiological ecology of a basaltic community of Ridgeia piscesae from the Juan de Fuca Ridge[J]. Deep Sea Research I, 2003, 50: 763-780.
[27] Weber R E, Hourdez S, Knowles F, et al. Hemoglobin function in deep-sea and hydrothermal vent endemic fish: Symenchelis arasitica (Anguillidae) and Thermarces Cerberus (Zoarcidae)[J]. Journal of Experimental Biology, 2003, 206: 2 697-2 702.
[28] Hilario A, Young C M, Tyler P A. Sperm storage, internal fertilization and embryonic dispersal in vent and seep tubeworms (Polychaeta:Siboglinidae:Vestimentifera)[J]. Biological Bulletin,2005, 208: 20-28.
[29] Metaxas A. Spatial and temporal patterns in larval supply at hydrothermal vents on the northwest Pacific Ocean[J]. Limnology & Oceanography,2004, 49: 1949-1 956.
[30] Mullineaux L S, Peterson C H, Micheli F, et al. Successional mechanism varies along a gradient in hydrothermal fluid flux at deep-sea vents[J]. Ecological Monographs, 2003, 73: 523-542.
[31] Mullineaux L S, Mills S W, Sweetman A K, et al. Vertical, lateral and temporal structure in larval distributions at hydrothermal vents[J]. Marine Ecology Progress Series, 2005, 293: 1-16.
[32] Mullineaux L S, Kim S L, Pooley A, et al. Identification of archaeogastropod larvae from a hydrothermal vent community[J]. Marine Biology,1996, 124: 551-560.[33] Taylor C-WHOI (used on cruise-Extreme 2002)[EB/OL]. http://www.ocean.udel.edu/extreme2002/creatures/microbes/,2009.
[34] Kouris A, Juniper S K, Fre bourg G,et al.Protozoan bacterial symbiosis in a deep-sea hydrothermal vent folliculinid ciliate (Folliculinopsis sp.) from the Juan de Fuca Ridge[J].Marine Ecology,2007, 28: 63-71.
[35] Cowen R K, Lwiza K M M, Sponaugle S,et al. Connectivity of marine populations: Open or closed?[J].Science,2000, 287: 857-859.
[36] Mullineaux L S, Mills S W, Sweetman A K,et al. Vertical, lateral and temporal structure in larval distributions at hydrothermal vents[J].Marine Ecology Proggress Series,2005, 293:1-16.
[37] Ramirez-Llodra E. Fecundity and life-history strategies in marine invertebrates[J].Advances in Marine Biology,2002, 43: 88-170.
[38] Marsh A G, Mullineaux L S, Young C M,et al. Larval dispersal potential of the tubeworm Riftia pachyptila at deep-sea hydrothermal vents[J].Nature,2001, 411: 77-80.
[39] Yoerger Dana R, Bradley Albert M, Jakuba Michael,et al.Autonomous and remotely operated vehicle technology for hydrothermal vent discovery[J].Exploration and Sampling, Oceanography,2007, 20(1): 152-161.
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