Abstract
Since the discovery of dense animal communities associated with deep-sea hydrothermal venting (Lonsdale 1997), biological knowledge of those animals has accumulated (Van Dover 2000). Some unique animals associated with vent fields were found to depend on chemosynthetic primary production (Corliss et al. 1979). Subsequently, similar chemosynthetic animal assemblages were also discovered associated with deep-sea methane-seep areas, whale falls, and sunken wood (Paull et al. 1984; Smith et al. 1989). To understand the pathways of adaptation to these environments, species shared between different habitats are of particular interest (Distel et al. 2000; Lorion et al. 2008). On a global scale, the number of species shared between vents and seeps is less than 10% of the total recorded vent or seep species (e.g. Tunnicliffe et al. 1998, 2003; Sibuet and Olu 1998). In the vent and seep communities around Japan, however, this figure exceeds 20% (based on a faunal list provided by Fujikura et al. 2008), although the identification of species is still in progress. This relatively high abundance of both vent- and seep-inhabiting species suggests close relationships between vent and seep communities around Japan. A high similarity between megafaunal communities at vents and seeps around Japan was already noted by Fujikura et al. (1995); however, that study was based on species abundances investigated at only a single vent and two methane-seep communities. To date, at least 55 vent and seep communities have been discovered around Japan (Fujikura et al. 2008), and further analyses are required to elucidate the nature of this similarity.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Ashi J (2003) Characteristics of Nankai Trough and origin of seeping water. Kaiyo Mon 35:296–300 (in Japanese)
Barry JP, Buck KR, Kochevar RK et al (2002) Methane-based symbiosis in a mussel, Bathymodiolus platifrons, from cold seeps in Sagami Bay, Japan. Invertebr Biol 121:47–54
Clarke KR, Warwick RM (2001) Change in Marine Communities: an approach to statistical analysis and interpretation, 2nd edn. PRIMER-E, Plymouth, UK
Clement M, Posada D, Crandall KA (2000) TCS: a computer program to estimate gene genealogies. Mol Ecol 9:1657–1659
Colwell F, Matsumoto R, Reed D (2004) Review of the gas hydrates, geology, and biology of the Nankai Trough. Chem Geol 205:391–404
Corliss JB, Dymond J, Gordon LI et al (1979) Submarine thermal springs on the Galapagos Rift. Science 203:1073–1083
Distel DL, Baco AR, Chuang E et al (2000) Do mussels take wooden steps to deep-sea vents? Nature 403:725–726
Excoffier L, Laval G, Schneider S (2005) Arlequin ver. 3.0: an integrated software package for population genetics data analysis. Evol Bioinform (Online) 1:47–50
Fujikura K, Hashimoto J, Fujiwara Y et al (1995) Community ecology of the chemosynthetic community at Off Hatsushima site, Sagami Bay, Japan. JAMSTEC Deep Sea Res 11:227–241 (in Japanese with English figure captions)
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. Mar Ecol Prog Ser 190:17–26
Fujikura K, Kojima S, Fujiwara Y et al (2000) New distribution records of vesicomyid bivalves from deep-sea chemosynthesis-based communities in Japanese waters. Venus 59:103–121
Fujikura K, Fujiwara Y, Ishibashi J et al (2001) Report on investigation of hydrothermal vent ecosystems by the crewed submersible ‘Shinkai 2000’ on the Dai-yon (No. 4) Yonaguni Knoll and the Hatoma Knoll, the Okinawa Trough. JAMSTEC Deep Sea Res 19:141–154 (in Japanese with English abstract and figure captions)
Fujikura K, Hashimoto J, Okutani T (2002) Estimated population densities of megafauna in two chemosynthesis-based communities: a cold seep in Sagami Bay and a hydrothermal vent in the Okinawa Trough. Benthos Res 57:21–30
Fujikura K, Aoki M, Fujiwara Y et al (2003) Report on investigation of vent and methane seep ecosystems by the crewed submersible ‘Shinkai 2000’ and the ROV ‘Dolphin 3K’ on the Hatoma and the Kuroshima Knolls, the Nansei-shoto area. JAMSTEC Deep Sea Res 22:21–30 (in Japanese with English abstract and figure captions)
Fujikura K, Amaki K, Barry J et al (2007) Long-term in situ monitoring of spawning behavior and fecundity in Calyptogena spp. Mar Ecol Prog Ser 333:185–193
Fujikura K, Okutani T, Maruyama T (eds) (2008) Deep-sea life – biological observations using research submersibles. Tokai University Press, Kanagawa, Japan (in Japanese with English figure captions)
Fujiwara Y, Tsukahara J, Hashimoto J et al (1998) In situ spawning of a deep-sea vesicomyid clam: evidence for environmental cue. Deep Sea Res I 45:1881–1889
Fujiwara Y, Takai K, Uematsu K et al (2000) Phylogenetic characterization of endosymbionts in three hydrothermal vent mussels: influence on host distributions. Mar Ecol Prog Ser 208:147–155
Fujiwara Y, Kato C, Masui N et al (2001) Dual symbiosis in the cold-seep thyasirid clam Maorithyas hadalis from the hadal zone in the Japan Trench, western Pacific. Mar Ecol Prog Ser 214:151–159
Fujiwara Y, Kawato M, Yamamoto T et al (2007) Three-year investigations into sperm whale-fall ecosystems in Japan. Mar Ecol 28:219–232
Glasby GP, Notsu K (2003) Submarine hydrothermal mineralization in the Okinawa Trough, SW of Japan: an overview. Ore Geol Rev 23:299–233
Goffredi SK, Hurtado LA, Hallam SJ, Vrijenhoek RC (2003) Evolutionary relationships of deep-sea vent and cold seep clams (Mollusca: Vesicomyidae) of the “pacifica/lepta” species complex. Mar Biol 142:311–320
Hashimoto J, Ohta S, Tanaka T et al (1989) Deep-sea communities dominated by the giant clam, Calyptogena soyoae, along the slope foot of Hatsushima Island, Sagami Bay, Central Japan. Palaeogeogr Palaeoclimatol Palaeoecol 71:179–192
Hashimoto J, Fujikura K, Miura T et al (1993) Discovery of vestimentiferan tube-worms in the euphotic zone. Proc JAMSTEC Symp Deep Sea Res 9:321–326
Hashimoto J, Ohta S, Fujikura K et al (1995) Life habit of vesicomyid clam, Calyptogena soyoae, and hydrogen sulfide concentration in interstitial waters in Sagami Bay, Japan. J Oceanogr 51:341–350
Ishibashi J, Urabe T (1994) Hydrothermal activity related to arc-backarc magmatism in the Western Pacific. In: Taylor B (ed) Backarc basins, tectonics and magmatism. Plenum, New York/London, pp 451–495
Iwasaki H, Kyuno A, Shintaku M et al (2006) Evolutionary relationships of deep-sea mussels inferred by mitochondrial DNA sequences. Mar Biol 149:1111–1122
Juniper K, Sibuet M (1987) Cold seep benthic communities in Japan subduction zones: spatial organization, trophic strategies and evidence for temporal evolution. Mar Ecol Prog Ser 40:115–126
Kiel S, Goedert JL (2006) Deep-sea food bonanzas: early Cenozoic whale-fall communities resemble wood-fall rather than seep communities. Proc R Soc B 273:2625–2631
Kojima S (2002) Deep-sea chemoautosynthesis-based communities in the Northwestern Pacific. J Oceanogr 58:343–363
Kojima S, Ohta S (1997) Calyptogena okutanii n. sp. a sibling species of Calyptogena soyoae Okutani, 1957 (Bivalvia: Vesicomyidae). Venus 56:189–195
Kojima S, Ohta S, Yamamoto T et al (2001) Molecular taxonomy of vestimentiferans of the western Pacific and their phylogenetic relationship to species of the eastern Pacific. I. Family Lamellibrachiidae. Mar Biol 139:211–219
Kojima S, Ohta S, Yamamoto T et al (2002) Molecular taxonomy of vestimentiferans of the western Pacific and their phylogenetic relationship to species of the eastern Pacific II. Families Escarpiidae and Arcovestiidae. Mar Biol 141:57–64
Kojima S, Fujikura K, Okutani T (2005) Genetic differentiation of two vesicomyid bivalves, Calyptogena okutanii and Calyptogena nankaiensis, between seep areas off the central Honshu and hydrothermal vent fields in the Okinawa Trough. Venus 64:45–53
Kojima S, Tsuchida E, Numanami H et al (2006) Synonymy of Calyptogena solidissima with Calyptogena kawamurai (Bivalvia: Vesicomyidae) and its population structure revealed by mitochondrial DNA sequences. Zool Sci 23:835–842
Kuwahara H, Yoshida T, Takaki Y et al (2007) Reduced genome of the thioautotrophic intracellular symbiont in a deep-sea clam, Calyptogena okutanii. Curr Biol 17:881–886
Kyuno A, Shintaku M, Fujita Y et al (2009) Dispersal and differentiation of deep-sea mussels of the genus Bathymodiolus (Mytilidae, Bathymodiolinae). J Mar Biol Article ID 625672, pp 1–15
Lallemand SE, Glaçon G, Lauriat-Rage A et al (1992) Seafloor manifestations of fluid seepage at the top of a 2000-metre-deep ridge in the eastern Nankai accretionary wedge: long-lived venting and tectonic implications. Earth Planet Sci Lett 109:333–346
Lonsdale P (1977) Clustering of suspension-feeding macrobenthos near abyssal hydrothermal vents at oceanic spreading centers. Deep Sea Res 24:857–863
Lorion J, Duperron S, Gros O et al (2008) Several deep-sea mussels and their associated symbionts are able to live both on wood and on whale falls. Proc R Soc B 276:177–185
Magurran AE (1988) Ecological diversity and its measurement. Princeton University Press, Princeton, NJ
Matsumoto R, Okuda Y, Hiruta A et al (2009) Formation and collapse of gas hydrate deposits in high methane flux area of the Joetsu Basin, eastern margin of Japan Sea. J Geogr 118:43–71 (in Japanese with English abstract and figure captions)
Miyazaki J, Shintaku M, Kyuno A et al (2004) Phylogenetic relationships of deep-sea mussels of the genus Bathymodiolus (Bivalvia: Mytiidae). Mar Biol 144:527–535
Mizota C, Yamanaka T (2003) Strategic adaptation of a deep-sea, chemosynthesis-based animal community: an evaluation based on soft body part carbon, nitrogen, and sulfur isotopic signatures. Jpn J Benthol 58:56–59 (in Japanese with English abstract and figure captions)
Munroe TA, Hashimoto J (2008) A new western Pacific tonguefish (Pleuronectiformes: Cynoglossidae): the first pleuronectiform discovered at active hydrothermal vents. Zootaxa 1839:43–59
Ogawa Y, Fujioka K, Fujikura K et al (1996) En echelon patterns of Calyptogena colonies in the Japan Trench. Geology 24:807–810
Ohta S, Kim DS (2001) Submersible observations of the hydrothermal vent communities on the Iheya Ridge, Mid Okinawa Trough. Jpn J Oceanogr 57:663–677
Ohta S, Laubier L (1987) Deep biological communities in the subduction zone of Japan from bottom photographs taken during “Nautile” dives in the Kaiko project. Earth Planet Sci Lett 83:329–342
Okutani T, Egawa K (1985) The first underwater observation on living habitat and thanatocenoses of Calyptogena soyoae in bathyal depth of Sagami Bay. Venus 44:285–289
Paull CK, Hecker B, Commeau R et al (1984) Biological communities at the Florida Escarpment resemble hydrothermal vent taxa. Science 226:965–967
Sakai H, Gamo T, Kim ES et al (1990) Venting of carbon dioxide-rich fluid and hydrate formation in Mid-Okinawa Trough backarc basin. Science 248:1093–1096
Sibuet M, Olu K (1998) Biogeography, biodiversity and fluid dependence of deep-sea cold-seep communities at active and passive margins. Deep Sea Res II 45:517–567
Sibuet M, Juniper K, Pautot G (1988) Cold-seep benthic communities in the Japan subduction zones: geological control of community development. J Mar Res 46:333–348
Smith CR, Kukert H, Wheatcroft RA et al (1989) Vent fauna on whale remains. Science 341:27–28
Tokuda G, Yamada A, Nakano K et al (2006) Occurrence and recent long-distance dispersal of deep-sea hydrothermal vent shrimp. Biol Lett 2:257–260
Tsunogai U, Ishibashi J, Wakita H et al (1994) Source of “cold seepage” at the off Hatsushima Island, Sagami Bay: a preliminary report of the Dive 721 of “Shinkai 2000”. JAMSTEC Deep Sea Res 10:395–403 (in Japanese with English abstract and figure captions)
Tunnicliffe V, Fowler MR (1996) Influence of sea-floor spreading on the global hydrothermal vent fauna. Nature 379:531–533
Tunnicliffe V, McArthur AG, McHugh D (1998) A biological perspective of the deep-sea hydrothermal vent fauna. Adv Mar Biol 34:353–442
Tunnicliffe V, Juniper K, Sibuet M (2003) Reducing environments of the deep-sea floor. In: Tyler PA (ed) Ecosystems of the deep oceans, vol 28, Ecosystems of the world. Elsevier, Amsterdam, The Netherlands, pp 81–110
Van Dover CL (2000) The ecology of deep-sea hydrothermal vent. Princeton University Press, Princeton, NJ, p 424
Watanabe H, Tsuchida S, Fujikura K et al (2005) Population history associated with hydrothermal vent activity inferred from genetic structure of neoverrucid barnacles around Japan. Mar Ecol Prog Ser 288:233–240
Watanabe H, Kado R, Kaida M et al (2006) Dispersal of vent-barnacle (genus Neoverruca) in the Western Pacific. Cah Biol Mar 47:353–357
Yamanaka T, Ishibashi J, Hashimoto J (2000) Organic geochemistry of hydrothermal petroleum generated in the submarine Wakamiko caldera, southern Kyushu, Japan. Org Geochem 31:1117–1132
Acknowledgements
We appreciate Drs. Motohiro Shimanaga and Dhugal J. Lindsay for their useful advices on analyzing similarities among vent and seep communities. We also thank the three reviewers and the editor Dr. Steffen Kiel, who gave us helpful comments to improve this paper.
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2010 Springer Science+Business Media B.V.
About this chapter
Cite this chapter
Watanabe, H., Fujikura, K., Kojima, S., Miyazaki, JI., Fujiwara, Y. (2010). Japan: Vents and Seeps in Close Proximity. In: Kiel, S. (eds) The Vent and Seep Biota. Topics in Geobiology, vol 33. Springer, Dordrecht. https://doi.org/10.1007/978-90-481-9572-5_12
Download citation
DOI: https://doi.org/10.1007/978-90-481-9572-5_12
Published:
Publisher Name: Springer, Dordrecht
Print ISBN: 978-90-481-9571-8
Online ISBN: 978-90-481-9572-5
eBook Packages: Earth and Environmental ScienceEarth and Environmental Science (R0)