about
Evolutionary process of deep-sea bathymodiolus musselsHow deep-sea wood falls sustain chemosynthetic lifeDo larval supply and recruitment vary among chemosynthetic environments of the deep sea?World-wide whale worms? A new species of Osedax from the shallow north AtlanticDeep-sea whale fall fauna from the Atlantic resembles that of the Pacific Ocean.Microbial communities in sunken wood are structured by wood-boring bivalves and location in a submarine canyonEcological succession of a Jurassic shallow-water ichthyosaur fall.Explaining bathymetric diversity patterns in marine benthic invertebrates and demersal fishes: physiological contributions to adaptation of life at depthAdaptive radiation of chemosymbiotic deep-sea musselsThe secret to successful deep-sea invasion: does low temperature hold the key?Phylogeny and diversification patterns among vesicomyid bivalvesBones as biofuel: a review of whale bone composition with implications for deep-sea biology and palaeoanthropologyExtracellular and mixotrophic symbiosis in the whale-fall mussel Adipicola pacifica: a trend in evolution from extra- to intracellular symbiosisSeveral deep-sea mussels and their associated symbionts are able to live both on wood and on whale fallsDeep-sea food bonanzas: early Cenozoic whale-fall communities resemble wood-fall rather than seep communitiesBeta-diversity on deep-sea wood falls reflects gradients in energy availabilityDiscovery of chemoautotrophic symbiosis in the giant shipworm Kuphus polythalamia (Bivalvia: Teredinidae) extends wooden-steps theory.Biogeography revisited with network theory: retracing the history of hydrothermal vent communities.Genetic connectivity between north and south Mid-Atlantic Ridge chemosynthetic bivalves and their symbionts.Diversity of symbioses between chemosynthetic bacteria and metazoans at the Guiness cold seep site (Gulf of Guinea, West Africa).Integrative biology of Idas iwaotakii (Habe, 1958), a 'model species' associated with sunken organic substratesAre organic falls bridging reduced environments in the deep sea? - results from colonization experiments in the Gulf of CádizThe contrasted evolutionary fates of deep-sea chemosynthetic mussels (Bivalvia, Bathymodiolinae).Methane Seep Carbonates Host Distinct, Diverse, and Dynamic Microbial Assemblages.Macroinvertebrate community assembly on deep-sea wood falls in Monterey Bay is strongly influenced by wood type.Temporal and Spatial Variations of Bacterial and Faunal Communities Associated with Deep-Sea Wood Falls.Environmental acquisition of thiotrophic endosymbionts by deep-sea mussels of the genus bathymodiolusSymbiotic diversity in marine animals: the art of harnessing chemosynthesis.Understanding processes at the origin of species flocks with a focus on the marine Antarctic fauna.Temporal and spatial constraints on community assembly during microbial colonization of wood in seawaterMicrobial diversity in shallow-water hydrothermal sediments of Kueishan Island, Taiwan as revealed by pyrosequencing.Possible role of a taurine transporter in the deep-sea mussel Bathymodiolus septemdierum in adaptation to hydrothermal vents.Do ampharetids take sedimented steps between vents and seeps? Phylogeny and habitat-use of Ampharetidae (Annelida, Terebelliformia) in chemosynthesis-based ecosystems.Bacteria alone establish the chemical basis of the wood-fall chemosynthetic ecosystem in the deep-sea.Insights into deep-sea adaptations and host-symbiont interactions: A comparative transcriptome study on Bathymodiolus mussels and their coastal relatives.Unexpected co-occurrence of six bacterial symbionts in the gills of the cold seep mussel Idas sp. (Bivalvia: Mytilidae).The early conversion of deep-sea wood falls into chemosynthetic hotspots revealed by in situ monitoring.Specific dynamic action affects the hydrostatic pressure tolerance of the shallow-water spider crab Maja brachydactyla.The ocean is not deep enough: pressure tolerances during early ontogeny of the blue mussel Mytilus edulis.A new yeti crab phylogeny: Vent origins with indications of regional extinction in the East Pacific.
P2860
Q21090018-9AF6B693-A09D-4948-992F-45C677C6B780Q21133766-F38F2A43-5010-4FCF-BA9C-0264ADBF4B28Q21562192-59341A6C-3EA7-4DDD-994E-0C7B49D8B5D0Q24676983-C682A787-13E7-48BD-B81A-F32295AC330EQ27339640-F2969453-216D-4891-8B9C-C2C979B2E297Q28538561-A343A598-1600-4AF0-B9DF-F81D2A8A8DA8Q28655478-17CD2370-CEB8-489F-92B2-0D6CA09137A1Q28655926-D7FCB29B-5E6D-46D6-992A-8770FF495943Q28680643-609348AB-3B3A-4179-965D-8A1B567B0A20Q28710404-3DB7387D-01BA-4833-89EC-7866BF171E29Q28730622-A6756A3E-6602-4C8D-8F41-6ADB7CA508F5Q28744620-AD565A22-6383-4C95-B581-314CEBC62092Q28750192-DE7FC3DD-B84B-42A9-9C7E-E2E79645CBB7Q28755872-934B52E4-7838-421F-B71F-DE4AB138E6FBQ28766834-80EC77CA-2EFA-442F-803C-0F101ED5DE53Q33580959-92BFB6BD-2EA0-442C-BE4C-B17CEC7D7447Q33650936-1B30D6B2-6CAB-491C-9A04-13848A66306CQ33998371-6014FD76-57E2-4CC2-B3BA-6C620EEC6E7EQ34335826-393C1884-DDD7-4716-8DBF-565ED831D256Q34509227-06AA22DD-AAD6-4693-907F-7D7D38DADDEAQ34874202-D3B5F8C1-E370-4064-85BB-C732F7FDD2FDQ35009625-A408BDBE-1FD4-48D3-B604-607FF9B4EC1DQ35074394-1189F0B7-B57D-4346-8357-2460D69D6182Q35875950-F26CA6D6-D375-4872-B8C9-E67BA15122DBQ36199411-F642396A-87DD-4F52-B309-FF5BCD5E9011Q36259856-DE885A36-4712-4BF3-97F5-EA7A28241F84Q37054862-5F0C9F73-8ACA-462A-9438-1113EA2FAC4CQ37270477-731458CA-E77F-4B5C-8CCF-2AE6A91233B9Q38368267-899B83A4-44B2-490C-8B6A-E93052922D25Q39783321-8CBFAD82-8FC0-4708-B95B-FF24B71A8E50Q40777885-8EF6135B-8F13-447A-A86E-2C8EB80F2158Q44551916-39AA3C60-0C62-4A8A-9893-B5DAE774D354Q46091586-A0197493-654B-4166-84BC-151BE417A8CEQ46292850-EE9C7A54-B0D7-4A4F-A5E7-823A10107EA4Q46377877-5E6AB861-F1FF-40AA-B420-1413812F5718Q46841549-9EC64C4B-D86A-4660-851B-026301A17048Q49311527-7A6F8EC0-CC28-4B5A-B1AE-B81C146CC26CQ51606529-3FCEC6E5-7E3A-4665-935D-0CE5DFCBE895Q51946941-3AF0F07B-37E1-428A-82E4-B7045D71FFB5Q52652198-35F08B5C-6E96-4FAC-8A2F-A9A84B855014
P2860
description
article publié dans la revue scientifique Nature
@fr
scientific article published in Nature
@en
wetenschappelijk artikel
@nl
наукова стаття, опублікована в Nature в лютому 2000
@uk
name
Do mussels take wooden steps to deep-sea vents?
@en
Do mussels take wooden steps to deep-sea vents?
@nl
type
label
Do mussels take wooden steps to deep-sea vents?
@en
Do mussels take wooden steps to deep-sea vents?
@nl
prefLabel
Do mussels take wooden steps to deep-sea vents?
@en
Do mussels take wooden steps to deep-sea vents?
@nl
P2093
P2860
P356
P1433
P1476
Do mussels take wooden steps to deep-sea vents?
@en
P2093
P2860
P2888
P304
P356
10.1038/35001667
P407
P577
2000-02-01T00:00:00Z
P6179
1031259424