Chemosynthetic endosymbioses: adaptations to oxic-anoxic interfaces.
about
Ecology and biogeography of free-living nematodes associated with chemosynthetic environments in the deep sea: a reviewNew perspectives on the ecology and evolution of siboglinid tubewormsThe giant ciliate Zoothamnium niveum and its thiotrophic epibiont Candidatus Thiobios zoothamnicoli: a model system to study interspecies cooperationComparative genomics of vesicomyid clam (Bivalvia: Mollusca) chemosynthetic symbiontsA Novel Colonial Ciliate Zoothamnium ignavum sp. nov. (Ciliophora, Oligohymenophorea) and Its Ectosymbiont Candidatus Navis piranensis gen. nov., sp. nov. from Shallow-Water Wood FallsMetatranscriptional Response of Chemoautotrophic Ifremeria nautilei Endosymbionts to Differing Sulfur RegimesLoss of genes for DNA recombination and repair in the reductive genome evolution of thioautotrophic symbionts of Calyptogena clams.Epibiotic bacteria associated with the recently discovered Yeti crab, Kiwa hirsuta.The ecological perspective of microbial communities in two pairs of competitive Hawaiian native and invasive macroalgae.Diversity of symbioses between chemosynthetic bacteria and metazoans at the Guiness cold seep site (Gulf of Guinea, West Africa).The methanol dehydrogenase gene, mxaF, as a functional and phylogenetic marker for proteobacterial methanotrophs in natural environments.DNA variation and symbiotic associations in phenotypically diverse sea urchin Strongylocentrotus intermedius.Metatranscriptomic analysis of sulfur oxidation genes in the endosymbiont of solemya velum.Dual symbiosis with co-occurring sulfur-oxidizing symbionts in vestimentiferan tubeworms from a Mediterranean hydrothermal vent.Deep-biosphere consortium of fungi and prokaryotes in Eocene subseafloor basalts.First Description of Sulphur-Oxidizing Bacterial Symbiosis in a Cnidarian (Medusozoa) Living in Sulphidic Shallow-Water Environments.CO2 uptake and fixation by endosymbiotic chemoautotrophs from the bivalve Solemya velum.The metatrochophore of a deep-sea hydrothermal vent vestimentiferan (Polychaeta: Siboglinidae).Electrical Retrieval of Living Microorganisms from Cryopreserved Marine Sponges Using a Potential-Controlled ElectrodeRepeated replacement of an intrabacterial symbiont in the tripartite nested mealybug symbiosis.By more ways than one: Rapid convergence at hydrothermal vents shown by 3D anatomical reconstruction of Gigantopelta (Mollusca: Neomphalina).Use of carbon monoxide and hydrogen by a bacteria-animal symbiosis from seagrass sedimentsFree-living tube worm endosymbionts found at deep-sea vents.Metatranscriptomics reveal differences in in situ energy and nitrogen metabolism among hydrothermal vent snail symbionts.Nitrogen fixation in distinct microbial niches within a chemoautotrophy-driven cave ecosystem.Sulfur metabolisms in epsilon- and gamma-proteobacteria in deep-sea hydrothermal fields.Association of thioautotrophic bacteria with deep-sea sponges.Genetic subdivision of chemosynthetic endosymbionts of Solemya velum along the Southern New England coast.'Til death do us part': coming to terms with symbiotic relationships. Forward.A novel Chromatiales bacterium is a potential sulfide oxidizer in multiple orders of marine sponges.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).A methane-driven microbial food web in a wetland rice soil.An unbiased genome-wide view of the mutation rate and spectrum of the endosymbiotic bacterium Teredinibacter turnerae.Forever competent: deep-sea bivalves are colonized by their chemosynthetic symbionts throughout their lifetime.There are many ways to be a mutualist: endophytic fungus reduces plant survival but increases population growth.Specificity in diversity: single origin of a widespread ciliate-bacteria symbiosis.The uptake and excretion of partially oxidized sulfur expands the repertoire of energy resources metabolized by hydrothermal vent symbioses.Off-axis symbiosis found: Characterization and biogeography of bacterial symbionts of Bathymodiolus mussels from Lost City hydrothermal ventsA facultative mutualistic feedback enhances the stability of tropical intertidal seagrass beds
P2860
Q21091109-6E05CA26-E54C-4D5E-850A-55D8DDA0ED4CQ21135571-08D7C676-32D4-4F2B-8B6D-988F146E9608Q26866302-D54649DE-CE2B-4412-B006-A27877C1E24FQ28755432-D92D21B1-155A-48C7-B67C-51C41F3FB544Q28828648-A60FC13D-8B79-4BD3-834D-8864F31D5220Q28829846-A700F679-81EA-4917-8BBA-BDE5931C767BQ31031703-CCF7B8D1-0762-4950-8E30-9F29B292A223Q33344938-0BBBEE88-BBEB-481A-BEA7-37F21AC6FA32Q34501448-40580DA9-2821-40C0-9421-A4C34F2FCB4BQ34509227-77EC70B9-A975-4913-A50F-45024346B0B1Q34602873-7B07CA1F-3650-495D-9E95-B0DBC11C8396Q34851915-87681FAB-ED42-4963-B450-BC17832FD928Q35075429-184D4608-8BC5-46C5-AF0C-E04C2FC1A8DCQ35098223-6CDD38D3-9FF1-4FDD-9B10-5512B45F3D87Q35249335-F98082F1-07D4-46F2-8A6E-E7314CA94C82Q35641940-C3B507B0-F181-4412-83A2-3D7742894902Q35689666-B1B51064-4B64-4B0A-96CA-2B41BA4B82D9Q35704098-0A4866FF-C8FC-49B8-9FE8-2A752EC00930Q35737833-62EA689F-0093-4DF8-9DC9-CFC47BF5802EQ36116473-E1E034CA-3DB8-429B-86FA-EA33DFFC8253Q36294404-9EB31E62-7677-4FAE-B157-E6D8611058CFQ36554525-672F47E5-ADBF-4F4D-AF76-5DF5F250E405Q36746808-2F29C3EB-1274-4FDD-AACD-4F6F129AF4FBQ37039721-C3BDA407-3214-4644-966E-3D5EF6145AB1Q37327683-68F308B5-DC5F-4ACD-B5E6-C119D6325F70Q38525520-11DD8902-35C3-44FF-BBA2-DAE7999E0BE0Q41418278-28FB69FB-7B18-4DFB-8BDE-A9AFB14677DFQ42069111-6EC9F973-C230-4ECE-91A3-96486A977687Q45885326-F1081925-5248-4E24-ADC2-0CFAEE0B1995Q46193868-FAE4A3AE-4964-4AD5-A5D8-582CD9469011Q46377877-E3F66D4F-C0C0-4D48-9E49-1E9318C9F960Q46841549-A2730F33-F02D-4DDB-B8E3-0B4BD84112DDQ48076569-8C2B91BD-C091-47CF-94A4-BF0F46B4EE68Q50132610-A3E69259-3A3C-45D9-AEAA-DDECA20474EBQ50639895-A6736102-27D0-4D63-883E-16C79D3CCA29Q51561910-9F34E6F7-EBEB-415D-8CCF-334184F9231DQ53166486-EA2B428A-C580-49F2-99F2-3B95294CDDD4Q53262192-94499E3B-ECD1-4416-A360-921674089C3CQ57087838-50A9530C-EBC2-42F1-8331-C0B24C5392D9Q58699567-82305226-E03F-45C2-8C63-72D93D22719D
P2860
Chemosynthetic endosymbioses: adaptations to oxic-anoxic interfaces.
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年論文
@yue
2005年論文
@zh-hant
2005年論文
@zh-hk
2005年論文
@zh-mo
2005年論文
@zh-tw
2005年论文
@wuu
2005年论文
@zh
2005年论文
@zh-cn
name
Chemosynthetic endosymbioses: adaptations to oxic-anoxic interfaces.
@ast
Chemosynthetic endosymbioses: adaptations to oxic-anoxic interfaces.
@en
type
label
Chemosynthetic endosymbioses: adaptations to oxic-anoxic interfaces.
@ast
Chemosynthetic endosymbioses: adaptations to oxic-anoxic interfaces.
@en
prefLabel
Chemosynthetic endosymbioses: adaptations to oxic-anoxic interfaces.
@ast
Chemosynthetic endosymbioses: adaptations to oxic-anoxic interfaces.
@en
P2093
P1476
Chemosynthetic endosymbioses: adaptations to oxic-anoxic interfaces.
@en
P2093
Colleen M Cavanaugh
Frank J Stewart
Irene L G Newton
P304
P356
10.1016/J.TIM.2005.07.007
P577
2005-09-01T00:00:00Z