Animal adaptations for tolerance and exploitation of poisonous sulfide.
about
Anaerobic animals from an ancient, anoxic ecological nicheUnsuspected diversity of Niphargus amphipods in the chemoautotrophic cave ecosystem of Frasassi, central ItalyThresholds of hypoxia for marine biodiversityPeroxisome proliferation in Foraminifera inhabiting the chemocline: an adaptation to reactive oxygen species exposure?Genomic resources for a model in adaptation and speciation research: characterization of the Poecilia mexicana transcriptomeBiochemistry and evolution of anaerobic energy metabolism in eukaryotesThe incomplete natural history of mitochondriaThe Influence of Organic Material and Temperature on the Burial Tolerance of the Blue Mussel, Mytilus edulis: Considerations for the Management of Marine Aggregate DredgingCharacteristics and function of sulfur dioxygenase in Echiuran worm Urechis unicinctusLocally adapted fish populations maintain small-scale genetic differentiation despite perturbation by a catastrophic flood event.Evolutionary analyses of the small subunit of glutamate synthase: gene order conservation, gene fusions, and prokaryote-to-eukaryote lateral gene transfers.The deep-sea glass sponge Lophophysema eversa harbours potential symbionts responsible for the nutrient conversions of carbon, nitrogen and sulfur.Shared and unique patterns of embryo development in extremophile poeciliids.Predator avoidance in extremophile fish.Energy metabolism among eukaryotic anaerobes in light of Proterozoic ocean chemistry.Are organic falls bridging reduced environments in the deep sea? - results from colonization experiments in the Gulf of CádizIdentity of epibiotic bacteria on symbiontid euglenozoans in O2-depleted marine sediments: evidence for symbiont and host co-evolution.Effect of sulfide on growth of marine bacteria.Gut microbes may facilitate insect herbivory of chemically defended plants.Divergent evolution of male aggressive behaviour: another reproductive isolation barrier in extremophile poeciliid fishes?The Effect of Digestive Capacity on the Intake Rate of Toxic and Non-Toxic Prey in an Ecological ContextTranscriptional response to sulfide in the Echiuran Worm Urechis unicinctus by digital gene expression analysisHydrogen sulfide induces oxidative damage to RNA and DNA in a sulfide-tolerant marine invertebrate.Adaptive radiation in extremophilic Dorvilleidae (Annelida): diversification of a single colonizer or multiple independent lineages?Functional analysis of three sulfide:quinone oxidoreductase homologs in Chlorobaculum tepidum.Regulation of mitochondrial bioenergetic function by hydrogen sulfide. Part I. Biochemical and physiological mechanisms.Mitochondrial adaptations to utilize hydrogen sulfide for energy and signaling.Of early animals, anaerobic mitochondria, and a modern sponge.Distribution, diversity, and activities of sulfur dioxygenases in heterotrophic bacteria.The Role of Hydrogen Sulfide in Evolution and the Evolution of Hydrogen Sulfide in Metabolism and Signaling.Cysteinyl-tRNA synthetase governs cysteine polysulfidation and mitochondrial bioenergetics.Gradient evolution of body colouration in surface- and cave-dwelling Poecilia mexicana and the role of phenotype-assortative female mate choice.Colonisation of toxic environments drives predictable life-history evolution in livebearing fishes (Poeciliidae).Ovarian structure and oogenesis of the extremophile viviparous teleost Poecilia mexicana (Poeciliidae) from an active sulfur spring cave in Southern Mexico.Mathematical analysis of a mechanism for autonomous metabolic oscillations in continuous culture of Saccharomyces cerevisiae.Evolution of the sulfide-binding function within the globin multigenic family of the deep-sea hydrothermal vent tubeworm Riftia pachyptila.How much is too much? Identifying benchmarks of adverse effects of macroalgae on the macrofauna in intertidal flats.Staphylococcus aureus sqr Encodes a Type II Sulfide:Quinone Oxidoreductase and Impacts Reactive Sulfur Speciation in Cells.Three enzymatic activities catalyze the oxidation of sulfide to thiosulfate in mammalian and invertebrate mitochondria.Response of sulfide:quinone oxidoreductase to sulfide exposure in the echiuran worm Urechis unicinctus.
P2860
Q21093235-98B9F750-F9A8-410F-97A1-C8D4653C79B0Q21284126-9374F80A-B0A9-4275-A5B3-B0AA69BD4B31Q24642610-7E8734F3-3743-4922-982D-03ACFE378558Q24654028-242D1F25-9AE9-4970-943A-7BE470516E6FQ28706123-26140006-3E4B-4388-8A4B-07560237C3F4Q28728648-77AEDCAF-033A-4506-BAF5-7F56EA8167CCQ29616111-32D80D42-DDDB-449B-8458-CE662FF76A80Q30391880-1B838E4D-F70B-4D1D-902C-EF5A4F90052AQ31145843-BD4D9E59-E8A9-475C-B34A-11111F9450A2Q33669540-F12FA9B7-53B8-49D2-87BD-DECC28008C04Q33905327-10090372-B61D-4DDE-868D-E02A37C2392DQ34045542-C8607ECE-A0FC-4151-B216-3F3C728A4C2DQ34075640-E405E71B-8DDC-41D6-A3A4-80D28C99DFD9Q34295861-1D300404-7AA0-4701-B289-041B6225337EQ34777710-EE488C8A-5039-4FDF-9576-8CE56B6A0BC1Q35009625-798503DB-DFB0-4A13-B3D1-EE5F7D166807Q35018640-6D6F5CEA-54DC-47B1-8C4A-8301C2F58AE4Q35114979-9E1EA002-080B-45C4-BC70-05C51B5B22A9Q35621080-CFD1171A-463F-4D84-BC46-9446364F980AQ35724981-48851745-9AE0-4F56-A269-155335CF2614Q35750221-76AEB30B-60E0-4794-AF1A-4D2ABC6DA94BQ35815509-BEB86024-ACAB-42FE-91B6-AF52CB6169F6Q35972902-6BB427D0-2A31-4DEA-BB3B-0ACD85FD9C33Q36209327-0D6E380C-FF04-43C5-A849-F478E0A0AB42Q37075567-91068E6E-DF7D-45B1-88DF-FD2ADB100A56Q37686284-2E7D60CA-4688-4B71-91B7-B0A3D4BDB0C1Q37995085-9854C68B-F67D-4A11-A0B2-3F9434FF318BQ38239452-2FEC482C-7541-4602-9D76-8D49F5634096Q38319362-25AD02C0-43A5-4FDA-9F3A-A94C3BD6AF6AQ38671099-05985BCA-1C9B-4A49-A029-1D10635FEF28Q42587502-78EED853-EC30-4AB9-AE2E-938B59E76A0FQ42662443-BB569B9F-1C1B-4AB3-BCC5-7C415356EDCFQ43019857-776410DE-8C7D-48CC-A419-F37B00846862Q43032462-4CE5E807-4CAB-46A7-A248-A1781240AB07Q43651534-64EB3C82-A925-466A-9A8A-BB63EEE95135Q44117736-5243AF3C-2F69-459C-AAFC-447DF6F31C88Q44968141-3F389652-4972-4D97-AA27-796035D20C56Q46465462-6A8E5089-EC83-468F-A806-9FEC91631994Q46583629-EE566C76-0D8C-4DD6-A7BC-99251515BA7BQ46858057-28722154-43EA-43BD-9393-F62209608483
P2860
Animal adaptations for tolerance and exploitation of poisonous sulfide.
description
1998 nî lūn-bûn
@nan
1998年の論文
@ja
1998年論文
@yue
1998年論文
@zh-hant
1998年論文
@zh-hk
1998年論文
@zh-mo
1998年論文
@zh-tw
1998年论文
@wuu
1998年论文
@zh
1998年论文
@zh-cn
name
Animal adaptations for tolerance and exploitation of poisonous sulfide.
@en
type
label
Animal adaptations for tolerance and exploitation of poisonous sulfide.
@en
prefLabel
Animal adaptations for tolerance and exploitation of poisonous sulfide.
@en
P1476
Animal adaptations for tolerance and exploitation of poisonous sulfide.
@en
P2093
Grieshaber MK
P356
10.1146/ANNUREV.PHYSIOL.60.1.33
P577
1998-01-01T00:00:00Z