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Difference between revisions of "Gnaiger 1977 Invertebrate anoxibiosis"

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(Created page with "{{Publication |title=Gnaiger E (1980) Energetics of invertebrate anoxibiosis: direct calorimetry in aquatic oligochaetes. FEBS Lett 112: 239-42. |info=[http://www.ncbi.nlm.nih.go...")
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{{Publication
{{Publication
|title=Gnaiger E (1980) Energetics of invertebrate anoxibiosis: direct calorimetry in aquatic oligochaetes. FEBS Lett 112: 239-42.
|title=Gnaiger E (1977) Thermodynamic considerations of invertebrate anoxibiosis. In: Applications of calorimetry in life sciences. Lamprecht I, Schaarschmidt B (eds), de Gruyter, Berlin:281-303.
|info=[http://www.ncbi.nlm.nih.gov/pubmed/7371862 PMID: 7371862]
|info=[[Media:Gnaiger 1977 Invertrebrate anoxibiosis.pdf |'''Bioblast pdf''']]
|authors=Gnaiger E
|authors=Gnaiger E
|year=1980
|year=1977
|journal=FEBS Lett
|journal=de Gruyter
|mipnetlab=AT_Innsbruck_Gnaiger E, AT Innsbruck MitoCom
|abstract=[[File:Gnaiger 1977 Invertrebrate anoxibiosis Fig1.jpg|right|240px]] New insight into the biochemical mechanism of invertebrate anoxibiosis made possible the calculation of the free-energy changes associated with the generation of high-energy bonds in nucleoside triphosphates (ATP, GTP, ITP) under anoxic conditions. The values obtained are compared with thermodynamic data of aerobic and fermentative energy production, and indicate a selection towards increased energetic efficiency of biochemical pathways leading to less toxic and readily excretable end products in anoxibiotic invertebrates. The thermodynamic model is mainly based upon a metabolic scheme elaborated on intertidal bivalves by de Zwaan et al, benthic oligochaetes and fresh-water bivalves.Β  It may provide a general hypothesis for the energetic processes which operate in a variety of ecological and taxonomic groups of anoxibiotic animals.
|mipnetlab=AT Innsbruck Gnaiger E
}}
}}
{{Labeling
{{Labeling
|area=Respiration, Comparative MiP;environmental MiP
|area=Respiration, Comparative MiP;environmental MiP
|taxonomic group=Annelids
|injuries=Ischemia-reperfusion
|preparations=Intact Organism
|organism=Annelids, Molluscs
|injuries=Hypoxia
|preparations=Intact organism
|topics=Aerobic glycolysis
|topics=Aerobic glycolysis, ATP, Coupling efficiency;uncoupling
|couplingstates=ROUTINE
|additional=Microcalorimetry, Malic enzyme
|additional=Microcalorimetry
}}
}}
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* [[Malic enzyme]]

Revision as of 08:31, 9 November 2016

Publications in the MiPMap
Gnaiger E (1977) Thermodynamic considerations of invertebrate anoxibiosis. In: Applications of calorimetry in life sciences. Lamprecht I, Schaarschmidt B (eds), de Gruyter, Berlin:281-303.

Β» Bioblast pdf

Gnaiger E (1977) de Gruyter

Abstract:

Gnaiger 1977 Invertebrate anoxibiosis Fig1.jpg

New insight into the biochemical mechanism of invertebrate anoxibiosis made possible the calculation of the free-energy changes associated with the generation of high-energy bonds in nucleoside triphosphates (ATP, GTP, ITP) under anoxic conditions. The values obtained are compared with thermodynamic data of aerobic and fermentative energy production, and indicate a selection towards increased energetic efficiency of biochemical pathways leading to less toxic and readily excretable end products in anoxibiotic invertebrates. The thermodynamic model is mainly based upon a metabolic scheme elaborated on intertidal bivalves by de Zwaan et al, benthic oligochaetes and fresh-water bivalves. It may provide a general hypothesis for the energetic processes which operate in a variety of ecological and taxonomic groups of anoxibiotic animals.


β€’ O2k-Network Lab: AT Innsbruck Gnaiger E


Labels: MiParea: Respiration, Comparative MiP;environmental MiP 

Stress:Ischemia-reperfusion  Organism: Annelids, Molluscs 

Preparation: Intact organism 

Regulation: Aerobic glycolysis, ATP, Coupling efficiency;uncoupling 



Microcalorimetry, Malic enzyme 

Science and adventure