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Storey 1979 Can J Zool

From Bioblast
Publications in the MiPMap
Storey KB, Storey JM, Johansen K, Hochachka PW (1979) Octopine metabolism in Sepia officinalis: effect of hypoxia and metabolite loads on the blood levels of octopine and related compounds. Can J Zool 57:2331-6.

ยป Can J Zool

Storey KB, Storey JM, Johansen K, Hochachka PW (1979) Can J Zool

Abstract: Male Sepia officinalis were subjected to hypoxia and the concentrations of blood metabolites were measured during stress and recovery. Blood octopine levels were elevated during hypoxia, whereas blood glucose concentration declined. During recovery, octopine was rapidly cleared from the blood while blood glucose concentration increased, initially overshooting the control level, before returning to prehypoxia levels. The clearance of an octopine bolus (300โ€‚ฮผmol given intravenously) from the blood was followed. Octopine uptake from the blood was correlated with a transient rise in blood glucose concentration. Injection of an arginine bolus resulted in an increase in blood octopine levels, whereas a lactate bolus led to elevated blood glucose and octopine levels. The data show that octopine concentration in cephalopod blood is modulated in response to physiological stress and that octopine metabolism is closely integrated with the metabolism of glucose, arginine, and lactate. It is suggested that the octopine produced during glycolytic muscular work is transported via the bloodstream for use as an aerobic substrate in other tissues. The inverse relationship between blood octopine and glucose levels suggests the presence of a modified "Cori cycle" in which octopine released from muscle can be taken up by tissues capable of utilizing the compound as a gluconeogenic substrate.


Labels: MiParea: Comparative MiP;environmental MiP 

Stress:Ischemia-reperfusion  Organism: Molluscs