Oxidative DNA damage and antioxidant defenses in the European common lizard ( Lacerta vivipara) in supercooled and frozen states

The European common lizard ( Lacerta vivipara) tolerates long periods at sub-zero temperatures, either in the supercooled or the frozen state. Both physiological conditions limit oxygen availability to tissues, compelling lizards to cope with potential oxidative stress during the transition from isc...

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Bibliographic Details
Published in:Cryobiology 2006-02, Vol.52 (1), p.74-82
Main Authors: Voituron, Yann, Servais, Stéphane, Romestaing, Caroline, Douki, Thierry, Barré, Hervé
Format: Article
Language:English
Subjects:
8-oxodGuo
Adaptation, Physiological
Adenine - metabolism
Aldehydes - metabolism
Animals
Antioxidants - metabolism
Antioxidants - pharmacology
Catalase
Catalase - metabolism
DNA Damage - drug effects
DNA Damage - physiology
Freeze tolerance
Freezing
Glutathione peroxidase
Glutathione Peroxidase - metabolism
Guanine - metabolism
Lacerta vivipara
Lacertilia
Lipid Peroxidation
Lipid peroxidation induced DNA adducts
Liver - metabolism
Lizards - metabolism
Malondialdehyde - metabolism
Muscles - metabolism
Oxidative Stress - drug effects
Oxidative Stress - physiology
Reptile
Supercooling
Superoxide dismutase
Superoxide Dismutase - metabolism
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Summary:The European common lizard ( Lacerta vivipara) tolerates long periods at sub-zero temperatures, either in the supercooled or the frozen state. Both physiological conditions limit oxygen availability to tissues, compelling lizards to cope with potential oxidative stress during the transition from ischemic/anoxic conditions to reperfusion with aerated blood during recovery. To determine whether antioxidant defenses are implicated in the survival of lizards when facing sub-zero temperatures, we monitored the activities of antioxidant enzymes and oxidative stress either during supercooling or during freezing exposures (20 h at −2.5 °C) and 24 h after thawing in two organs of lizards—muscle and liver. Supercooling induced a significant increase in the total SOD and GPx activity in muscle (by 67 and 157%, respectively), but freezing had almost no effect on enzyme activity, either in muscle or in liver. By contrast, thawed lizards exhibited higher GPx activity in both organs (a 133% increase in muscle and 59% increase in liver) and a significant decrease in liver catalase activity (a 47% difference between control and thawed lizards). These data show that supercooling (but not freezing) triggers activation of the antioxidant system and this may be in anticipation of the overgeneration of oxyradicals when the temperature increases (while thawing or at the end of supercooling). Oxidative stress was assessed from the content of 8-oxodGuo and the different DNA adducts resulting from lipid peroxidation, but it was unaltered whatever the physiological state of the lizards, thus demonstrating the efficiency of the antioxidant system that has been developed by this species. Overall, antioxidant defenses appear to be part of the adaptive machinery for reptilian tolerance to sub-zero temperatures.
ISSN:0011-2240
1090-2392
DOI:10.1016/j.cryobiol.2005.09.006