Experiment: Elevated temperature and PCO2 affect enzyme activities in differentially oxidative tissues of Notothenia rossii

Mitochondrial plasticity plays a central role in setting the capacity for acclimation of aerobic metabolism in ectotherms in response to environmental changes. We still lack a clear picture if and to what extent the energy metabolism and mitochondrial enzymes of Antarctic fish can compensate for cha...

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Bibliographic Details
Main Authors: Strobel, Anneli, Leo, Elettra, Pörtner, Hans-Otto, Mark, Felix Christopher
Format: Dataset
Language:English
Published: PANGAEA 2014
Subjects:
Carbon dioxide
partial pressure
Carlini/Jubany Station
Citrate synthase activity
per protein
Citrate synthase activity per fresh mass
Cytochrome c oxidase activity
per fresh mass
Identification
Jubany_Dallmann
MULT
Multiple investigations
PotterCove
Potter Cove
King George Island
Antarctic Peninsula
Priority Programme 1158 Antarctic Research with Comparable Investigations in Arctic Sea Ice Areas
Species
SPP1158
Temperature
technical
Arctic
Antarctic
The Antarctic
Antarc*
Notothenia rossii
Sea ice
Online Access:https://doi.pangaea.de/10.1594/PANGAEA.829831
https://doi.org/10.1594/PANGAEA.829831
Description
Summary:Mitochondrial plasticity plays a central role in setting the capacity for acclimation of aerobic metabolism in ectotherms in response to environmental changes. We still lack a clear picture if and to what extent the energy metabolism and mitochondrial enzymes of Antarctic fish can compensate for changing temperatures or PCO2 and whether capacities for compensation differ between tissues. We therefore measured activities of key mitochondrial enzymes (citrate synthase (CS), cytochrome c oxidase (COX)) from heart, red muscle, white muscle and liver in the Antarctic fish Notothenia rossii after warm- (7 °C) and hypercapnia- (0.2 kPa CO2) acclimation vs. control conditions (1 °C, 0.04 kPa CO2). In heart, enzymes showed elevated activities after cold-hypercapnia acclimation, and a warm-acclimation-induced upward shift in thermal optima. The strongest increase in enzyme activities in response to hypercapnia occurred in red muscle. In white muscle, enzyme activities were temperature-compensated. CS activity in liver decreased after warm-normocapnia acclimation (temperature-compensation), while COX activities were lower after cold- and warm-hypercapnia exposure, but increased after warm-normocapnia acclimation. In conclusion, warm-acclimated N. rossii display low thermal compensation in response to rising energy demand in highly aerobic tissues, such as heart and red muscle. Chronic environmental hypercapnia elicits increased enzyme activities in these tissues, possibly to compensate for an elevated energy demand for acid-base regulation or a compromised mitochondrial metabolism, that is predicted to occur in response to hypercapnia exposure. This might be supported by enhanced metabolisation of liver energy stores. These patterns reflect a limited capacity of N. rossii to reorganise energy metabolism in response to rising temperature and PCO2.

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