A Protein Titration Hypothesis for the Temperature-Dependence of Tissue CO 2 Content in Reptiles and Amphibians

Whole-body CO2 stores are known to increase with cooling in reptiles and amphibians (-Δ[CO2]/ΔT ). The aim of this study was to determine the mechanism(s) producing this inverse relationship. The Δ[CO2]/ΔT coefficients were determined for eight reptilian and one amphibian species and were found to d...

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Main Authors: Stinner, J. N., Hartzler, Lynn K., Grguric, M. R., Newlon, D. L.
Format: Text
Language:unknown
Published: CORE Scholar 1998
Subjects:
Coluber constrictor
Reptiles
Amphibians
Temperature
Respiratory Exchange Ratio
Oxygen Consumption
Carbon Dioxide Production
Acid–Base Balance
pH
Protein Charge
Tissue Carbon Dioxide Content
Electrolytes
Skeletal Muscle
Biology
Life Sciences
Medical Sciences
Medicine and Health Sciences
Systems Biology
Carbonic acid
Online Access:https://corescholar.libraries.wright.edu/biology/175
http://jeb.biologists.org/content/201/3/415.full.pdf
id ftwrightuniv:oai:corescholar.libraries.wright.edu:biology-1205
record_format openpolar
spelling ftwrightuniv:oai:corescholar.libraries.wright.edu:biology-1205 2023-05-15T15:53:04+02:00 A Protein Titration Hypothesis for the Temperature-Dependence of Tissue CO 2 Content in Reptiles and Amphibians Stinner, J. N. Hartzler, Lynn K. Grguric, M. R. Newlon, D. L. 1998-02-01T08:00:00Z https://corescholar.libraries.wright.edu/biology/175 http://jeb.biologists.org/content/201/3/415.full.pdf unknown CORE Scholar https://corescholar.libraries.wright.edu/biology/175 http://jeb.biologists.org/content/201/3/415.full.pdf Biological Sciences Faculty Publications Coluber constrictor Reptiles Amphibians Temperature Respiratory Exchange Ratio Oxygen Consumption Carbon Dioxide Production Acid–Base Balance pH Protein Charge Tissue Carbon Dioxide Content Electrolytes Skeletal Muscle Biology Life Sciences Medical Sciences Medicine and Health Sciences Systems Biology text 1998 ftwrightuniv 2021-11-21T09:52:31Z Whole-body CO2 stores are known to increase with cooling in reptiles and amphibians (-Δ[CO2]/ΔT ). The aim of this study was to determine the mechanism(s) producing this inverse relationship. The Δ[CO2]/ΔT coefficients were determined for eight reptilian and one amphibian species and were found to differ by a factor of approximately 10, from -0.21 mmol kg-1 °C-1 in the Mediterranean spur-thighed tortoise Testudo graeca to -0.02 mmol kg-1 °C-1 in the bullfrog Rana catesbeiana. The Δ[CO2]/ΔT coefficients were correlated with values in the literature for in vivo plasma ΔpH/ΔT coefficients (Δ[CO2]/ΔT=-0.18--8.24ΔpH/ΔT; r2=0.87). Plasma electrolyte concentrations (Na+, K+, Ca2+, Mg2+, Cl-, inorganic phosphate, SO42- and lactate), [protein], [CO2], PCO2 and pH were measured in chronically cannulated resting black racer snakes Coluber constrictor. When the temperature was reduced from 30 to 10 °C, pH increased slightly (by -0.0028 pH units °C-1), PCO2 decreased by 7 mmHg, [CO2] increased by 3.2 mmol l-1 and [HPO42-+H2PO4-] increased by 0.7 mmol l-1. Concentrations of protein and of the remaining electrolytes were not significantly different (P>0.05) at 30 and 10 °C. Net plasma protein charge, calculated from the principle of electroneutrality (the sum of the cations in mequiv = the sum of anions in mequiv), was -0.48 mequiv g-1 protein at 30 °C and -0.38 mequiv g-1 protein at 10 °C. This 21 % decrease was attributed to the increases in [CO2] (i.e. carbonic acid) and inorganic phosphate concentration. Between 30 and 10 °C, skeletal muscle pH and [CO2] in C. constrictor increased (by -0.009 units °C-1 and -0.125 mmol kg-1 °C-1, respectively), [Na+] and [Cl-] each decreased by approximately 12 mequiv l-1, and [K+] and the percentage of water did not change significantly. It is concluded that the increase in whole-body CO2 stores with cooling in reptiles and amphibians results from the passive effects of temperature changes upon the ionization constants of proteins and the active adjustment of PCO2 (ventilatory regulation), so that -ΔpK is greater than -ΔpH. Active transmembrane ion-exchange processes do not appear to be involved. Text Carbonic acid Wright State University: CORE Scholar (Campus Online Repository)
institution Open Polar
collection Wright State University: CORE Scholar (Campus Online Repository)
op_collection_id ftwrightuniv
language unknown
topic Coluber constrictor
Reptiles
Amphibians
Temperature
Respiratory Exchange Ratio
Oxygen Consumption
Carbon Dioxide Production
Acid–Base Balance
pH
Protein Charge
Tissue Carbon Dioxide Content
Electrolytes
Skeletal Muscle
Biology
Life Sciences
Medical Sciences
Medicine and Health Sciences
Systems Biology
spellingShingle Coluber constrictor
Reptiles
Amphibians
Temperature
Respiratory Exchange Ratio
Oxygen Consumption
Carbon Dioxide Production
Acid–Base Balance
pH
Protein Charge
Tissue Carbon Dioxide Content
Electrolytes
Skeletal Muscle
Biology
Life Sciences
Medical Sciences
Medicine and Health Sciences
Systems Biology
Stinner, J. N.
Hartzler, Lynn K.
Grguric, M. R.
Newlon, D. L.
A Protein Titration Hypothesis for the Temperature-Dependence of Tissue CO 2 Content in Reptiles and Amphibians
topic_facet Coluber constrictor
Reptiles
Amphibians
Temperature
Respiratory Exchange Ratio
Oxygen Consumption
Carbon Dioxide Production
Acid–Base Balance
pH
Protein Charge
Tissue Carbon Dioxide Content
Electrolytes
Skeletal Muscle
Biology
Life Sciences
Medical Sciences
Medicine and Health Sciences
Systems Biology
description Whole-body CO2 stores are known to increase with cooling in reptiles and amphibians (-Δ[CO2]/ΔT ). The aim of this study was to determine the mechanism(s) producing this inverse relationship. The Δ[CO2]/ΔT coefficients were determined for eight reptilian and one amphibian species and were found to differ by a factor of approximately 10, from -0.21 mmol kg-1 °C-1 in the Mediterranean spur-thighed tortoise Testudo graeca to -0.02 mmol kg-1 °C-1 in the bullfrog Rana catesbeiana. The Δ[CO2]/ΔT coefficients were correlated with values in the literature for in vivo plasma ΔpH/ΔT coefficients (Δ[CO2]/ΔT=-0.18--8.24ΔpH/ΔT; r2=0.87). Plasma electrolyte concentrations (Na+, K+, Ca2+, Mg2+, Cl-, inorganic phosphate, SO42- and lactate), [protein], [CO2], PCO2 and pH were measured in chronically cannulated resting black racer snakes Coluber constrictor. When the temperature was reduced from 30 to 10 °C, pH increased slightly (by -0.0028 pH units °C-1), PCO2 decreased by 7 mmHg, [CO2] increased by 3.2 mmol l-1 and [HPO42-+H2PO4-] increased by 0.7 mmol l-1. Concentrations of protein and of the remaining electrolytes were not significantly different (P>0.05) at 30 and 10 °C. Net plasma protein charge, calculated from the principle of electroneutrality (the sum of the cations in mequiv = the sum of anions in mequiv), was -0.48 mequiv g-1 protein at 30 °C and -0.38 mequiv g-1 protein at 10 °C. This 21 % decrease was attributed to the increases in [CO2] (i.e. carbonic acid) and inorganic phosphate concentration. Between 30 and 10 °C, skeletal muscle pH and [CO2] in C. constrictor increased (by -0.009 units °C-1 and -0.125 mmol kg-1 °C-1, respectively), [Na+] and [Cl-] each decreased by approximately 12 mequiv l-1, and [K+] and the percentage of water did not change significantly. It is concluded that the increase in whole-body CO2 stores with cooling in reptiles and amphibians results from the passive effects of temperature changes upon the ionization constants of proteins and the active adjustment of PCO2 (ventilatory regulation), so that -ΔpK is greater than -ΔpH. Active transmembrane ion-exchange processes do not appear to be involved.
format Text
author Stinner, J. N.
Hartzler, Lynn K.
Grguric, M. R.
Newlon, D. L.
author_facet Stinner, J. N.
Hartzler, Lynn K.
Grguric, M. R.
Newlon, D. L.
author_sort Stinner, J. N.
title A Protein Titration Hypothesis for the Temperature-Dependence of Tissue CO 2 Content in Reptiles and Amphibians
title_short A Protein Titration Hypothesis for the Temperature-Dependence of Tissue CO 2 Content in Reptiles and Amphibians
title_full A Protein Titration Hypothesis for the Temperature-Dependence of Tissue CO 2 Content in Reptiles and Amphibians
title_fullStr A Protein Titration Hypothesis for the Temperature-Dependence of Tissue CO 2 Content in Reptiles and Amphibians
title_full_unstemmed A Protein Titration Hypothesis for the Temperature-Dependence of Tissue CO 2 Content in Reptiles and Amphibians
title_sort protein titration hypothesis for the temperature-dependence of tissue co 2 content in reptiles and amphibians
publisher CORE Scholar
publishDate 1998
url https://corescholar.libraries.wright.edu/biology/175
http://jeb.biologists.org/content/201/3/415.full.pdf
genre Carbonic acid
genre_facet Carbonic acid
op_source Biological Sciences Faculty Publications
op_relation https://corescholar.libraries.wright.edu/biology/175
http://jeb.biologists.org/content/201/3/415.full.pdf
_version_ 1766388127136481280

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