The electrocardiogram of vertebrates: Evolutionary changes from ectothermy to endothermy

The electrocardiogram (ECG) reveals that heart chamber activation and repolarization are much faster in mammals and birds compared to ectothermic vertebrates of similar size. Temperature, however, affects electrophysiology of the heart and most data from ectotherms are determined at body temperature...

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Bibliographic Details
Published in:Progress in biophysics and molecular biology 2019-07, Vol.144, p.16-29
Main Authors: Boukens, Bastiaan J.D., Kristensen, Ditte L., Filogonio, Renato, Carreira, Laura B.T., Sartori, Marina R., Abe, Augusto S., Currie, Shannon, Joyce, William, Conner, Justin, Opthof, Tobias, Crossley, Dane A., Wang, Tobias, Jensen, Bjarke
Format: Article
Language:English
Subjects:
Animals
Biological Evolution
Body Temperature Regulation
Electrocardiography
Heart - physiology
Humans
Vertebrates - physiology
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Summary:The electrocardiogram (ECG) reveals that heart chamber activation and repolarization are much faster in mammals and birds compared to ectothermic vertebrates of similar size. Temperature, however, affects electrophysiology of the heart and most data from ectotherms are determined at body temperatures lower than those of mammals and birds. The present manuscript is a review of the effects of temperature on intervals in the ECG of ectothermic and endothermic vertebrates rather than a hypothesis-testing original research article. However, the conclusions are supported by the inclusion of original data (Iguana iguana, N = 4; Python regius, N = 5; Alligator mississippiensis, N = 4). Most comparisons were of animals of approximately 1 kg. Compared to mammals and birds, the reptiles at 35–37 °C had 4 fold lower heart rates, 2 fold slower atrial and ventricular conduction (longer P- and QRS-wave durations), and 4 fold longer PR intervals (atrioventricular delay) and QT intervals (total ventricular repolarization). We conclude that the faster chamber activation in endotherms cannot be explained by temperature alone. Based on histology, we show that endotherms have a more compact myocardial architecture. In mammals, disorganization of the compact wall by fibrosis associates with conduction slowing and we suggest the compact tissue architecture allows for faster chamber activation. The short cardiac cycle that characterizes mammals and birds, however, is predominantly accommodated by shortening of the atrioventricular delay and the QT interval, which is so long in a 1 kg iguana that it compares to that of an elephant.
ISSN:0079-6107
1873-1732
DOI:10.1016/j.pbiomolbio.2018.08.005