The autonomic control and functional significance of the changes in heart rate associated with air breathing in the jeju, Hoplerythrinus unitaeniatus

• Published in: Journal of experimental biology Vol. 210; no. Pt 23; pp. 4224 - 4232
• Main Authors: McKenzie, D J, Campbell, H A, Taylor, E W, Micheli, M, Rantin, F T, Abe, A S
• Format: Journal Article
• Language: English
• Published: England 01.12.2007
• Subjects: Adrenergic Antagonists - pharmacology; Air; Animals; Autonomic Nervous System - drug effects; Autonomic Nervous System - physiology; Behavior, Animal - drug effects; Behavior, Animal - physiology; Cholinergic Antagonists - pharmacology; Female; Fishes - physiology; Freshwater; Heart Rate - drug effects; Heart Rate - physiology; Hoplerythrinus unitaeniatus; Hypoxia; Male; Oxygen Consumption - drug effects; Respiration - drug effects; Teleostei
• ISSN: 0022-0949; 1477-9145
• DOI: 10.1242/jeb.009266

The jeju is a teleost fish with bimodal respiration that utilizes a modified swim bladder as an air-breathing organ (ABO). Like all air-breathing fish studied to date, jeju exhibit pronounced changes in heart rate (fH) during air-breathing events, and it is believed that these may facilitate oxygen uptake (MO2) from the ABO. The current study employed power spectral analysis (PSA) of fH patterns, coupled with instantaneous respirometry, to investigate the autonomic control of these phenomena and their functional significance for the efficacy of air breathing. The jeju obtained less than 5% of total MO2 (MtO2) from air breathing in normoxia at 26 degrees C, and PSA of beat-to-beat variability in fH revealed a pattern similar to that of unimodal water-breathing fish. In deep aquatic hypoxia (water PO2)=1 kPa) the jeju increased the frequency of air breathing (fAB) tenfold and maintained MtO2 unchanged from normoxia. This was associated with a significant increase in heart rate variability (HRV), each air breath (AB) being preceded by a brief bradycardia and then followed by a brief tachycardia. These fH changes are qualitatively similar to those associated with breathing in unimodal air-breathing vertebrates. Within 20 heartbeats after the AB, however, a beat-to-beat variability in fH typical of water-breathing fish was re-established. Pharmacological blockade revealed that both adrenergic and cholinergic tone increased simultaneously prior to each AB, and then decreased after it. However, modulation of inhibitory cholinergic tone was responsible for the major proportion of HRV, including the precise beat-to-beat modulation of fH around each AB. Pharmacological blockade of all variations in fH associated with air breathing in deep hypoxia did not, however, have a significant effect upon fAB or the regulation of MtO2. Thus, the functional significance of the profound HRV during air breathing remains a mystery.