Summary
The bluefin tuna heart remains at ambient water temperature (Ta) but must supply blood to warm regions of the body served by countercurrent vascular heat exchangers. Despite this unusual physiology, inherent difficulties have precluded an understanding of the cardiovascular responses to Ta in free-swimming bluefin tunas. We measured the heart rate (fH) responses of two captive Pacific bluefin tunas (Thunnus orientalis; 9.7 and 13.3 kg) over a cumulative period of 40 d. Routine fH during fasting in the holding tank at a Ta of 20°C was 45.1±8.0 and 40.7±6.5 beats min-1 for Tuna 1 and Tuna 2, respectively. fH decreased in each fish with Q10 of 2.6 (Tuna 1) and 3.1 (Tuna 2) as Ta in the tank was slowly decreased to 15°C (~0.4oC h-1), despite a gradual increase in swimming speed. The same thermal challenge during digestion revealed similar thermal dependence of fH and indicated that the rate of visceral cooling is not buffered by the heat increment of feeding. Acutely decreasing Ta from 20 to 10°C while Tuna 1 swam in a tunnel respirometer caused a progressive increase in tail beat-frequency and oxygen consumption rate (Mo2). fH of this fish decreased with Q10 of 2.7 as Ta decreased between 20 and 15°C, while further cooling to 10°C saw a general plateau in fH around 35 beats min-1 with Q10 of 1.3. A discussion of the relationships between fH, Mo2 , and haemoglobin-oxygen binding sheds further light on how bluefin cardiorespiratory systems function in a changing thermal environment.
