KIDDER, G.W.,III*; GOLDSMITH, C.E.; NEVILLE, M.J.; PETERSEN, C.W.; PRESTON, R.P.; Mt. Desert Isl. Bio. Lab, Salisbury Cove, ME; Illinois St. Univ., Normal, IL; Illinois St. Univ., Normal, IL; College of the Atlantic, Bar Harbor, ME; Illinois St. Univ., Normal, IL: Basal Oxygen Consumption in Fundulus heteroclitus
The basal oxygen consumption of F. heteroclitus is needed for further investigations of the energetics of osmoregulation. We used flow-through respirometry, bubbling gas through the water containing the fish, through a drying tube to remove water and carbon dioxide, through an oxygen sensor and a mass flow meter, both read every 15 seconds by a computer. During each 24 hour run, a solenoid valve bypassed the fish chamber 20 times for 7.5 minutes each, to recalibrate the oxygen sensor. Thus 20 readings of QO2 (ml O2/kg�hr) were obtained per 24 hour period while holding the oxygen tension within 0.5% of its target value. Fish were acclimated to seawater and tested in seawater. QO2 decreased over 50% during the first 12 hours in the chamber, remaining constant thereafter; the values from 12 to 24 hours after any change are taken as the basal rate in that condition. We find that oxygen consumption is a function of temperature (Q10 = 2.65) and of fish size, as expected. We searched for circadian or tidal rhythms in respiration without finding any. We have determined the effect of lowered oxygen tension on QO2. At 10.5 C, 50% inhibition occurs at about 5% oxygen, with excellent 24 hour survival. We calculate a minimum ventilation rate of 12.09 � 0.58 ml water/kg fish�hr in air, which is increased to 26.01 � 2.68 in 5% oxygen. This is consistent with the widely held assumption that low oxygen availability might impose limits on adaptation to other stressors such as osmotic challenges. This suggests a method for increasing the energy demand due to osmotic work. [Sup. by NSF-CRUI 0111860 to RLP, GWK and CWP]