Reeve Connor, Smith Kurtis A, Bzonek Paul A, Cooke Steven J, Blanchfield Paul J, Brownscombe Jacob W
Department of Biology, Carleton University, Ottawa, Ontario, Canada.
Great Lakes Laboratory for Fisheries and Aquatic Sciences, Fisheries and Oceans Canada, Burlington, Ontario, Canada.
J Fish Biol. 2024 Dec;105(6):1769-1783. doi: 10.1111/jfb.15916. Epub 2024 Sep 3.
Bioenergetics models are powerful tools used to address a range of questions in fish biology. However, these models are rarely informed by free-swimming activity data, introducing error. To quantify the costs of activity in free-swimming fish, calibrations produced from standardized laboratory trials can be applied to estimate energy expenditure from sensor data for specific tags and species. Using swim tunnel respirometry, we calibrated acceleration sensor-equipped transmitting tags to estimate the aerobic metabolic rates (ṀO) of lake trout (Salvelinus namaycush) at three environmentally relevant temperatures. Aerobic and swim performance were also assessed. Like other calibrations, we found strong relationships between ṀO and acceleration or swimming speed, and jackknife validations and data simulations suggest that our models accurately predict metabolic costs of activity in adult lake trout (~5% algebraic error and ~20% absolute error). Aerobic and swim performance metrics were similar to those reported in other studies, but their critical swimming speed was lower than expected. Additionally, lake trout exhibited a wide aerobic scope, suggesting that the avoidance of waters ≥15°C may be related to selection for optimal growing temperatures. The ability to quantify the free-swimming energetic costs of activity will advance our understanding of lake trout ecology and may yield improvements to bioenergetics model.
生物能量学模型是用于解决鱼类生物学中一系列问题的强大工具。然而,这些模型很少依据自由游动活动数据构建,从而引入了误差。为了量化自由游动鱼类的活动成本,可以应用标准化实验室试验得出的校准结果,根据特定标签和物种的传感器数据来估算能量消耗。我们使用游泳隧道呼吸测量法,对配备加速度传感器的发射标签进行校准,以估算湖鳟(Salvelinus namaycush)在三个与环境相关的温度下的有氧代谢率(ṀO)。同时还评估了有氧能力和游泳表现。与其他校准一样,我们发现ṀO与加速度或游泳速度之间存在很强的相关性,留一法验证和数据模拟表明,我们的模型能够准确预测成年湖鳟活动的代谢成本(代数误差约为5%,绝对误差约为20%)。有氧能力和游泳表现指标与其他研究报告的相似,但其临界游泳速度低于预期。此外,湖鳟表现出较宽的有氧代谢范围,这表明避开温度≥15°C的水域可能与选择最佳生长温度有关。量化自由游动活动的能量成本的能力将推动我们对湖鳟生态学的理解,并可能改进生物能量学模型。
