水体离子组成对虹鳟鱼在静息和持续运动时高碳酸血症期间酸碱调节的影响。

Effects of water ionic composition on acid-base regulation in rainbow trout, during hypercarbia at rest and during sustained exercise.

作者信息

Tovey Katelyn J, Brauner Colin J

机构信息

Department of Zoology, University of British Columbia, 6270 University Boulevard, Vancouver, BC, V6T 1Z4, Canada.

出版信息

J Comp Physiol B. 2018 Mar;188(2):295-304. doi: 10.1007/s00360-017-1129-y. Epub 2017 Oct 24.

DOI:10.1007/s00360-017-1129-y

PMID:29067494

Abstract

Aquatic hypercarbia (elevated environmental CO) results in a blood acidosis in fish, which is compensated by the exchange of Na and/or Cl for its acid/base counterpart (H, HCO) across the gill epithelium. To date, no studies exist on how a single species, capable of inhabiting both fresh and saltwater, responds to hypercarbia, at rest or during sustained exercise. Rainbow trout was acclimated to soft water (in mmol l: Na, 0.08; Cl, 0.05; pH 6.7-6.8), hard water (in mmol l: Na, 2.4; Cl, 0.2; pH 7.9-8.0), or 85% saltwater (28 ppt) (in mmol l: Na, 410; Cl, 476; pH 7.8-8.0). Acid-base relevant blood parameters were measured during a 1 kPa CO hypercarbia exposure, both at rest and during sustained exercise (~ 60% U ). After 48 h of hypercarbia, resting hard-, and saltwater trout fully restored blood pH, whereas soft-water-acclimated trout was only 60.6 ± 10.5% recovered. In all fish, recovery was associated with an increase in plasma [HCO] and an equimolar reduction in plasma [Cl]. Following 8 h of hypercarbia during sustained exercise, saltwater fish fully restored blood pH, while soft- and hard water fish were 42 ± 18.1 and 64 ± 6.8% recovered, respectively. Results provide intra-specific support demonstrating that saltwater acclimated fish acid-base compensate faster than freshwater fish during hypercarbia. Furthermore, data indicate that recovery during hypercarbia in trout is more rapid during exercise than rest. This not only demonstrates an important link between ambient water ion levels and ability to recover from acid-base disturbances, but also it presents novel data, suggesting that exercise may enhance acid-base regulation.

摘要

水体高碳酸血症（环境中二氧化碳升高）会导致鱼类血液酸中毒，这可通过鳃上皮细胞中钠和/或氯与其酸碱对应物（氢离子、碳酸氢根离子）的交换来代偿。迄今为止，尚无关于单一物种（既能栖息于淡水又能栖息于咸水）在静止或持续运动状态下如何应对高碳酸血症的研究。虹鳟鱼分别适应软水（单位：毫摩尔/升：钠，0.08；氯，0.05；pH值6.7 - 6.8）、硬水（单位：毫摩尔/升：钠，2.4；氯，0.2；pH值7.9 - 8.0）或85%的咸水（28‰）（单位：毫摩尔/升：钠，410；氯，476；pH值7.8 - 8.0）。在1千帕二氧化碳高碳酸血症暴露期间，分别于静止和持续运动（约60%的最大摄氧量）状态下测量与酸碱相关的血液参数。高碳酸血症持续48小时后，静止状态下适应硬水和咸水的鳟鱼能完全恢复血液pH值，而适应软水的鳟鱼仅恢复了60.6±10.5%。在所有鱼类中，恢复都与血浆中碳酸氢根离子浓度升高以及血浆中氯离子浓度等摩尔减少有关。在持续运动期间高碳酸血症持续8小时后，咸水鱼能完全恢复血液pH值，而软水和硬水鱼分别恢复了42±18.1%和64±6.8%。研究结果提供了种内证据，表明在高碳酸血症期间，适应咸水的鱼类比适应淡水的鱼类酸碱代偿更快。此外，数据表明虹鳟鱼在高碳酸血症期间运动时的恢复比静止时更快。这不仅证明了环境水体离子水平与从酸碱紊乱中恢复能力之间的重要联系，还提供了新的数据，表明运动可能增强酸碱调节能力。