Department of Zoology, The University of British Columbia, 6270 University Blvd, Vancouver, BC, Canada, V6T 1Z4.
Department of Biology, Wilfrid Laurier University, 75 University Avenue, Waterloo, ON, Canada, N2L 3C5.
J Exp Biol. 2022 Sep 15;225(18). doi: 10.1242/jeb.243500. Epub 2022 Sep 22.
Phenotypic divergence is a hallmark of adaptive radiation. One example involves differentiation in physiological traits involved in ion regulation among species with contrasting lifestyles and living in distinct environments. Differentiation in ion regulation and its ecological implications among populations within species are, however, less well understood. To address this knowledge gap, we collected prickly sculpin (Cottus asper) from distinct habitat types including coastal rivers connected to estuaries, coastal lakes and interior lakes, all from British Columbia, Canada. We tested for differences in plasma Na+ and Cl-, gill Na+/K+-ATPase and H+-ATPase activity and protein abundance as well as changes in body mass and arterial blood pH in fish sampled from the field and acclimated to two different freshwater conditions in the laboratory: artificial lake water (ALW) and ion-poor water (IPW). We also tested for links between environmental water chemistry and the physiological characteristics associated with ion regulation. Transfer to IPW resulted in upregulation of gill Na+/K+-ATPase and H+-ATPase activity as well as increases in gill H+-ATPase protein expression level in each habitat compared with that in the common ALW treatment. Despite the presence of population-within-habitat-type differences, significant habitat-type effects were revealed in most of the ion regulation characteristics examined under different acclimation conditions. Significantly lower plasma Cl- was detected in fish from coastal rivers than in fish from the other two habitat types during the IPW treatment, which was also significantly lower compared with that in ALW. Similarly, gill Na+/K+-ATPase activity was lower in the coastal river populations in IPW than in fish from coastal and interior lakes, which was not in accordance with the protein expression in the gill. For gill H+-ATPase, fish from interior lake populations had the highest level of activity across all habitat types under all conditions, which was related to the protein levels in the gill. The activity of gill H+-ATPase was positively correlated with the combined effect of water Na+ and pH under the ALW treatment. Our results suggest that variation in habitat may be an important factor driving differences in gill Na+/K+-ATPase and H+-ATPase activity across populations of C. asper. Further, the combined effect of water Na+ and pH may have played a key role in physiological adaptation in C. asper during post-glacial freshwater colonization and dispersal.
表型分异是适应辐射的一个标志。一个例子是涉及生活方式截然不同且生活在不同环境中的物种在离子调节方面的生理特征的分化。然而,对于物种内种群之间离子调节的分化及其生态意义,我们的了解还比较有限。为了填补这一知识空白,我们从加拿大不列颠哥伦比亚省的不同生境类型中收集了刺鲈(Cottus asper),包括与河口相连的沿海河流、沿海湖泊和内陆湖泊。我们测试了来自野外的鱼类在实验室中适应两种不同淡水条件(人工湖水(ALW)和贫水(IPW))后的血浆 Na+和 Cl-、鳃 Na+/K+-ATP 酶和 H+-ATP 酶活性和蛋白丰度的差异,以及体重和动脉血 pH 的变化。我们还测试了环境水化学与离子调节相关的生理特征之间的联系。转移到 IPW 导致在每个生境类型中,与常见的 ALW 处理相比,鳃 Na+/K+-ATP 酶和 H+-ATP 酶活性以及鳃 H+-ATP 酶蛋白表达水平上调。尽管存在生境内种群类型的差异,但在不同适应条件下,大多数离子调节特征都显示出显著的生境类型效应。在 IPW 处理期间,来自沿海河流的鱼类的血浆 Cl-明显低于其他两种生境类型的鱼类,与 ALW 相比也明显降低。同样,在 IPW 中,沿海河流种群的鳃 Na+/K+-ATP 酶活性也低于沿海和内陆湖泊的鱼类,这与鳃中的蛋白表达不一致。对于鳃 H+-ATP 酶,在所有条件下,所有生境类型中内陆湖泊种群的活性最高,这与鳃中的蛋白水平有关。在 ALW 处理下,鳃 H+-ATP 酶的活性与水 Na+和 pH 的综合效应呈正相关。我们的研究结果表明,生境的变化可能是驱动 C. asper 种群鳃 Na+/K+-ATP 酶和 H+-ATP 酶活性差异的一个重要因素。此外,水 Na+和 pH 的综合效应可能在 C. asper 后冰河淡水殖民和扩散过程中的生理适应中发挥了关键作用。
