Department of Anatomy, Cell Biology and Zoology, University of Extremadura, Badajoz, Spain.
PLoS One. 2012;7(7):e42206. doi: 10.1371/journal.pone.0042206. Epub 2012 Jul 31.
Basal metabolic rate (BMR) is closely linked to different habitats and way of life. In birds, some studies have noted that BMR is higher in marine species compared to those inhabiting terrestrial habitats. However, the extent of such metabolic dichotomy and its underlying mechanisms are largely unknown. Migratory shorebirds (Charadriiformes) offer a particularly interesting opportunity for testing this marine-non-marine difference as they are typically divided into two broad categories in terms of their habitat occupancy outside the breeding season: 'coastal' and 'inland' shorebirds. Here, we measured BMR for 12 species of migratory shorebirds wintering in temperate inland habitats and collected additional BMR values from the literature for coastal and inland shorebirds along their migratory route to make inter- and intraspecific comparisons. We also measured the BMR of inland and coastal dunlins Calidris alpina wintering at a similar latitude to facilitate a more direct intraspecific comparison. Our interspecific analyses showed that BMR was significantly lower in inland shorebirds than in coastal shorebirds after the effects of potentially confounding climatic (latitude, temperature, solar radiation, wind conditions) and organismal (body mass, migratory status, phylogeny) factors were accounted for. This indicates that part of the variation in basal metabolism might be attributed to genotypic divergence. Intraspecific comparisons showed that the mass-specific BMR of dunlins wintering in inland freshwater habitats was 15% lower than in coastal saline habitats, suggesting that phenotypic plasticity also plays an important role in generating these metabolic differences. We propose that the absence of tidally-induced food restrictions, low salinity, and less windy microclimates associated with inland freshwater habitats may reduce the levels of energy expenditure, and hence BMR. Further research including common-garden experiments that eliminate phenotypic plasticity as a source of phenotypic variation is needed to determine to what extent these general patterns are attributable to genotypic adaptation.
基础代谢率 (BMR) 与不同的栖息地和生活方式密切相关。在鸟类中,一些研究指出,与栖息在陆地栖息地的鸟类相比,海洋物种的 BMR 更高。然而,这种代谢二分法的程度及其潜在机制在很大程度上尚不清楚。迁徙涉禽(Charadriiformes)为测试这种海洋与非海洋差异提供了一个特别有趣的机会,因为它们在繁殖季节之外通常根据其栖息地占用情况分为两大类:“沿海”和“内陆”涉禽。在这里,我们测量了 12 种迁徙涉禽在温带内陆栖息地越冬时的 BMR,并从文献中收集了沿海和内陆涉禽在迁徙途中的额外 BMR 值,以进行种间和种内比较。我们还测量了在相似纬度越冬的内陆和沿海黑腹滨鹬 Calidris alpina 的 BMR,以方便更直接的种内比较。我们的种间分析表明,在考虑了潜在的混杂气候(纬度、温度、太阳辐射、风况)和生物体(体重、迁徙状态、系统发育)因素后,内陆涉禽的 BMR 明显低于沿海涉禽。这表明基础代谢的部分变异可能归因于基因型分歧。种内比较表明,在内陆淡水栖息地越冬的黑腹滨鹬的比质量 BMR 比在沿海咸水栖息地低 15%,这表明表型可塑性也在产生这些代谢差异方面发挥了重要作用。我们提出,与内陆淡水栖息地相关的潮汐引起的食物限制减少、低盐度和较少的风的小气候可能会降低能量消耗水平,从而降低 BMR。需要进行包括共同饲养实验在内的进一步研究,以消除表型可塑性作为表型变异的来源,以确定这些一般模式在多大程度上归因于基因型适应。
