Maldonado Karin, Sabat Pablo, Piriz Gabriela, Bogdanovich José M, Nespolo Roberto F, Bozinovic Francisco
Departamento de Ciencias Ecológicas, Facultad de Ciencias, Universidad de Chile Santiago, Chile.
Departamento de Ciencias Ecológicas, Facultad de Ciencias, Universidad de ChileSantiago, Chile; Center of Applied Ecology and Sustainability, Pontificia Universidad Católica de ChileSantiago, Chile.
Front Physiol. 2016 Dec 27;7:649. doi: 10.3389/fphys.2016.00649. eCollection 2016.
Food availability varies substantially throughout animals' lifespans, thus the ability to profit from high food levels may directly influence animal fitness. Studies exploring the link between basal metabolic rate (BMR), growth, reproduction, and other fitness traits have shown varying relationships in terms of both magnitude and direction. The diversity of results has led to the hypothesis that these relationships are modulated by environmental conditions (e.g., food availability), suggesting that the fitness consequences of a given BMR may be context-dependent. In turn, there is indirect evidence that individuals with an increased capacity for aerobic work also have a high capacity for acquiring energy from food. Surprisingly, very few studies have explored the correlation between maximum rates of energy acquisition and BMR in endotherms, and to the best of our knowledge, none have attempted to elucidate relationships between the former and aerobic capacity [e.g., maximum metabolic rate (MMR), aerobic scope (Factorial aerobic scope, FAS; Net aerobic scope, NAS)]. In this study, we measured BMR, MMR, maximum food intake (recorded under low ambient temperature and food conditions; MFI), and estimated aerobic scope in the leaf-eared mouse (). We, then, examined correlations among these variables to determine whether metabolic rates and aerobic scope are functionally correlated, and whether an increased aerobic capacity is related to a higher MFI. We found that aerobic capacity measured as NAS is positively correlated with MFI in endotherms, but with neither FAS nor BMR. Therefore, it appears plausible that the capacity for assimilating energy under conditions of abundant resources is determined adaptively by NAS, as animals with higher NAS would be promoted by selection. In theory, FAS is an invariant measurement of the extreme capacity for energy turnover in relation to resting expenditure, whereas NAS represents the maximum capacity for simultaneous aerobic processes above maintenance levels. Accordingly, in our study, FAS and NAS represent different biological variables; FAS, in contrast to NAS, may not constrain food intake. The explanations for these differences are discussed in biological and mathematical terms; further, we encourage the use of NAS rather than FAS when analyzing the aerobic capacity of animals.
食物可利用性在动物的整个生命周期中差异很大,因此从高食物水平中获取益处的能力可能直接影响动物的适应性。探索基础代谢率(BMR)、生长、繁殖和其他适应性特征之间联系的研究表明,在幅度和方向方面存在不同的关系。结果的多样性导致了这样一种假设,即这些关系受到环境条件(如食物可利用性)的调节,这表明给定BMR的适应性后果可能取决于具体情境。反过来,有间接证据表明,有氧工作能力增强的个体从食物中获取能量的能力也很高。令人惊讶的是,很少有研究探讨恒温动物能量获取最大速率与BMR之间的相关性,据我们所知,也没有研究试图阐明前者与有氧能力[如最大代谢率(MMR)、有氧范围(阶乘有氧范围,FAS;净有氧范围,NAS)]之间的关系。在本研究中,我们测量了叶耳鼠的BMR、MMR、最大食物摄入量(在低环境温度和食物条件下记录;MFI),并估计了其有氧范围。然后,我们检查了这些变量之间的相关性,以确定代谢率和有氧范围是否在功能上相关,以及有氧能力的增强是否与更高的MFI相关。我们发现,以NAS衡量的有氧能力与恒温动物的MFI呈正相关,但与FAS和BMR均无相关性。因此,在资源丰富的条件下,同化能量的能力由NAS适应性地决定似乎是合理的,因为具有较高NAS的动物会受到自然选择的青睐。理论上,FAS是相对于静息能量消耗的能量周转极限能力的不变量度,而NAS代表维持水平以上同时进行有氧过程的最大能力。因此,在我们的研究中,FAS和NAS代表不同的生物学变量;与NAS不同,FAS可能不会限制食物摄入量。我们从生物学和数学角度讨论了这些差异的解释;此外,我们鼓励在分析动物的有氧能力时使用NAS而非FAS。
