Density-Dependent Individual and Population-Level Metabolic Rates in a Suite of Single-Celled Eukaryotes

J. Delong, D. Hanson
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引用次数: 13

Abstract

Population level metabolic rates are by definition the sum of the individual metabolic rates within a population. Several studies have used estimates of individual metabolic rates to scale up metabolic activity of individuals to popula- tions or whole communities. However, for aquatic single-celled organisms, individual metabolic rate is related to per- capita resource availability, and accounting for this fact is essential for obtaining accurate estimates of population- or community-level metabolism. We frame the problem with a simple model of resource division that predicts per capita metabolic rate should decline with increasing density. We allow the magnitude of density-dependence to be adjusted by intraspecific competition, from perfectly dependent to completely independent of density. Our results demonstrate that per-capita metabolic rate of single-celled eukaryotes is indeed inversely related to density via the per-capita availability of resources, and this has a significant effect on population-level metabolic rates. Suppression of individual metabolic rate occurred up to an order of magnitude, and although this magnitude of suppression has been seen in starved protists, our results indicate that a broad continuum of density-dependence governs the resource-dependent variability in metabolic rates for these organisms. The species we used cover a range of resource acquisition modes and phylogenies, suggesting that density-dependence of metabolic rate may be widespread in aquatic unicells.
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一组单细胞真核生物的密度依赖性个体和群体水平代谢率
根据定义,种群水平代谢率是种群内个体代谢率的总和。一些研究已经使用个体代谢率的估计来将个体的代谢活动扩大到群体或整个社区。然而,对于水生单细胞生物,个体代谢率与人均可利用资源有关,考虑到这一事实对于准确估计种群或社区水平的代谢至关重要。我们用一个简单的资源分配模型来描述这个问题,该模型预测人均代谢率应该随着密度的增加而下降。我们允许密度依赖的大小通过种内竞争来调整,从完全依赖到完全独立于密度。我们的研究结果表明,单细胞真核生物的人均代谢率确实通过人均资源可得性与密度成反比,这对种群水平的代谢率有显著影响。个体代谢率的抑制高达一个数量级,尽管在饥饿的原生生物中也发现了这种程度的抑制,但我们的研究结果表明,这些生物的代谢率的资源依赖性变异性是由密度依赖性的广泛连续体控制的。我们使用的物种涵盖了一系列资源获取模式和系统发育,这表明代谢率的密度依赖性可能在水生单细胞中广泛存在。
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