Numerical response of predator to prey: Dynamic interactions and population cycles in Eurasian lynx and roe deer

IF 7.1 1区 环境科学与生态学 Q1 ECOLOGY
Henrik Andrén, Olof Liberg
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引用次数: 0

Abstract

The dynamic interactions between predators and their prey have two fundamental processes: numerical and functional responses. Numerical response is defined as predator growth rate as a function of prey density or both prey and predator densities [dP/dt = f(N, P)]. Functional response is defined as the kill rate by an individual predator being a function of prey density or prey and predator densities combined. Although there are relatively many studies on the functional response in mammalian predators, the numerical response remains poorly documented. We studied the numerical response of Eurasian lynx (Lynx lynx) to various densities of its primary prey species, roe deer (Capreolus capreolus), and to itself (lynx). We exploited an unusual natural situation, spanning three decades where lynx, after a period of absence in central and southern Sweden, during which roe deer populations had grown to high densities, subsequently recolonized region after region, from north to south. We divided the study area into seven regions, with increasing productivity from north to south. We found strong effects of both roe deer density and lynx density on lynx numerical response. Thus, both resources and intraspecific competition for these resources are important to understanding the lynx population dynamic. We built a series of deterministic lynx–roe deer models, and applied them to the seven regions. We found a very good fit between these Lotka–Volterra type models and the data. The deterministic models produced almost cyclic dynamics or dampened cycles in five of the seven regions. Thus, we documented population cycles in this large predator–large herbivore system, which is rarely done. The amplitudes in the dampened cycles decreased toward the south. Thus, the dynamics between lynx and roe deer became more stable with increasing carrying capacity for roe deer, which is related to higher productivity in the environment. This increased stability could be explained by variation in predation risk, where human presence can act as prey refugia, and by a more diverse prey guild that will weaken the direct interaction between lynx and roe deer.

Abstract Image

捕食者对猎物的数字反应:欧亚猞猁和狍子的动态相互作用和种群周期
捕食者与猎物之间的动态相互作用有两个基本过程:数值反应和功能反应。数值反应是指捕食者的增长率是猎物密度或猎物密度和捕食者密度的函数[dP/dt = f(N, P)]。功能响应是指捕食者个体的捕杀率与猎物密度或猎物密度和捕食者密度的函数关系。尽管对哺乳动物捕食者功能响应的研究相对较多,但对数量响应的研究仍然很少。我们研究了欧亚猞猁(Lynx lynx)对其主要猎物狍子(Capreolus capreolus)和自身(猞猁)的不同密度的数量反应。猞猁在瑞典中部和南部消失了一段时间,在此期间狍子的数量增长到了很高的密度,随后猞猁从北到南重新占领了一个又一个地区。我们将研究区域划分为七个地区,生产力从北向南递增。我们发现,狍子密度和猞猁密度对猞猁数量反应的影响都很大。因此,资源和种内资源竞争对于了解猞猁种群动态都很重要。我们建立了一系列确定性的猞猁-狍子模型,并将其应用于七个地区。我们发现这些洛特卡-伏特拉(Lotka-Volterra)型模型与数据的拟合度非常高。在七个地区中,有五个地区的确定性模型产生了几乎是周期性的动态或减弱的周期。因此,我们在这个大型食肉动物-大型食草动物系统中记录了种群周期,而这是很少见的。阻尼周期的振幅向南减小。因此,随着狍子承载能力的增加,猞猁和狍子之间的动态关系变得更加稳定,这与环境中更高的生产力有关。这种稳定性的提高可以用捕食风险的变化(人类的存在可以成为猎物的避难所)以及猎物种类的增加来解释,因为猎物种类的增加会削弱猞猁和狍子之间的直接相互作用。
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来源期刊
Ecological Monographs
Ecological Monographs 环境科学-生态学
CiteScore
12.20
自引率
0.00%
发文量
61
审稿时长
3 months
期刊介绍: The vision for Ecological Monographs is that it should be the place for publishing integrative, synthetic papers that elaborate new directions for the field of ecology. Original Research Papers published in Ecological Monographs will continue to document complex observational, experimental, or theoretical studies that by their very integrated nature defy dissolution into shorter publications focused on a single topic or message. Reviews will be comprehensive and synthetic papers that establish new benchmarks in the field, define directions for future research, contribute to fundamental understanding of ecological principles, and derive principles for ecological management in its broadest sense (including, but not limited to: conservation, mitigation, restoration, and pro-active protection of the environment). Reviews should reflect the full development of a topic and encompass relevant natural history, observational and experimental data, analyses, models, and theory. Reviews published in Ecological Monographs should further blur the boundaries between “basic” and “applied” ecology. Concepts and Synthesis papers will conceptually advance the field of ecology. These papers are expected to go well beyond works being reviewed and include discussion of new directions, new syntheses, and resolutions of old questions. In this world of rapid scientific advancement and never-ending environmental change, there needs to be room for the thoughtful integration of scientific ideas, data, and concepts that feeds the mind and guides the development of the maturing science of ecology. Ecological Monographs provides that room, with an expansive view to a sustainable future.
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