Amarasekare Priyanga
Department of Ecology and Evolutionary Biology, University of California Los Angeles, Los Angeles, CA, 90095, USA.
J Anim Ecol. 2015 May;84(3):665-679. doi: 10.1111/1365-2656.12320. Epub 2015 Jan 14.
Understanding how temperature variation influences the negative (e.g. self-limitation) and positive (e.g. saturating functional responses) feedback processes that characterize consumer-resource interactions is an important research priority. Previous work on this topic has yielded conflicting outcomes with some studies predicting that warming should increase consumer-resource oscillations and others predicting that warming should decrease consumer-resource oscillations. Here, I develop a consumer-resource model that both synthesizes previous findings in a common framework and yields novel insights about temperature effects on consumer-resource dynamics. I report three key findings. First, when the resource species' birth rate exhibits a unimodal temperature response, as demonstrated by a large number of empirical studies, the temperature range over which the consumer-resource interaction can persist is determined by the lower and upper temperature limits to the resource species' reproduction. This contrasts with the predictions of previous studies, which assume that the birth rate exhibits a monotonic temperature response, that consumer extinction is determined by temperature effects on consumer species' traits, rather than the resource species' traits. Secondly, the comparative analysis I have conducted shows that whether warming leads to an increase or decrease in consumer-resource oscillations depends on the manner in which temperature affects intraspecific competition. When the strength of self-limitation increases monotonically with temperature, warming causes a decrease in consumer-resource oscillations. However, if self-limitation is strongest at temperatures physiologically optimal for reproduction, a scenario previously unanalysed by theory but amply substantiated by empirical data, warming can cause an increase in consumer-resource oscillations. Thirdly, the model yields testable comparative predictions about consumer-resource dynamics under alternative hypotheses for how temperature affects competitive and resource acquisition traits. Importantly, it does so through empirically quantifiable metrics for predicting temperature effects on consumer viability and consumer-resource oscillations, which obviates the need for parameterizing complex dynamical models. Tests of these metrics with empirical data on a host-parasitoid interaction yield realistic estimates of temperature limits for consumer persistence and the propensity for consumer-resource oscillations, highlighting their utility in predicting temperature effects, particularly warming, on consumer-resource interactions in both natural and agricultural settings.
了解温度变化如何影响消费者 - 资源相互作用中具有代表性的负反馈(如自我限制)和正反馈(如饱和功能反应)过程,是一项重要的研究重点。此前关于该主题的研究得出了相互矛盾的结果,一些研究预测变暖会增加消费者 - 资源振荡,而另一些研究则预测变暖会减少消费者 - 资源振荡。在此,我构建了一个消费者 - 资源模型,该模型既在一个通用框架中综合了先前的研究结果,又对温度对消费者 - 资源动态的影响产生了新的见解。我报告了三个关键发现。第一,当资源物种的出生率呈现单峰温度响应时,正如大量实证研究所表明的那样,消费者 - 资源相互作用能够持续的温度范围由资源物种繁殖的下限和上限温度限制所决定。这与先前研究的预测形成对比,先前的研究假设出生率呈现单调温度响应,认为消费者灭绝是由温度对消费者物种特征的影响所决定,而非资源物种的特征。其次,我所进行的比较分析表明,变暖导致消费者 - 资源振荡增加还是减少取决于温度影响种内竞争的方式。当自我限制的强度随温度单调增加时,变暖会导致消费者 - 资源振荡减少。然而,如果自我限制在生理上最适合繁殖的温度下最强,这是一个先前理论未分析但有充分实证数据支持的情况,变暖会导致消费者 - 资源振荡增加。第三,该模型针对温度如何影响竞争和资源获取特征的替代假设,得出了关于消费者 - 资源动态的可检验比较预测。重要的是,它通过经验可量化的指标来预测温度对消费者生存能力和消费者 - 资源振荡的影响,从而无需对复杂的动态模型进行参数化。用宿主 - 寄生蜂相互作用的实证数据对这些指标进行测试,得出了消费者持续存在的温度限制以及消费者 - 资源振荡倾向的现实估计,突出了它们在预测温度影响,特别是变暖对自然和农业环境中消费者 - 资源相互作用的影响方面的效用。
