Coevolution and temporal dynamics of species interactions shape species coexistence

François Duchenne, Virginia Domínguez-García, Francisco Molina, Ignasi Bartomeus
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Abstract

Evolutionary and ecological forces shape species coexistence, but how different ecological mechanisms drive coevolutionary dynamics remains poorly understood. Focusing on mutualistic communities, we explore how morphological and phenological trait matching can shape the coevolution of species traits, influence the evolutionary trajectories at the community level, and determine community stability. Using in silico experiments, we first show that because phenological traits can decouple interactions in time, their coevolutionary dynamics led to the emergence of interaction motifs promoting facilitation over competition. In contrast, coevolution driven by morphological traits led to poorly structured networks with higher connectance. As a consequence, phenological coevolution increased the ecological stability of the community, relative to those coevolved based on morphology, and dampened the diversity-stability trade-off observed in morphologically coevolved communities. Next, by using 17 empirical pollination networks, we show that phenological motifs promoting facilitation were abundant in natural communities, and that as predicted by the theoretical models, the phenological structure in species interactions was a major determinant of the structural stability of these empirical communities. These results show that modelling explicitly the basic mechanisms determining species interactions is crucial to understand how species coevolve, and the ecological properties emerging at the community level, such as community structure and stability.
物种相互作用的共同进化和时间动态决定了物种的共存性
进化和生态的力量决定了物种的共存,但人们对不同的生态机制如何驱动共同进化动态仍然知之甚少。我们以互生群落为重点,探讨了形态和表观性状匹配如何塑造物种性状的共同进化、影响群落水平的进化轨迹并决定群落的稳定性。我们首先利用硅学实验表明,由于表观性状可以在时间上解除相互作用的耦合,它们的协同进化动态导致了促进竞争的相互作用模式的出现。与此相反,由形态特征驱动的共同进化则导致了结构不完善、连接度较高的网络。因此,与基于形态的共同进化相比,物候共同进化提高了群落的生态稳定性,并抑制了形态共同进化群落中观察到的多样性-稳定性权衡。接下来,通过使用 17 个经验授粉网络,我们证明了自然群落中存在大量的促进物候模式,而且正如理论模型所预测的那样,物种相互作用中的物候结构是这些经验群落结构稳定性的主要决定因素。这些结果表明,明确地模拟决定物种相互作用的基本机制对于理解物种如何共同进化以及群落水平上出现的生态特性(如群落结构和稳定性)至关重要。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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