The Interplay of Binary and Quantitative Structure on the Stability of Mutualistic Networks.

IF 2.2 3区 生物学 Q1 ZOOLOGY
Christopher R Anderson, Alva R K Curtsdotter, Phillip P A Staniczenko, Fernanda S Valdovinos, Berry J Brosi
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引用次数: 0

Abstract

Understanding how the structure of biological systems impacts their resilience (broadly defined) is a recurring question across multiple levels of biological organization. In ecology, considerable effort has been devoted to understanding how the structure of interactions between species in ecological networks is linked to different broad resilience outcomes, especially local stability. Still, nearly all of that work has focused on interaction structure in presence-absence terms and has not investigated quantitative structure, i.e., the arrangement of interaction strengths in ecological networks. We investigated how the interplay between binary and quantitative structure impacts stability in mutualistic interaction networks (those in which species interactions are mutually beneficial), using community matrix approaches. We additionally examined the effects of network complexity and within-guild competition for context. In terms of structure, we focused on understanding the stability impacts of nestedness, a structure in which more-specialized species interact with smaller subsets of the same species that more-generalized species interact with. Most mutualistic networks in nature display binary nestedness, which is puzzling because both binary and quantitative nestedness are known to be destabilizing on their own. We found that quantitative network structure has important consequences for local stability. In more-complex networks, binary-nested structures were the most stable configurations, depending on the quantitative structures, but which quantitative structure was stabilizing depended on network complexity and competitive context. As complexity increases and in the absence of within-guild competition, the most stable configurations have a nested binary structure with a complementary (i.e., anti-nested) quantitative structure. In the presence of within-guild competition, however, the most stable networks are those with a nested binary structure and a nested quantitative structure. In other words, the impact of interaction overlap on community persistence is dependent on the competitive context. These results help to explain the prevalence of binary-nested structures in nature and underscore the need for future empirical work on quantitative structure.

二元结构和定量结构对互助网络稳定性的相互作用
了解生物系统的结构如何影响其复原力(广义上)是一个在生物组织的多个层面上反复出现的问题。在生态学领域,人们一直致力于了解生态网络中物种间的相互作用结构如何与不同的广义恢复力结果(尤其是局部稳定性)相关联。然而,几乎所有的研究工作都集中在存在-不存在条件下的相互作用结构,而没有研究定量结构,即生态网络中相互作用强度的排列。我们利用群落矩阵方法,研究了二元结构和定量结构之间的相互作用如何影响互利相互作用网络(物种之间的相互作用是互利的)的稳定性。此外,我们还研究了网络复杂性和行会内部环境竞争的影响。在结构方面,我们重点了解了嵌套性对稳定性的影响,在嵌套性结构中,专业化程度较高的物种与同一物种的较小子集发生相互作用,而专业化程度较高的物种则与同一物种的较小子集发生相互作用。自然界中的大多数互惠网络都显示出二元嵌套性,这一点令人费解,因为二元嵌套性和定量嵌套性本身都会破坏稳定性。我们发现,定量网络结构对局部稳定性有重要影响。在更复杂的网络中,二元嵌套结构是最稳定的配置,这取决于定量结构;但哪种定量结构具有稳定性取决于网络的复杂性和竞争环境。随着复杂性的增加,在没有行会内部竞争的情况下,最稳定的配置是具有互补(即反嵌套)定量结构的嵌套二元结构。然而,在存在行会内部竞争的情况下,最稳定的网络是具有嵌套二元结构和嵌套定量结构的网络。换句话说,交互重叠对群落持久性的影响取决于竞争环境。这些结果有助于解释二元嵌套结构在自然界中的普遍存在,并强调了未来对定量结构进行实证研究的必要性。
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来源期刊
CiteScore
4.70
自引率
7.70%
发文量
150
审稿时长
6-12 weeks
期刊介绍: Integrative and Comparative Biology ( ICB ), formerly American Zoologist , is one of the most highly respected and cited journals in the field of biology. The journal''s primary focus is to integrate the varying disciplines in this broad field, while maintaining the highest scientific quality. ICB''s peer-reviewed symposia provide first class syntheses of the top research in a field. ICB also publishes book reviews, reports, and special bulletins.
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