大沿海生态系统中从捕食者到猎物优势的空间格局转变。

A spatial regime shift from predator to prey dominance in a large coastal ecosystem.

机构信息

Department of Ecology, Environment and Plant Sciences, Stockholm University, Stockholm, Sweden.

Department of Aquatic Resources, Swedish University of Agricultural Sciences, Drottningholm, Sweden.

出版信息

Commun Biol. 2020 Aug 27;3(1):459. doi: 10.1038/s42003-020-01180-0.

DOI:10.1038/s42003-020-01180-0

PMID:32855431

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7452892/

Abstract

Regime shifts in ecosystem structure and processes are typically studied from a temporal perspective. Yet, theory predicts that in large ecosystems with environmental gradients, shifts should start locally and gradually spread through space. Here we empirically document a spatially propagating shift in the trophic structure of a large aquatic ecosystem, from dominance of large predatory fish (perch, pike) to the small prey fish, the three-spined stickleback. Fish surveys in 486 shallow bays along the 1200 km western Baltic Sea coast during 1979-2017 show that the shift started in wave-exposed archipelago areas near the open sea, but gradually spread towards the wave-sheltered mainland coast. Ecosystem surveys in 32 bays in 2014 show that stickleback predation on juvenile predators (predator-prey reversal) generates a feedback mechanism that appears to reinforce the shift. In summary, managers must account for spatial heterogeneity and dispersal to better predict, detect and confront regime shifts within large ecosystems.

摘要

生态系统结构和过程的状态转移通常从时间角度进行研究。然而，理论预测，在具有环境梯度的大型生态系统中，状态转移应该从局部开始，并逐渐在空间中传播。在这里，我们从实证上记录了一个大型水生生态系统的营养结构的空间传播的状态转移，从大型掠食性鱼类（鲈鱼、梭子鱼）的优势转变为小型猎物鱼类，即三刺棘鱼。1979 年至 2017 年期间，在沿 1200 公里长的波罗的海西部海岸的 486 个浅湾进行的鱼类调查显示，这种转移始于靠近开阔海域的波浪暴露的群岛地区，但逐渐向波浪遮蔽的大陆海岸扩散。2014 年在 32 个海湾进行的生态系统调查显示，棘鱼对幼年捕食者的捕食（捕食者-猎物逆转）产生了一种反馈机制，似乎加强了这种转移。总之，管理者必须考虑空间异质性和扩散，以更好地预测、检测和应对大型生态系统内的状态转移。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cbff/7452892/b0467ca7d3a2/42003_2020_1180_Fig1_HTML.jpg

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大沿海生态系统中从捕食者到猎物优势的空间格局转变。

A spatial regime shift from predator to prey dominance in a large coastal ecosystem.

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