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两种被捕捞的近缘物种生活史阶段之间的混合相互作用。

Mixed interactions among life history stages of two harvested related species.

作者信息

Bellier Edwige

机构信息

Department of Arctic and Marine Biology The Arctic University of Norway Tromsø Norway.

出版信息

Ecol Evol. 2022 Mar 7;12(3):e8530. doi: 10.1002/ece3.8530. eCollection 2022 Feb.

DOI:10.1002/ece3.8530
PMID:35309747
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8901886/
Abstract

Climate change and harvesting can affect the ecosystems' functioning by altering the population dynamics and interactions among species. Knowing how species interact is essential for better understanding potentially unintended consequences of harvest on multiple species in ecosystems. I analyzed how stage-specific interactions between two harvested competitors, the haddock () and Atlantic cod (), living in the Barents Sea affect the outcome of changes in the harvest of the two species. Using state-space models that account for observation errors and stochasticity in the population dynamics, I run different harvesting scenarios and track population-level responses of both species. The increasing temperature elevated the number of larvae of haddock but did not significantly influence the older age-classes. The nature of the interactions between both species shifted from predator-prey to competition around age-2 to -3. Increased cod fishing mortality, which led to decreasing abundance of cod, was associated with an increasing overall abundance of haddock, which suggests compensatory dynamics of both species. From a stage-specific approach, I show that a change in the abundance in one species may propagate to other species, threatening the exploited species' recovery. Thus, this study demonstrates that considering interactions among life history stages of harvested species is essential to enhance species' co-existence in harvested ecosystems. The approach developed in this study steps forward the analyses of effects of harvest and climate in multi-species systems by considering the comprehension of complex ecological processes to facilitate the sustainable use of natural resources.

摘要

气候变化和捕捞会通过改变种群动态以及物种间的相互作用来影响生态系统的功能。了解物种间如何相互作用对于更好地理解捕捞对生态系统中多个物种可能产生的意外后果至关重要。我分析了生活在巴伦支海的两种被捕捞的竞争物种——黑线鳕()和大西洋鳕鱼()之间特定阶段的相互作用如何影响这两种物种捕捞量变化的结果。使用考虑了种群动态中观测误差和随机性的状态空间模型,我运行了不同的捕捞情景并追踪了两种物种在种群水平上的反应。温度升高增加了黑线鳕的幼体数量,但对年龄较大的鱼群没有显著影响。两种物种之间的相互作用性质在2至3岁左右从捕食 - 猎物关系转变为竞争关系。鳕鱼捕捞死亡率增加导致鳕鱼数量减少,这与黑线鳕总体数量增加有关,这表明两种物种存在补偿动态。从特定阶段的方法来看,我表明一个物种数量的变化可能会传播到其他物种,威胁到被开发物种的恢复。因此,本研究表明,考虑被捕捞物种生活史阶段之间的相互作用对于增强被开发生态系统中物种的共存至关重要。本研究中开发的方法通过考虑对复杂生态过程的理解来推进对多物种系统中捕捞和气候影响的分析,以促进自然资源的可持续利用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6602/8901886/5a43f046fec0/ECE3-12-e8530-g002.jpg
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Sound physiological knowledge and principles in modeling shrinking of fishes under climate change.气候变化下鱼类体型缩小模型构建中需要具备生理学方面的知识和原理。
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Global fishery prospects under contrasting management regimes.不同管理体制下的全球渔业前景。
Proc Natl Acad Sci U S A. 2016 May 3;113(18):5125-9. doi: 10.1073/pnas.1520420113. Epub 2016 Mar 28.
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