Taking stock: Is recovery of a depleted population possible in a changing climate?

IF 1.9 2区 农林科学 Q2 FISHERIES
Joseph A. Langan, Richard J. Bell, Jeremy S. Collie
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Abstract

As the impacts of climate change become more severe throughout the global oceans, fisheries managers will be increasingly challenged to rebuild stocks exhibiting declining productivity. In such cases, detailed knowledge of species life history will be necessary to both restrict harvest and manage other environmental conditions, where possible, that impact survivorship. A current example of these challenges, the Southern New England/Mid-Atlantic Bight winter flounder stock remains in a persistently depleted state due to a combination of past harvest and the effects of climate change mediated through increased predation. To explore the recovery capacity of a subpopulation of this stock, a life-cycle model was fit to 29 year classes of stage-specific winter flounder data from surveys conducted in Narragansett Bay, Rhode Island and used to project future subpopulation abundance. Supporting a prevailing hypothesis, the results indicated that environmental factors influencing juvenile mortality were largely responsible for inhibiting recovery. Furthermore, recovery of the subpopulation to past levels of abundance was determined to be unlikely even under optimistic future conditions resulting from aggressive management interventions. Taken together, the findings of this work pose important questions regarding the realism of assessing climate-challenged populations against biological reference points set under past environmental regimes and the degree to which harvest restrictions to promote recovery of such stocks should be allowed to limit warm-water fisheries thriving in a warming ocean.

评估:在气候变化的情况下,枯竭的人口能否恢复?
随着气候变化对全球海洋的影响越来越严重,渔业管理人员将面临越来越大的挑战,以重建生产力下降的种群。在这种情况下,物种生活史的详细知识将是必要的,以限制收获和管理其他环境条件,在可能的情况下,影响生存。当前这些挑战的一个例子是,由于过去的收获和由捕食增加介导的气候变化的影响,新英格兰南部/中大西洋白牙冬季比目鱼种群仍然处于持续枯竭状态。为了探索该种群的一个亚种群的恢复能力,对罗德岛纳拉甘西特湾调查的29年特定阶段冬季比目鱼数据进行了生命周期模型拟合,并用于预测未来亚种群的丰度。研究结果支持一种流行的假设,表明影响幼鱼死亡率的环境因素是抑制恢复的主要原因。此外,即使在积极的管理干预导致的乐观的未来条件下,亚种群也不太可能恢复到过去的丰度水平。总而言之,这项工作的发现提出了一些重要的问题,包括根据过去环境制度下设定的生物参考点来评估气候挑战种群的现实性,以及应该允许在多大程度上限制捕捞限制,以促进这类种群的恢复,从而限制在变暖的海洋中蓬勃发展的温水渔业。
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来源期刊
Fisheries Oceanography
Fisheries Oceanography 农林科学-海洋学
CiteScore
5.00
自引率
7.70%
发文量
50
审稿时长
>18 weeks
期刊介绍: The international journal of the Japanese Society for Fisheries Oceanography, Fisheries Oceanography is designed to present a forum for the exchange of information amongst fisheries scientists worldwide. Fisheries Oceanography: presents original research articles relating the production and dynamics of fish populations to the marine environment examines entire food chains - not just single species identifies mechanisms controlling abundance explores factors affecting the recruitment and abundance of fish species and all higher marine tropic levels
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