COTSMod: A spatially explicit metacommunity model of outbreaks of crown-of-thorns starfish and coral recovery.

3区 生物学 Q1 Agricultural and Biological Sciences
S A Matthews, K Shoemaker, Morgan S Pratchett, C Mellin
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引用次数: 2

Abstract

Outbreaks of the Pacific crown-of-thorns starfish (COTS; Acanthaster cf. solaris) have been responsible for 40% of the decline in coral cover on the GBR over the last 35 years. With the intensity and frequency of bleaching and cyclonic disturbances increasing, effectively managing these outbreaks may allow reefs an opportunity to recover from these cumulative impacts. Significant research effort has been directed toward developing regional scale models for COTS outbreaks, but these have yet to be fit explicitly to long term time series at the scale of the entire GBR, nor do previous research efforts incorporate explicit estimates of cumulative disturbance history. We developed a stage-based metapopulation model for COTS at a 1×1km resolution using long-term time series and modelled estimates of COTS larval connectivity, nutrient concentrations and important vital rates estimated from the literature. We coupled this metapopulation model to an existing spatially explicit model of coral cover growth, disturbance and recovery across the GBR from 1996 to 2017 to create a metacommunity model. Our results were validated against a spatially and temporally extensive dataset of COTS and coral cover across the GBR, predicting an average coral decline of 1.3% p.a. across the GBR, and accurately recreating coral cover trajectories (mean prediction error=7.1%) and COTS outbreak classification (accuracy=80%). Sensitivity analyses revealed that overall model accuracy was most sensitive to larval predation (boosted regression tree; relative importance=46.7%) and two parameters defining juvenile density dependent mortality (21.5% and 17.5%). The COTS model underestimated peak COTS densities particularly in the Swains and Townsville sectors of the reef, while overestimating COTS density during non-outbreak years. A better understanding of inter-annual variability in larval connectivity, and regionally variable density dependence for adult COTS life stages may improve model fit during these extreme outbreak events. Our model provides a platform to develop upon, and with improvements to estimates of larval connectivity and larval predation could be used to simulate the effects of implementing varying combinations of COTS interventions. This research highlights the importance of the early life history stages of COTS as drivers of outbreak dynamics, emphasizing the need for further empirical research to estimate these parameters.

COTSMod:棘冠海星爆发与珊瑚恢复的空间显式元群落模型。
太平洋棘冠海星(COTS)爆发;在过去的35年里,GBR上珊瑚覆盖面积下降的40%是由Acanthaster (cf. solaris)造成的。随着白化和气旋干扰的强度和频率的增加,有效地管理这些爆发可能使珊瑚礁有机会从这些累积的影响中恢复过来。重要的研究工作已被用于开发COTS暴发的区域尺度模型,但这些模型尚未明确适合整个GBR尺度的长期时间序列,以前的研究工作也没有纳入累积干扰历史的明确估计。我们开发了一个基于阶段的超种群模型,以1×1km分辨率使用长期时间序列和模型估计的COTS幼虫连通性,营养物质浓度和重要的生命率估计从文献。我们将这一元种群模型与1996年至2017年GBR中珊瑚覆盖增长、干扰和恢复的现有空间明确模型相结合,创建了一个元群落模型。我们的研究结果与GBR的COTS和珊瑚覆盖的时空广泛数据集进行了验证,预测整个GBR的珊瑚平均每年下降1.3%,并准确地重建了珊瑚覆盖轨迹(平均预测误差=7.1%)和COTS爆发分类(准确率=80%)。敏感性分析表明,总体模型精度对幼虫捕食最为敏感(增强回归树;相对重要性=46.7%)和定义幼鱼密度依赖性死亡率的两个参数(21.5%和17.5%)。COTS模型低估了峰值COTS密度,特别是在珊瑚礁的Swains和Townsville部分,而高估了非爆发年的COTS密度。更好地了解幼虫连通性的年际变化,以及成虫COTS生命阶段的区域可变密度依赖,可能会改善这些极端暴发事件期间的模型拟合。我们的模型提供了一个开发平台,并且随着对幼虫连通性和幼虫捕食估计的改进,可以用来模拟实施不同COTS干预组合的效果。这项研究强调了COTS生命早期阶段作为疫情动态驱动因素的重要性,强调需要进一步的实证研究来估计这些参数。
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来源期刊
Advances in Marine Biology
Advances in Marine Biology MARINE & FRESHWATER BIOLOGY-
CiteScore
6.10
自引率
0.00%
发文量
6
审稿时长
12 months
期刊介绍: Advances in Marine Biology was first published in 1963 under the founding editorship of Sir Frederick S. Russell, FRS. Now edited by Charles Sheppard, the serial publishes in-depth and up-to-date reviews on a wide range of topics which will appeal to postgraduates and researchers in marine biology, fisheries science, ecology, zoology and biological oceanography. Eclectic volumes in the series are supplemented by thematic volumes on such topics as The Biology of Calanoid Copepods.
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