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沉积物暴露对珊瑚的影响:实验研究的系统综述

Effects of sediment exposure on corals: a systematic review of experimental studies.

作者信息

Tuttle Lillian J, Donahue Megan J

机构信息

Hawai'i Institute of Marine Biology, University of Hawai'i at Mānoa, Kāne'ohe, HI 96744 USA.

NOAA NMFS Pacific Islands Regional Office, Honolulu, HI 96860 USA.

出版信息

Environ Evid. 2022;11(1):4. doi: 10.1186/s13750-022-00256-0. Epub 2022 Feb 7.

DOI:10.1186/s13750-022-00256-0
PMID:35154667
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8818373/
Abstract

BACKGROUND

Management actions that address local-scale stressors on coral reefs can rapidly improve water quality and reef ecosystem condition. In response to reef managers who need actionable thresholds for coastal runoff and dredging, we conducted a systematic review and meta-analysis of experimental studies that explore the effects of sediment on corals. We identified exposure levels that 'adversely' affect corals while accounting for sediment bearing (deposited vs. suspended), coral life-history stage, and species, thus providing empirically based estimates of stressor thresholds on vulnerable coral reefs.

METHODS

We searched online databases and grey literature to obtain a list of potential studies, assess their eligibility, and critically appraise them for validity and risk of bias. Data were extracted from eligible studies and grouped by sediment bearing and coral response to identify thresholds in terms of the lowest exposure levels that induced an adverse physiological and/or lethal effect. Meta-regression estimated the dose-response relationship between exposure level and the magnitude of a coral's response, with random-effects structures to estimate the proportion of variance explained by factors such as study and coral species.

REVIEW FINDINGS

After critical appraisal of over 15,000 records, our systematic review of corals' responses to sediment identified 86 studies to be included in meta-analyses (45 studies for deposited sediment and 42 studies for suspended sediment). The lowest sediment exposure levels that caused adverse effects in corals were well below the levels previously described as 'normal' on reefs: for deposited sediment, adverse effects occurred as low as 1 mg/cm/day for larvae (limited settlement rates) and 4.9 mg/cm/day for adults (tissue mortality); for suspended sediment, adverse effects occurred as low as 10 mg/L for juveniles (reduced growth rates) and 3.2 mg/L for adults (bleaching and tissue mortality). Corals take at least 10 times longer to experience tissue mortality from exposure to suspended sediment than to comparable concentrations of deposited sediment, though physiological changes manifest 10 times faster in response to suspended sediment than to deposited sediment. Threshold estimates derived from continuous response variables (magnitude of adverse effect) largely matched the lowest-observed adverse-effect levels from a summary of studies, or otherwise helped us to identify research gaps that should be addressed to better quantify the dose-response relationship between sediment exposure and coral health.

CONCLUSIONS

We compiled a global dataset that spans three oceans, over 140 coral species, decades of research, and a range of field- and lab-based approaches. Our review and meta-analysis inform the no-observed and lowest-observed adverse-effect levels (NOAEL, LOAEL) that are used in management consultations by U.S. federal agencies. In the absence of more location- or species-specific data to inform decisions, our results provide the best available information to protect vulnerable reef-building corals from sediment stress. Based on gaps and limitations identified by our review, we make recommendations to improve future studies and recommend future synthesis to disentangle the potentially synergistic effects of multiple coral-reef stressors.

SUPPLEMENTARY INFORMATION

The online version contains supplementary material available at 10.1186/s13750-022-00256-0.

摘要

背景

应对珊瑚礁局部尺度压力源的管理行动能够迅速改善水质和珊瑚礁生态系统状况。为回应珊瑚礁管理者对沿海径流和疏浚可操作阈值的需求,我们对探索沉积物对珊瑚影响的实验研究进行了系统综述和荟萃分析。我们确定了在考虑沉积物承载形式(沉积与悬浮)、珊瑚生活史阶段和物种的情况下“不利”影响珊瑚的暴露水平,从而为脆弱珊瑚礁上的压力源阈值提供基于实证的估计。

方法

我们搜索了在线数据库和灰色文献,以获取潜在研究列表,评估其 eligibility,并对其有效性和偏倚风险进行严格评估。从符合条件的研究中提取数据,并按沉积物承载形式和珊瑚反应进行分组,以确定导致生理和/或致死性不利影响的最低暴露水平阈值。荟萃回归估计暴露水平与珊瑚反应强度之间的剂量反应关系,采用随机效应结构估计研究和珊瑚物种等因素解释的方差比例。

综述结果

在对超过15000条记录进行严格评估后,我们对珊瑚对沉积物反应的系统综述确定了86项研究纳入荟萃分析(沉积沉积物研究45项,悬浮沉积物研究42项)。对珊瑚造成不利影响的最低沉积物暴露水平远低于先前在珊瑚礁上描述为“正常”的水平:对于沉积沉积物,幼虫出现不利影响的最低水平为1毫克/平方厘米/天(附着率受限),成体为4.9毫克/平方厘米/天(组织死亡);对于悬浮沉积物,幼体出现不利影响的最低水平为10毫克/升(生长率降低),成体为3.2毫克/升(白化和组织死亡)。尽管生理变化对悬浮沉积物的反应比对沉积沉积物的反应快10倍,但珊瑚因暴露于悬浮沉积物而经历组织死亡的时间至少是暴露于同等浓度沉积沉积物的10倍。从连续反应变量(不利影响程度)得出的阈值估计在很大程度上与研究综述中观察到的最低不利影响水平相匹配,否则有助于我们识别应解决的研究差距,以更好地量化沉积物暴露与珊瑚健康之间的剂量反应关系。

结论

我们编制了一个涵盖三大洋、140多种珊瑚物种、数十年研究以及一系列基于野外和实验室方法的全球数据集。我们的综述和荟萃分析为美国联邦机构在管理咨询中使用的未观察到和最低观察到的不利影响水平(NOAEL、LOAEL)提供了信息。在缺乏更多特定地点或物种数据来为决策提供依据的情况下,我们的结果提供了现有的最佳信息,以保护脆弱的造礁珊瑚免受沉积物压力。基于我们综述中确定的差距和局限性,我们提出了改进未来研究的建议,并建议未来进行综合分析以厘清多种珊瑚礁压力源的潜在协同效应。

补充信息

在线版本包含可在10.1186/s13750 - 022 - 00256 - 0获取的补充材料。

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