Biodiversity and aquatic ecosystems conservation in global large river basins: a synthesis of the 5th Mississippi-Yangtze International Symposium

IF 4.6 2区 环境科学与生态学 Q1 ECOLOGY Ecological Processes Pub Date : 2024-07-02 DOI:10.1186/s13717-024-00531-7
Yushun Chen, Michael A. Eggleton, Michael J. Moore, Quinton Phelps
{"title":"Biodiversity and aquatic ecosystems conservation in global large river basins: a synthesis of the 5th Mississippi-Yangtze International Symposium","authors":"Yushun Chen, Michael A. Eggleton, Michael J. Moore, Quinton Phelps","doi":"10.1186/s13717-024-00531-7","DOIUrl":null,"url":null,"abstract":"<p>The aquatic fauna of large river systems have been the cornerstones of multiple civilizations throughout human history. Today, they remain critically important as primary resources for humans as well as indicators of general ecosystem structure and function. Unfortunately, nearly all large-river systems globally are at risk from over-exploitation, pollution, large-scale development, navigation, dredging, climate change, and other threats. For instance, human stressors (such as dams, navigation, agriculture, fishing) and flooding and droughts have affected aquatic biological resources in both the Mississippi and Yangzte River basins (Chen et al. 2016). The Mississippi-Yangtze River Basin Symposium (MYRIBS) is a series of international symposia supported by American Fisheries Society (AFS) and China Society of Fisheries (CSF) dedicated to the promotion of international collaborations and communications in fisheries and aquatic sciences. Although communications and exchanges have centered primarily around the USA and China, other large-river basins have been represented and welcomed into the various symposia. From previous symposia, we have published an AFS book (Chen et al. 2016), and two journal special issues (AHS 2018; Chen and Phelps 2021). The current Mississippi-Yangtze special issue in the journal <i>Ecological Processes</i> includes a total of 13 articles in three focus areas: (1) non-native fish monitoring and assessment, (2) habitat and biodiversity under human stressors, and (3) restoration and management.</p><p>Non-native fish is a hot topic in aquatic biodiversity conservation of global large river basins. Under the global trade and other factors, non-native freshwater fishes have successfully established their populations in many of the biogeographical regions (Gozlan 2008; Bernery et al. 2022). In this issue, Bernery et al. (2024) conducted a global scale analysis on the introduction pathways of non-native fish species, and found that those with broad diets, high parental care, and multiple introduction pathways are the mostly widely introduced and established species. In the lower Mississippi River basin, Eggleton et al. (2024) compared fish assemblages in oxbow lakes before and after bigheaded carps [i.e., largely silver carp (<i>Hypophthalmichthys molitrix</i>) but also bighead carp (<i>H. nobilis</i>)] establishment and found fish indices such as richness, diversity, evenness, and dominance were greater during the post-carp period. In the Pearl River, a large subtropical river in southern China, Shuai et al. (2023) investigated the invasion impacts of Nile tilapia (<i>Oreochromis niloticus</i>) and found that the trophic position of the widely distributed and locally important economically harvested piscivorous culter fish (<i>Culter recurviceps</i>), mandarinfish (<i>Siniperca kneri</i>), and catfish (<i>Pelteobagrus fulvidraco</i>) in the invaded Dongjiang River was significantly lowered compared with the uninvaded reference.</p><p>Human related stressors have greatly affected aquatic ecosystems and increased habitat and biodiversity loss in large river basins (Chen et al. 2020; Su et al. 2021). In the Mississippi Alluvial Plain, Skoog et al. (2024) compared water quality, habitat, and fish assemblages in both agriculture and forest streams, and found that forest streams had significantly better instream and riparian habitats than agriculture streams, and that fish assemblages showed a clear gradient in response to instream habitat conditions, water quality, and benthic chlorophyll a production. In the Yangtze River, Gao et al. (2024) examined phytoplankton taxonomic and functional group patterns and found that water quality (nitrate, total suspended solids, turbidity) and habitat (water flow, river bank and river channel conditions) were critical in driving phytoplankton patterns, followed by climate and land use. Jia et al. (2023) studied freshwater mussel populations in Poyang Lake and found that freshwater mussel density had significant relationships with habitat conditions such as Froude number, water temperature, and chlorophyll a. Zhang et al. (2023) applied a species distribution model to estimate the extent and quality of breeding habitat changes of Chinese mitten crab <i>Eriocheir sinensis</i> in the Yangzte River Estuary and found that habitat degradation significantly affected female distribution and their reproductive processes, particularly gonad development during the pre-reproductive period and fecundity during the reproductive period. In French Guiana, Cantera et al. (2023) applied the environmental DNA metabarcoding technique to study fish communities and found that deforestation is modifying the functional diversity of freshwater fish communities in both streams and rivers. In the Ganga River of India, De et al. (2023) studied effects of habitat disturbance on riparian spider community and found a significant difference in the indices of functional diversity among the lowly, moderately, and highly disturbed sites.</p><p>To bend the freshwater biodiversity loss curve, many conservation, restoration, and management strategies and approaches are needed (Tickner et al. 2020). In the Yangtze River, Gao et al. (2023) developed a phytoplankton-based index of biotic integrity for ecological health assessment and found that the phytoplankton-based ecological health of the Yangtze River was rated as “good” during both dry and wet seasons, with an overall better condition in the dry season. Zhu et al. (2024) studied strontium (Sr) markers in juvenile blunt-snout bream <i>Megalobrama amblycephala</i> and found that fin ray Sr marking is a successful method for juvenile <i>M. amblycephala</i>, with the advantages of non-lethality and negligible sampling injuries, which facilitates the rapid and effective evaluation of Sr marking in restocking of this fish for ecological restorations. Liu et al. (2023) assessed fish resources changes 5 years after the fishing ban in the Chishui River, a tributary of the Yangtze River, and found that a total of 11 native fish species that had disappeared for many years appeared again after the fishing ban. In the Upper Mississippi River, Ward et al. (2023) applied the Resist-Accept-Direct (RAD) framework in large-river management, and found that the RAD framework helps identify plausible long-term trajectories in different reaches (or subbasins) of the river and how the associated social-ecological transformations could be managed by altering site-scale conditions.</p><p>Experience and lessons can be learned from international communications and collaborations such as the MYRIBS series. Under multiple human stressors and climate change, fishery ecologists and biologists should continue working together to promote biodiversity and aquatic ecosystems conservation in global large-river basins.</p><p>Not applicable.</p><ul data-track-component=\"outbound reference\" data-track-context=\"references section\"><li><p>AHS (Acta Hydrobiologica Sinica) (2018) The Mississippi-Yangtze River Basins special issue. http://ssswxb.ihb.ac.cn/article/2018/6. 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Ecol Process 13:15</p><p>Article Google Scholar </p></li></ul><p>Download references<svg aria-hidden=\"true\" focusable=\"false\" height=\"16\" role=\"img\" width=\"16\"><use xlink:href=\"#icon-eds-i-download-medium\" xmlns:xlink=\"http://www.w3.org/1999/xlink\"></use></svg></p><p>We thank many colleagues from both the Mississippi and Yangtze River Basins and globally for their continued support for MYRIBS and related science communication activities. We would also like to thank the Mississippi Interstate Cooperative Resource Association (MICRA), the Lower Mississippi River Conservation Committee (LMRCC), the Arkansas Game and Fish Foundation, the American Fisheries Society (AFS), China Society of Fisheries, Institute of Hydrobiolgy, Chinese Academy of Sciences, and symposium co-organizers Hae Kim, Steve Waste, Craig Paukert, and Alf Haukenes for their support of the 5th MYRIBS in 2022. This work was supported by National Key R&amp;D Program of China (2023YFC3209002, 2019YFD0901203), and Chinese Academy of Sciences (QYZDB-SSW-SMC041, ZDRW-ZS-2017-3-2).</p><p>The current study was mainly supported by National Key Research and Development Program of China (2023YFC3209002; 2019YFD0901203) and Chinese Academy of Sciences (QYZDB-SSW-SMC041, ZDRW-ZS-2017-3-2).</p><h3>Authors and Affiliations</h3><ol><li><p>State Key Laboratory of Freshwater Ecology and Biotechnology, Institute of Hydrobiology, Chinese Academy of Sciences, Wuhan, 430072, China</p><p>Yushun Chen</p></li><li><p>Department of Aquaculture and Fisheries, University of Arkansas at Pine Bluff, 1200 North University Drive , Pine Bluff, AR, 71601, USA</p><p>Michael A. Eggleton</p></li><li><p>U.S. Geological Survey, Iowa Cooperative Fish and Wildlife Research Unit, Department of Natural Resource Ecology and Management, Iowa State University, Ames, IA, 50011, USA</p><p>Michael J. Moore</p></li><li><p>Department of Biology, Missouri State University, 901 S. National Ave., Springfield, MO, 65897, USA</p><p>Quinton Phelps</p></li></ol><span>Authors</span><ol><li><span>Yushun Chen</span>View author publications<p>You can also search for this author in <span>PubMed<span> </span>Google Scholar</span></p></li><li><span>Michael A. Eggleton</span>View author publications<p>You can also search for this author in <span>PubMed<span> </span>Google Scholar</span></p></li><li><span>Michael J. Moore</span>View author publications<p>You can also search for this author in <span>PubMed<span> </span>Google Scholar</span></p></li><li><span>Quinton Phelps</span>View author publications<p>You can also search for this author in <span>PubMed<span> </span>Google Scholar</span></p></li></ol><h3>Contributions</h3><p>Yushun Chen developed the first draft, Yushun Chen, Michael Eggleton, Michael Moore, and Quinton Phelps revised and approved the final manuscript.</p><h3>Corresponding author</h3><p>Correspondence to Yushun Chen.</p><h3>Ethics approval and consent to participate</h3>\n<p>Not applicable.</p>\n<h3>Consent for publication</h3>\n<p>Not applicable.</p>\n<h3>Competing interests</h3>\n<p>The authors declare that they have no competing interest.</p><h3>Publisher's Note</h3><p>Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.</p><p><b>Open Access</b> This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.</p>\n<p>Reprints and permissions</p><img alt=\"Check for updates. 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Abstract

The aquatic fauna of large river systems have been the cornerstones of multiple civilizations throughout human history. Today, they remain critically important as primary resources for humans as well as indicators of general ecosystem structure and function. Unfortunately, nearly all large-river systems globally are at risk from over-exploitation, pollution, large-scale development, navigation, dredging, climate change, and other threats. For instance, human stressors (such as dams, navigation, agriculture, fishing) and flooding and droughts have affected aquatic biological resources in both the Mississippi and Yangzte River basins (Chen et al. 2016). The Mississippi-Yangtze River Basin Symposium (MYRIBS) is a series of international symposia supported by American Fisheries Society (AFS) and China Society of Fisheries (CSF) dedicated to the promotion of international collaborations and communications in fisheries and aquatic sciences. Although communications and exchanges have centered primarily around the USA and China, other large-river basins have been represented and welcomed into the various symposia. From previous symposia, we have published an AFS book (Chen et al. 2016), and two journal special issues (AHS 2018; Chen and Phelps 2021). The current Mississippi-Yangtze special issue in the journal Ecological Processes includes a total of 13 articles in three focus areas: (1) non-native fish monitoring and assessment, (2) habitat and biodiversity under human stressors, and (3) restoration and management.

Non-native fish is a hot topic in aquatic biodiversity conservation of global large river basins. Under the global trade and other factors, non-native freshwater fishes have successfully established their populations in many of the biogeographical regions (Gozlan 2008; Bernery et al. 2022). In this issue, Bernery et al. (2024) conducted a global scale analysis on the introduction pathways of non-native fish species, and found that those with broad diets, high parental care, and multiple introduction pathways are the mostly widely introduced and established species. In the lower Mississippi River basin, Eggleton et al. (2024) compared fish assemblages in oxbow lakes before and after bigheaded carps [i.e., largely silver carp (Hypophthalmichthys molitrix) but also bighead carp (H. nobilis)] establishment and found fish indices such as richness, diversity, evenness, and dominance were greater during the post-carp period. In the Pearl River, a large subtropical river in southern China, Shuai et al. (2023) investigated the invasion impacts of Nile tilapia (Oreochromis niloticus) and found that the trophic position of the widely distributed and locally important economically harvested piscivorous culter fish (Culter recurviceps), mandarinfish (Siniperca kneri), and catfish (Pelteobagrus fulvidraco) in the invaded Dongjiang River was significantly lowered compared with the uninvaded reference.

Human related stressors have greatly affected aquatic ecosystems and increased habitat and biodiversity loss in large river basins (Chen et al. 2020; Su et al. 2021). In the Mississippi Alluvial Plain, Skoog et al. (2024) compared water quality, habitat, and fish assemblages in both agriculture and forest streams, and found that forest streams had significantly better instream and riparian habitats than agriculture streams, and that fish assemblages showed a clear gradient in response to instream habitat conditions, water quality, and benthic chlorophyll a production. In the Yangtze River, Gao et al. (2024) examined phytoplankton taxonomic and functional group patterns and found that water quality (nitrate, total suspended solids, turbidity) and habitat (water flow, river bank and river channel conditions) were critical in driving phytoplankton patterns, followed by climate and land use. Jia et al. (2023) studied freshwater mussel populations in Poyang Lake and found that freshwater mussel density had significant relationships with habitat conditions such as Froude number, water temperature, and chlorophyll a. Zhang et al. (2023) applied a species distribution model to estimate the extent and quality of breeding habitat changes of Chinese mitten crab Eriocheir sinensis in the Yangzte River Estuary and found that habitat degradation significantly affected female distribution and their reproductive processes, particularly gonad development during the pre-reproductive period and fecundity during the reproductive period. In French Guiana, Cantera et al. (2023) applied the environmental DNA metabarcoding technique to study fish communities and found that deforestation is modifying the functional diversity of freshwater fish communities in both streams and rivers. In the Ganga River of India, De et al. (2023) studied effects of habitat disturbance on riparian spider community and found a significant difference in the indices of functional diversity among the lowly, moderately, and highly disturbed sites.

To bend the freshwater biodiversity loss curve, many conservation, restoration, and management strategies and approaches are needed (Tickner et al. 2020). In the Yangtze River, Gao et al. (2023) developed a phytoplankton-based index of biotic integrity for ecological health assessment and found that the phytoplankton-based ecological health of the Yangtze River was rated as “good” during both dry and wet seasons, with an overall better condition in the dry season. Zhu et al. (2024) studied strontium (Sr) markers in juvenile blunt-snout bream Megalobrama amblycephala and found that fin ray Sr marking is a successful method for juvenile M. amblycephala, with the advantages of non-lethality and negligible sampling injuries, which facilitates the rapid and effective evaluation of Sr marking in restocking of this fish for ecological restorations. Liu et al. (2023) assessed fish resources changes 5 years after the fishing ban in the Chishui River, a tributary of the Yangtze River, and found that a total of 11 native fish species that had disappeared for many years appeared again after the fishing ban. In the Upper Mississippi River, Ward et al. (2023) applied the Resist-Accept-Direct (RAD) framework in large-river management, and found that the RAD framework helps identify plausible long-term trajectories in different reaches (or subbasins) of the river and how the associated social-ecological transformations could be managed by altering site-scale conditions.

Experience and lessons can be learned from international communications and collaborations such as the MYRIBS series. Under multiple human stressors and climate change, fishery ecologists and biologists should continue working together to promote biodiversity and aquatic ecosystems conservation in global large-river basins.

Not applicable.

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We thank many colleagues from both the Mississippi and Yangtze River Basins and globally for their continued support for MYRIBS and related science communication activities. We would also like to thank the Mississippi Interstate Cooperative Resource Association (MICRA), the Lower Mississippi River Conservation Committee (LMRCC), the Arkansas Game and Fish Foundation, the American Fisheries Society (AFS), China Society of Fisheries, Institute of Hydrobiolgy, Chinese Academy of Sciences, and symposium co-organizers Hae Kim, Steve Waste, Craig Paukert, and Alf Haukenes for their support of the 5th MYRIBS in 2022. This work was supported by National Key R&D Program of China (2023YFC3209002, 2019YFD0901203), and Chinese Academy of Sciences (QYZDB-SSW-SMC041, ZDRW-ZS-2017-3-2).

The current study was mainly supported by National Key Research and Development Program of China (2023YFC3209002; 2019YFD0901203) and Chinese Academy of Sciences (QYZDB-SSW-SMC041, ZDRW-ZS-2017-3-2).

Authors and Affiliations

  1. State Key Laboratory of Freshwater Ecology and Biotechnology, Institute of Hydrobiology, Chinese Academy of Sciences, Wuhan, 430072, China

    Yushun Chen

  2. Department of Aquaculture and Fisheries, University of Arkansas at Pine Bluff, 1200 North University Drive , Pine Bluff, AR, 71601, USA

    Michael A. Eggleton

  3. U.S. Geological Survey, Iowa Cooperative Fish and Wildlife Research Unit, Department of Natural Resource Ecology and Management, Iowa State University, Ames, IA, 50011, USA

    Michael J. Moore

  4. Department of Biology, Missouri State University, 901 S. National Ave., Springfield, MO, 65897, USA

    Quinton Phelps

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  1. Yushun ChenView author publications

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Contributions

Yushun Chen developed the first draft, Yushun Chen, Michael Eggleton, Michael Moore, and Quinton Phelps revised and approved the final manuscript.

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Correspondence to Yushun Chen.

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Chen, Y., Eggleton, M.A., Moore, M.J. et al. Biodiversity and aquatic ecosystems conservation in global large river basins: a synthesis of the 5th Mississippi-Yangtze International Symposium. Ecol Process 13, 52 (2024). https://doi.org/10.1186/s13717-024-00531-7

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全球大河流域的生物多样性和水生生态系统保护:第五届密西西比-长江国际研讨会综述
在人类历史上,大河水系的水生动物一直是多种文明的基石。今天,它们作为人类的主要资源以及生态系统总体结构和功能的指标,仍然具有极其重要的意义。不幸的是,全球几乎所有大型河流系统都面临着过度开发、污染、大规模开发、航运、疏浚、气候变化和其他威胁的风险。例如,人类压力因素(如水坝、航运、农业、渔业)以及洪水和干旱都对密西西比河和长江流域的水生生物资源造成了影响(Chen 等,2016 年)。密西西比河-长江流域研讨会(MYRIBS)是由美国渔业协会(AFS)和中国水产学会(CSF)支持的一系列国际研讨会,致力于促进渔业和水产科学领域的国际合作与交流。尽管交流和沟通主要围绕美国和中国,但其他大河流域也派代表参加了各种研讨会,并受到欢迎。在以往的研讨会上,我们出版了一本 AFS 书籍(Chen 等,2016 年)和两本期刊特刊(AHS,2018 年;Chen 和 Phelps,2021 年)。本次在《生态过程》杂志上发表的密西西比-长江特刊包括三个重点领域共13篇文章:(1)非外来鱼类监测与评估;(2)人类胁迫下的生境与生物多样性;(3)恢复与管理。"非外来鱼类是全球大江大河流域水生生物多样性保护的热点话题。在全球贸易和其他因素的影响下,非外来淡水鱼类已成功地在许多生物地理区域建立了自己的种群(Gozlan,2008 年;Bernery 等,2022 年)。在这一问题上,Bernery 等人(2024 年)在全球范围内对非本地鱼类物种的引入途径进行了分析,发现那些食性广泛、亲本保育程度高、引入途径多的物种是最广泛引入和建立种群的物种。在密西西比河下游流域,Eggleton 等人(2024 年)比较了鳙鱼[即主要是鲢鱼(Hypophthalmichthys molitrix),但也有鳙鱼(H. nobilis)]引入前后牛首湖中的鱼类组合,发现鱼类丰富度、多样性、均匀度和优势度等指数在引入鳙鱼后更高。Shuai 等人(2023 年)在中国南方的亚热带大河珠江中调查了鲤科鱼类入侵对珠江的影响。(Shuai 等人(2023 年)研究了尼罗罗非鱼(Oreochromis niloticus)的入侵影响,发现与未受入侵的参照河段相比,受入侵的东江中广泛分布的、对当地具有重要经济价值的食鱼类--鲻鱼(Culter recurviceps)、鳜鱼(Siniperca kneri)和鲶鱼(Pelteobagrus fulvidraco)的营养级明显降低。与人类相关的压力因素极大地影响了水生生态系统,加剧了大型流域栖息地和生物多样性的丧失(Chen 等,2020 年;Su 等,2021 年)。在密西西比冲积平原,Skoog 等人(2024 年)比较了农业溪流和森林溪流的水质、栖息地和鱼类组合,发现森林溪流的河内和河岸栖息地明显优于农业溪流,鱼类组合对河内栖息地条件、水质和底栖生物叶绿素 a 产量的响应呈明显梯度。在长江,Gao 等人(2024 年)研究了浮游植物的分类和功能群模式,发现水质(硝酸盐、总悬浮固体、浊度)和生境(水流、河岸和河道条件)是浮游植物模式的关键驱动因素,其次是气候和土地利用。Jia 等(2023 年)对鄱阳湖淡水贻贝种群进行了研究,发现淡水贻贝密度与弗劳德数、水温和叶绿素 a 等生境条件有显著关系。(2023) 应用物种分布模型估算了长江口中华绒螯蟹繁殖生境变化的程度和质量,发现生境退化显著影响了雌蟹的分布及其繁殖过程,特别是繁殖前期的性腺发育和繁殖期的受精率。在法属圭亚那,Cantera 等人(2023 年)应用环境 DNA 代谢编码技术研究鱼类群落,发现森林砍伐正在改变溪流和河流中淡水鱼群落的功能多样性。De 等人(2023 年)在印度恒河研究了生境干扰对河岸蜘蛛群落的影响,发现低度、中度和高度干扰地点的功能多样性指数存在显著差异。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Ecological Processes
Ecological Processes Environmental Science-Ecological Modeling
CiteScore
8.50
自引率
4.20%
发文量
64
审稿时长
13 weeks
期刊介绍: Ecological Processes is an international, peer-reviewed, open access journal devoted to quality publications in ecological studies with a focus on the underlying processes responsible for the dynamics and functions of ecological systems at multiple spatial and temporal scales. The journal welcomes manuscripts on techniques, approaches, concepts, models, reviews, syntheses, short communications and applied research for advancing our knowledge and capability toward sustainability of ecosystems and the environment. Integrations of ecological and socio-economic processes are strongly encouraged.
期刊最新文献
Effects of warming on soil fungal community and its function in a temperate steppe Non-linear response of plant caloric value to N addition and mowing treatments in a meadow steppe Spatial patterns of causality in temperate silvopastoral systems: a perspective on nitrification stability in response to flooding Functional and phylogenetic structure of mammals along elevational gradients in the Central and East Himalayas Fine spatial scale assessment of structure and configuration of vegetation cover for northern bobwhites in grazed pastures
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