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Zooplankton biodiversity monitoring in polluted freshwater ecosystems: A technical review
Journal Pre-proof Zooplankton Biodiversity Monitoring in Polluted Freshwater Ecosystems: A technical review Wei Xiong, Xuena Huang, Yiyong Chen, Ruiying Fu, Xun Du, Xingyu Chen, Aibin Zhan PII:
S2666-4984(19)30008-0
DOI:
https://doi.org/10.1016/j.ese.2019.100008
Reference:
ESE 100008
To appear in:
Environmental Science and Ecotechnology
Please cite this article as: W. Xiong, X. Huang, Y. Chen, R. Fu, X. Du, X. Chen, A. Zhan, Zooplankton Biodiversity Monitoring in Polluted Freshwater Ecosystems: A technical review, Environmental Science and Ecotechnology, https://doi.org/10.1016/j.ese.2019.100008. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 The Author(s). Published by Elsevier B.V. on behalf of Chinese Society for Environmental SciencesHarbin Institute of TechnologyChinese Research Academy of Environmental Sciences.
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Zooplankton Biodiversity Monitoring in Polluted Freshwater
2
Ecosystems: A technical review
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Wei Xiong1, Xuena Huang1, Yiyong Chen1, Ruiying Fu1, Xun Du1, Xingyu Chen1,2, Aibin
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Zhan1,3*
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1
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Shuangqing Road, Haidian District, Beijing 100085, China;
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2
Research Center for Eco-Environmental Sciences, Chinese Academy of Sciences, 18
College of Resources, Environment and Tourism, Capital Normal University, 105 West
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Third Ring Road, Haidian District, Beijing 100048, China;
11
3
12
Road, Shijingshan District, Beijing 100049, China.
University of Chinese Academy of Sciences, Chinese Academy of Sciences, 19A Yuquan
13 14
*Corresponding authors:
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Prof. Aibin Zhan; Email: [email protected] or [email protected]; Phone & Fax:
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(+86)-10-6284-9882;
1
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ABSRACT
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Freshwater ecosystems harbor a vast diversity of micro-eukaryotes (rotifers, crustaceans and
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protists), and such diverse taxonomic groups play important roles in ecosystem functioning
20
and services. Unfortunately, freshwater ecosystems and biodiversity therein are threatened by
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many environmental stressors, particularly those derived from intensive human activities
22
such as chemical pollution. In the past several decades, significant efforts have been devoted
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to halting biodiversity loss to recover services and functioning of freshwater ecosystems.
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Biodiversity monitoring is the first and a crucial step towards diagnosing pollution impacts
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on ecosystems and making conservation plans. Yet, bio-monitoring of ubiquitous
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micro-eukaryotes is extremely challenging, owing to many technical issues associated with
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micro-zooplankton such as microscopic size, fuzzy morphological features, and extremely
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high biodiversity. Here, we review current methods used for monitoring zooplankton
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biodiversity to advance management of impaired freshwater ecosystems. We discuss the
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development of traditional morphology-based identification methods such as scanning
31
electron microscope (SEM) and ZOOSCAN and FlowCAM automatic systems, and
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DNA-based strategies such as metabarcoding and real-time quantitative PCR. In addition, we
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summarize advantages and disadvantages of these methods when applied for monitoring
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impacted ecosystems, and we propose practical DNA-based monitoring workflows for
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studying biological consequences of environmental pollution in freshwater ecosystems.
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Finally, we propose possible solutions for existing technical issues to improve accuracy and
37
efficiency of DNA-based biodiversity monitoring.
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Keywords: biodiversity, micro-eukaryotes, metabarcoding, freshwater ecosystem, water 2
39
pollution.
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1 Introduction
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1.1 Biodiversity loss in freshwater ecosystems
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Since the first proposition of the term ‘biodiversity’ in the United Nations’ Conference
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on Environment and Development in 1992, the importance of biodiversity has been well
44
recognized and conservation of biodiversity has drawn substantial attention (Warren 1996).
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Among various types of ecosystems, freshwater ecosystems provide unique habitats,
46
supporting a high level of biodiversity. Freshwater ecosystems occupy only approximately
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0.8% of the Earth’s surface but support almost 6% of all known species (Dudgeon et al. 2006).
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For example, more than 10,000 fish species live in freshwater ecosystems, accounting for 40%
49
of the known global fish species (Cazzolla 2016). In addition, freshwater ecosystems provide
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irreplaceable goods and services for human beings, such as drinking and irrigation water,
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food, creation, and regulation of micro-climate (Vörösmarty et al. 2010; Green et al. 2015).
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However, many factors, particularly those derived from anthropogenic activities such as
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water pollution and invasive species, have largely degraded freshwater ecosystems over the
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past several decades (Dudgeon et al. 2006; Bush et al. 2017). Freshwater ecosystems such as
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rivers and inland lakes are among the most threatened ecosystems on the Earth (Vörösmarty
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et al. 2010; Alahuhta et al. 2019). As a result, biodiversity loss in freshwater ecosystems is
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much faster than that in terrestrial counterparts (Geist 2011). Even worse, biodiversity loss in
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threaten freshwater ecosystems have not slowed down in recent years (Butchart et al. 2010),
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despite the fact that great effort has been placed on maintaining or recovering biodiversity in
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freshwater ecosystems. These efforts have been largely unsuccessful due to frequent 3
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disturbance derived from increasing anthropogenic activities and knowledge gaps on
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biodiversity in freshwater ecosystems (Clausen & York 2008).
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Indeed, biodiversity loss in freshwater ecosystem is likely much more severe than we
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have realized, as biological response to disturbance in freshwater ecosystems is not
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completely known, especially on the widespread but hidden microscopic taxa such as
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zooplankton (Cazzolla 2016). A large body of scientific literature has illustrated the
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biodiversity loss of macro-eukaryotes under human activity disturbance, such as fishes,
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amphibians, mollusks and crustaceans (Williams 2002; Stuart et al. 2004; Nobles & Zhang,
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2011; Freyhof & Brooks 2017). Nevertheless, studies on biodiversity loss dynamics of
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micro-eukaryotes are rare (Xiong et al. 2019). In terms of monitoring and conservation
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priority, better-known macro-eukaryotes have drawn more attention than micro-eukaryotes
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such as microscopic zooplankton (Darwall et al. 2009). Indeed, the highly neglected
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microscopic zooplankton play vital ecological roles in aquatic food-webs, such as linking
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phytoplankton and bacteria to high trophic levels such as fish (Johnson et al. 2011). The
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protection and recovery of overlooked microscopic zooplankton biodiversity largely
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determine the conservation of biodiversity at high trophic levels, as well as the integration
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and functioning of freshwater ecosystems.
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1.2 Potential indicative roles of zooplankton in freshwater ecosystems
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Zooplankton include diverse taxa such as protists, rotifers, copepods and cladocerans,
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many of which are microscopic (De Vargas et al. 2015). Multiple studies have made a
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consistent and crucial realization that zooplankton taxa are rapid responders to many
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environmental stressors, such as hydrological changes, climate changes and anthropogenic 4
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activity-induced water pollution (Duggan et al. 2001; Pawlowski et al. 2016). Specifically,
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previous laboratory or field studies have indicated that zooplankton communities were
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significantly impacted by excessive loading of nutrients (Duggan et al. 2001; Wang et al.
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2010; Xiong et al. 2019), and also negatively affected by microplastics (Scherer et al. 2018),
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pesticides (Hanazato 2001), and pharmaceuticals and personal care products (PPCPs) (Garric
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2013). As such, researchers have identified their usefulness as ecological indicators to water
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pollution. For instances, rotifers are used to diagnose ecological impacts of freshwater
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toxicants, such as endocrine disruptors, bioconcentration of lead, and nanoparticles toxicity
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(Snell & Marcial 2017). Yang et al. (2017b) indicated that zooplankton communities could be
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used to predict ecological thresholds of ammonia nitrogen. Payne (2013) listed and
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recommended seven key reasons for the use of protists as good bio-indicators in aquatic
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ecosystems. Azevêdo et al. (2015) showed that zooplankton communities played a
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complementary role to macroinvertebrates in indicating variation of the trophic status of
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waters. Thus, bio-monitoring zooplankton communities has become a widely accepted and
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irreplaceable aspect in ecological conservation and management of aquatic ecosystems.
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1.3 Technical difficulties for biodiversity monitoring of zooplankton
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Despite rapid development of novel technologies in the past several decades, most
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traditional morphology-based methods have been used to investigate interactions between
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biodiversity of zooplankton and environmental pollution in freshwater ecosystems (Wang et
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al. 2010; Xiong et al. 2016b). In recent years, several novel strategies, such as metabarcoding
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(see section 3.1 in this article), represent novel and robust approaches to profile microscopic
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organisms more efficiently and with finer resolution (Bucklin et al. 2016). Studies have 5
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facilitated the use of metabarcoding for assessing diversity of many zooplankton
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communities (Zhan et al. 2013, 2014b; Brown et al. 2015; Xiong et al. 2018), such as protists
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(Pawlowski et al. 2016) and copepods (Hirai et al. 2015). Metabarcoding-based methods have
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generated detailed information about biodiversity of zooplankton, providing important
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support to biodiversity conservation, such as the development of DNA-based ecological
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status assessment under the European Water Framework Directive (Hering et al. 2018), and
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advancement of routine freshwater bio-monitoring by using molecular methods (Blackman et
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al. 2019).
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Yet, there remain many methodological difficulties for biodiversity monitoring of
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zooplankton in both morphology-based and DNA-based strategies in polluted freshwater
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ecosystems, and many taxonomic groups of zooplankton are largely undescribed or unknown
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(Dudgeon et al. 2006). The primary issue for morphology-based biodiversity monitoring is
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resolution and efficiency. When gathering information on zooplankton composition and
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abundance in a traditional way, it relies heavily on taxonomists who identify specimens under
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a binocular microscope. The process is time- and cost-consuming and requires high expertise.
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Moreover, both the number of samples that can be analyzed and the availability of competent
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taxonomists are limited. Meanwhile, relatively low resolution imposes limitations on species
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identification, particularly at larval/juvenile stages and for cryptic species or species complex.
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In addition, morphology-based methods are challenged by rare species detection (Zhan et al.
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2013), which is of great significance for biological conservation. Rare species, which are
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often either endangered species or species under severe environmental stresses in polluted
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ecosystems, should be protected or analyzed in priority. 6
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Such difficulties in accurate morphological identification of species not only impede
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biodiversity monitoring in a traditional way, but also hinder biodiversity investigation by
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using DNA-based approaches (Zhan et al. 2013; Xiong et al. 2016a). Despite that DNA-based
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methods obviously advance the efficiency and resolution, particularly for studies aiming at
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large geographical scales, the precondition for DNA-based methods relies on available
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reference databases that must be constructed based on morphological identification (Briski et
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al. 2011). In addition, there are challenges in quantification of taxon abundance in using
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DNA-based methods such as metabarcoding, as metabarcoding analysis has not shown good
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agreement between specie abundance data and sequence abundance (e.g., Sun et al. 2015).
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1.4 Our aims
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To advance management of impaired freshwater ecosystems, this review aims to provide
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an overview of available methods for monitoring biodiversity of eukaryotic zooplankton,
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including both morphology-based and DNA-based approaches. In addition, we discuss
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technical difficulties, as well as causes and consequences of these difficulties in biodiversity
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monitoring. Finally, we propose a practical monitoring workflow to study biological
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consequences of environmental pollution in aquatic ecosystems as take-home information.
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2 Morphology-based methods for zooplankton biodiversity monitoring
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2.1 Traditional morphological methods
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The acquisition of biodiversity data has historically been based on morphological
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characterization of species. Researchers use many tools such as nets, pumps or water bottles
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to collect specimens and gatherer formation of composition and abundance of species, and
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then collected specimens are subjected for identification by taxonomists under a microscope 7
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(Gorsky et al. 2010; EÁlvarez et al. 2013; Andújar et al. 2018b). This traditional technique is
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considered to be useful for the identification and enumeration of microplankton (Fig. 1), and
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thus providing invaluable information on species identification (Gorsky et al. 2010; EÁlvarez
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et al. 2013). For instance, Humes (1994) have reported approximate 11500 morphological
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species of copepods. Kreutz & Foissner (2006) edited a book of protozoological monographs,
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recording 670 species of protists, micro-metazoans and bacteria in ponds of Simmelried in
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Germany. Wang (1961) studied and recorded 252 freshwater rotifer species in China, which
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laid the foundation for rotifer study in China.
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With the advent of morphological identification by electron microscopes, the scanning
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electron microscope (SEM) has become a powerful analytical tool (Fig. 2). The use of SEM
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significantly increases the resolution in specimen identification and helps detect taxonomy
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keys. For instance, by using SEM, several rotifer species with differentiated trophi were
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identified in an apparently morphological uniform genus (Segers 1995). Papa et al. (2012)
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updated taxonomic status of crustacean zooplankton in a lake in Philippines using a
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combination of light and scanning electron microscopes. Hines (2019) studied the
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biogeography of freshwater ciliates (protozoa) in Florida, USA with a high resolution of
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species identification by SEM. Thus, SEM has become an important complementary tool for
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morphology-based monitoring of zooplankton, particularly on microscopic taxa with debates.
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2.2 New morphological identification methods
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It is obvious that both traditional microscopes and SEMs can detect biological features
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in detail but fail to analyze a large number of species rapidly. With the advent of digital
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imaging and scanning technologies, several automatic or semiautomatic instruments have 8
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been developed to rapidly analyze zooplankton samples. The two representative ones are
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ZOOSCAN system (Gorsky et al. 2010) and Flow Ctometer And Microscope (FlowCAM)
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(EÁlvarez et al. 2013). ZOOSCAN takes digital images of zooplankton samples and analyze
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images based on available databases in a fast and (semi-)automatic way. By integrating
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ZooProcess and Plankton Identifier software, ZOOSCAN system can acquire and classify
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digital zooplankton images from collected zooplankton communities by comparing scanned
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images of each organism with a reference library. Meanwhile, the biomass and accurate body
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size of each species can be estimated by ZOOSCAN system for a quantitative study of
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zooplankton samples. However, ZOOSCAN is suitable for organisms with body size ranging
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from 200 µm to several centimeters, which excludes most taxa of rotifera and protozoa
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zooplankton in freshwater ecosystems. Currently, ZOOSCAN systems are popularly applied
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in marine ecosystems to rapidly estimate biomass and size distribution of mesozooplankton
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for biodiversity monitoring (Schultes et al. 2009).
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FlowCAM, which is developed based on the fluid imaging technology, is an automated
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imaging flow cytometer. FlowCAM uses laser detection to capture digital images of
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particles/organisms in a fluid. Image analysis of collected digitized images enable accurate
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estimation of the abundance and size of organisms and automatic classification of organisms
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(EÁlvarez et al. 2011). Depending on the setup of the instrument, FlowCAM can detect
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organisms with body size from 3 to 3000 µm, including almost all species in zooplankton
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communities in freshwater ecosystems, especially in polluted ones dominated by
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smaller-sized species (Xiong et al. 2019). Though FlowCAM was created for analyzing
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phytoplankton (Buskey & Hyatt 2006; Poulton 2016), more studies have used advanced 9
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FlowCAM to quantitatively analyze zooplankton (Le Bourg et al. 2015; Di Mauro et al. 2016;
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Broadway et al. 2018). Ide et al. (2008) carried out an adequate evaluation of zooplankton and
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phytoplankton in feeding of two omnivory copepod species using FlowCAM. Stanislawczyk
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(2016) demonstrated the capability of FlowCAM to distinguish between closely related
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zooplankton taxa and detect rare species such as exotic species at early developmental stages.
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Wang et al. (2017) used FlowCAM to quantitatively monitor zooplankton grazers in low
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abundance in algal cultures for early warning. In addition, Wong et al. (2017) optimized
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FlowCAM to overcome difficulties in low abundance samples. Altogether, the ability to
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automatically detect and count zooplankton in mixed-species samples in a rapid way is an
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obvious advantage in monitoring biodiversity in polluted freshwater ecosystems. In addition,
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FlowCAM can detect low abundance species, such as threatened or newly introduced
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nonnative invasive species, for conservation management and risk assessment.
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2.3 Technical challenges
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Traditional freshwater biodiversity monitoring is often based on direct observation
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methods, which are usually done by using an instrument to directly (e.g., microscope or SEM)
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or indirectly (e.g., ZOOSCAN and FlowCAM) observe morphological features of
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zooplankton organisms. There is no doubt that such methods cannot be totally replaced by
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new strategies such as genetic methods, thus we should know technical issues that have not
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been solved to possibly avoid errors.
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By using SEM, the accuracy of traditional morphological approaches can be highly
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improved (Naito et al. 2019). Obviously, the detailed features, particularly new taxonomic
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keys, should be deeply investigated and validated by competent taxonomists. Such detailed 10
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investigations can subside debates on taxonomy but are unlikely appropriate for large-scale
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surveys for ecological studies, such as causes and consequences of environmental pollution in
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freshwater ecosystems. ZOOSCAN and FlowCAM highly increase the efficiency of sample
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processing by automating and digitalizing samples. However, both ZOOSCAN and
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FlowCAM compromise resolution of species identification (Gorsky et al. 2010; EÁlvarez et
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al. 2013). Images captured by ZOOSCAN or FlowCAM are usually identified to high
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taxonomic levels such as genus or above (EÁlvarez et al. 2013; Detmer et al. 2019). In
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addition, ZOOSCAN has sound performance for species with body size ranging from 200µm
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to several centimeters. While in polluted freshwater, zooplankton communities are commonly
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dominated by small organisms such as rotifers and ciliates (Xiong et al. 2017, 2019; Yang et
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al. 2018). Meanwhile, libraries for taxonomy classification of digital images were constituted
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from zooplankton species in oceans, thus great effort is needed to create reference libraries
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derived from freshwater ecosystems. FlowCAM is more compatible to monitoring
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zooplankton in polluted freshwater ecosystems, but it is also limited by the same problems as
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ZOOSCAN (i.e., reference libraries). In addition, automatic classification of samples is
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error-prone, as all types of objects, including artifacts, are encountered in collected
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zooplankton samples (Culverhouse et al. 2006; EÁlvarez et al. 2011, 2013). As a result,
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validation or data quality control must be done to avoid errors generated from automatic
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processes.
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3 DNA-based methods for zooplankton biodiversity monitoring
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3.1 Biodiversity monitoring based on (meta)barcoding
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To overcome the limitation of conventional morphology-based methods, improved 11
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methods are urgently required for more rapid, sensitive and efficient detection of zooplankton
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species in freshwater ecosystems. With the development of molecular biology and sequencing
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technologies, DNA-based approaches provide opportunities for species identification and
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biodiversity survey in complex communities (Kelly et al. 2014; Creer et al. 2016; Brown et al.
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2015). Taxa can be distinguished by a specific short DNA sequence derived from several
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evolutionarily conserved genes in genomes or organelles (i.e., DNA barcode, Hebert et al.
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2003). Thus, DNA barcoding-based method is particularly powerful for identifying cryptic
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species by PCR amplification and sequencing of the selected DNA barcodes, which can
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potentially avoid artificial errors by traditional methods. Recently, technical advances of
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high-throughput sequencing (HTS) have largely revolutionized DNA barcoding-based
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methods, allowing rapid species identification of individuals across diverse ranges of taxa in
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environmental samples simultaneously in a single effort (i.e., DNA metabarcoding, Deiner et
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al. 2017).
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When compared to traditional methods, DNA metabarcoding-based methods are
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minimally invasive, faster, comprehensive, and time/cost-effective (Lim et al. 2016; Valentini
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et al. 2016; Ji et al. 2013; Xiong et al. 2016a). As a result, DNA metabarcoding-based
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methods have been popularly applied in the detection and bio-monitoring of biodiversity in a
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wide range of taxonomic groups, such as sharks, fishes, amphibians, and insects in aquatic
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ecosystems (Hanfling et al. 2016; Valentini et al. 2016; Bista et al. 2017; Boussarie et al.
256
2018). Shaw et al. (2017) compared fish communities detected by DNA metabarcoding with
257
that by conventional fyke netting in the North Para River (NPR) in South Australia, and their
258
results showed that DNA metabarcoding approach could detect 100% of the net-caught fish 12
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species under the premise that the sampling strategies were appropriate. The detection
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probability of amphibians and the number of detected fishes via DNA metabarcoding were
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higher than that by traditional methods (Valentini et al. 2016), clearly indicating that DNA
262
metabarcoding has the potential to become an important approach in biodiversity monitoring
263
in freshwater ecosystem. In addition, Yang et al. (2017a) compared the detection capacity of
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DNA metabarcoding with traditional morphology-based methods in studying the zooplankton
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community structure in eutrophic Lake Tai Basin of China, and their results showed that the
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species composition and biomass represented by sequence read counts obtained by DNA
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metabarcoding were consistent with morphological data. Indeed, DNA metabarcoding-based
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methods largely facilitated our understanding of biological consequences of environmental
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pollutions in freshwater ecosystems. Li et al. (2018) detected multiple taxa in protist and
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metazoan communities in the Yangtze River Delta using DNA metabarcoding, and they
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revealed that the community structure and biodiversity changes were mainly driven by
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nutrient levels. Xiong et al. (2017, 2019) illustrated that large-sized arthropods in slightly
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polluted river segments were shifted to small-sized species such as rotifers and ciliates in
274
highly disturbed areas, clearly putting forward an important ecological mechanism that the
275
role of species sorting can override dispersal as the dominant driver in determining
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community structure (i.e., fine-scale species sorting hypothesis). Therefore, DNA
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metabarcoding-based methods offer a sensitive, fast and powerful strategy to investigate
278
biodiversity fluctuation dynamics and further demonstrate important ecological problems
279
caused by water pollution derived from human activities (Chain et al. 2016; Xiong et al.
280
2019). 13
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The typical operational procedure of DNA metabarcoding technology for freshwater
282
biodiversity monitoring consists of the following five steps: sample collection, DNA
283
extraction, PCR amplification for selected genetic markers, sequencing and bioinformatics
284
analysis (Fig. 3). Here we briefly discuss the key technical issues that require attention to
285
avoid or decrease errors/bias during biodiversity assessment. It should be noted that despite
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DNA metabarcoding method has been widely used in biodiversity research and monitoring
287
(Goldberg et al. 2016; Leese et al. 2016; Deiner et al. 2017), many technical issues have not
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solved or well solved (Xiong et al. 2016). Thus, perfect and standardized protocols are still
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largely needed (Xiong et al. 2016a; Majaneva et al. 2018).
290
3.1.1 Sample collection and DNA isolation/capture
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There are two strategies of sampling zooplankton in biodiversity monitoring. One is
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sampling bulk specimen samples (community DNA metabarcoding), by which zooplankton
293
can be quantitatively collected and enriched by filtering the same volume of water at each
294
sampling site using plankton nets (Yang et al. 2017; Xiong et al. 2017, 2019). The collected
295
samples can be directly preserved in anhydrous alcohol, or further filtered through 5-µm
296
microporous filter membranes, then stored at -20 ℃ for subsequent DNA extraction. The
297
other strategy is sampling environmental DNA samples (eDNA metabarcoding) (Hanfling et
298
al. 2016; Zhang et al. 2018). Environmental DNA (eDNA) is the suspended DNA traces from
299
skin cells, organelles, gametes or even extracellular DNA of all organisms living in aquatic
300
ecosystems (Deiner et al. 2017). Environmental DNA can be captured onto filter membranes
301
by filtering 1-2 L of water in field or laboratory and preserved in anhydrous alcohol. To date,
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there is still a debate on the selection of filers and associated parameters including type, pore 14
303
size, pre-filtration and filter preservation strategy during the eDNA capture process. The most
304
commonly used filter for eDNA capture is 0.45-µm cellulose nitrate membrane, followed by
305
0.75/1.2-µm glass microfiber filers or polyethersulfone (Hanfling et al. 2016; Majaneva et al.
306
2018). Besides, in order to avoid false negatives caused by random sampling of rare taxa, it is
307
important to conduct repeated sampling for at least three times at each sampling site
308
(Thomsen et al. 2012).
309
It is important to keep in mind when we collect eDNA samples for biodiversity
310
monitoring that 1) the stability, dispersal and degradation rate of eDNA are substantially
311
influenced by various environmental factors such as temperature, pH, light intensity and
312
water chemistry (Goldberg et al. 2016; Seymour et al. 2018); 2) the temporal and spatial
313
distribution of eDNA highly vary in different ecosystems such as rivers and lakes, largely
314
owing to the transport of eDNA over large geographical scales in rivers and long retention
315
time in lakes (Turner et al. 2015; Deiner et al. 2016; Carraro et al. 2018); 3) eDNA from
316
different vertical depth of river and lakes has different biological significance, with that of
317
surface water indicating recent site biodiversity while sediments representing historical
318
biodiversity (Deiner et al. 2017). Thus, steps of eDNA capture need to be optimized in each
319
study, especially for highly polluted water with special hydrochemical features.
320
Currently, most studies relating to zooplankton biodiversity analysis used bulk specimen
321
samples (Xiong et al. 2017, 2019; Chain et al. 2015). However, when using eDNA to perform
322
biodiversity monitoring, sampling will be easier and less invasive. Djurhuus et al. (2018)
323
assessed the potential of eDNA metabarcoding to monitoring zooplankton biodiversity, by
324
comparing method of eDNA metabarcoding to bulk sample metabarcoding and 15
325
morphological methods, and they suggested that eDNA metabarcoding should be able to
326
provide complementary insights in biodiversity monitoring of zooplankton.
327
3.1.2 Selection of robust genetic markers and universal primers
328
“DNA metabarcode” is a fragment of DNA sequence being used for taxonomic
329
identification of multiple species existing in a mixed sample collected from communities or
330
environments (Deiner et al. 2017). The selection of DNA metabarcode will greatly influence
331
the detected species number and composition of taxonomic groups, as well as the accuracy of
332
species identification (Andújar et al. 2018a). Thus, the choice of appropriate genetic makers
333
is of vital importance for DNA metabarcoding analysis (Zhan & MacIsaac 2015). A desired
334
genetic marker for PCR primer design is expected to simultaneously possess both
335
evolutionarily conserved and hypervariable regions, of which conserved regions were used to
336
design universal primers for amplifying a wide range of species or taxonomic groups
337
(versatility), and hypervariable regions in the amplicons were used to accurately distinguish
338
the closely related species (high resolution) (Zhan & MacIsaac 2015).
339
Owing to the relatively high evolutionary rate and high taxonomic resolution capability,
340
the mitochondrial cytochrome c oxidase subunit I gene (COI) is considered as a competent
341
candidate genetic marker for metabarcoding survey for metazoa (Zhan & Maclsaac 2015;
342
Andújar et al. 2018b; Fernández et al. 2018). However, the amplification of COI in some
343
taxonomic groups such as crustaceans is still a difficult task, particularly in bulk samples (see
344
the review by Zhan & Maclsaac 2015 and references therein). To find a desired genetic
345
marker to metabarcode zooplankton biodiversity, Zhan et al. (2013, 2014) designed primer
346
pairs based on 18S and compared three commonly used genetic marker, including 18S, COI 16
347
and 16S by testing performance of different primer pairs, and they proposed that 18S was the
348
most efficient and powerful genetic marker for zooplankton biodiversity monitoring. Clarke
349
et al. (2017) claimed that COI (Leray et al. 2013) and 18S (Zhan et al. 2013) recovered
350
similar taxonomic coverage and beta-diversity, but different biomass and sequence reads
351
relationship and resolution, by comparing performance of these two best-known primer sets
352
in biodiversity study of zooplankton. Yet, Andújar et al. (2018b) argued that COI still should
353
be the most appropriate DNA metabarcode for bulk community analysis based on the
354
following reasons: 1) high resolution for taxonomic identification; 2) extensive coverage of
355
COI in reference sequence databases; 3) advantage of a protein-coding gene to identify
356
spurious sequences.
357
For eDNA metabarcoding, there are more challenges for selecting genetic markers and
358
primers, mainly due to low quality and quantity of eDNA and high proportion of
359
co-amplification of microbial DNA (Stat et al. 2017). Here, we urgently suggest that genetic
360
markers and associated universal primers should be well tested before application,
361
particularly on several parameters such as coverage of taxonomic groups and amplification
362
efficiency and bias. It is true that there are no perfect genetic markers and associated
363
universal primers for all taxonomic groups, but careful consideration of all influential
364
parameters can largely improve the power of DNA metabarcoding-based biodiversity survey.
365
While researchers struggle to select efficient genetic marker and primer sets in
366
metabarcoding, PCR-free methods are emerging recently, such as shotgun sequencing after
367
mitochondrial enrichment (Zhou et al. 2013). This method is independent on PCR, as
368
mitochondrial DNA is enriched during metaDNA extraction and sequenced by ultra-deep 17
369
high-throughput sequencing (HTS), and then COI sequences are retrieved by bioinformatic
370
analyses (Zhou et al. 2013). To avoid high cost of ultra-deep HTS and advance PCR-free
371
methods in routine environmental biomonitoring, a gene-enrichment technique was
372
recommended by Dowle et al. (2016). This method is derived from probe enrichment
373
techniques used in human genomic research (Blow 2009) and uses gene capture probes to
374
enrich target genes, followed by HTS to monitor biodiversity of aquatic communities (Dowle
375
et al. 2016). These two methods overcome PCR-derived biases to provide better estimate of
376
species abundance or biomass of target organisms, enhancing both the DNA sequence
377
information per taxon and the number of taxa.
378
3.1.3 Bioinformatics analysis
379
Enormous short sequence reads are generated by high throughput sequencing (HTS) in
380
DNA metabarcoding analysis, particularly after processing a large number of samples
381
collected from large geographical scales. Such big data sets pose vast challenges to
382
subsequent data processing procedures. A general data analysis process includes raw data
383
filtering, clustering of operational taxonomic units (OTUs), and taxonomy assignment.
384
Available evidence shows that sequencing errors greatly influence the biodiversity
385
estimates (Xiong et al. 2016a; Kunin et al. 2010). Thus, the removal of sequencing errors is
386
the first and one of the most important steps, which is challenged by discerning real rare taxa
387
from sequencing errors. Both rare species and artificial reads are usually recovered by low
388
number of sequences (e.g., low abundance OTUs), and the process of removal artificial reads
389
is prone to filter out a large proportion of rare species in samples (Zhan et al. 2014).
390
Depending on research aims, the clustering strategy for OTUs is another essential step for 18
391
assessing community biodiversity using DNA metabarcoding. These clustered molecular
392
OTUs were assigned to traditional taxonomic species in biodiversity monitoring, while
393
predefined similarity threshold (such as 97%) used in the clustering step may split one
394
traditional species into two or more OTUs or sequences for different taxa were clustered into
395
the same OTUs. To resolve this issue, newly developed methods, such as DADA2 (Callahan
396
et al. 2017) and UNOISE3 (Edgar 2016) were advanced algorithms of discerning and
397
removing sequencing errors and picked OTUs at similarity threshold of 100%, and LULU
398
was created for removing erroneous OTUs (Frøslev et al. 2017). Xiong & Zhan (2018) tested
399
different clustering strategies in studying zooplankton diversity, including newly developed
400
non-clustering (DADA2 and UNOISE 3) and clustering with different thresholds. Their
401
results showed that largely varied alpha biodiversity estimates were obtained by different
402
clustering strategies, but the ecological conclusions were consistently drawn by
403
non-clustering and clustering thresholds of 97-99%.
404
3.2 Indicator species detection based on metabarcoding
405
Owing to high sensitivity to environmental stressors, biological indicator species play
406
crucial roles in assessing pollution effects in aquatic ecosystems and provide early warning of
407
environmental changes (Casazza et al. 2002; Xiong et al. 2017, 2019). Identifying indicator
408
species, rather than traditional qualitative analysis of all species in biological communities,
409
provides a convenient and appealing approach in environmental monitoring, conservation and
410
management (Mächler et al. 2014). DNA barcoding has enhanced the sensitivity and
411
efficiency of species-level identification and highlights its wide use in indicator species
412
detection in biodiversity monitoring efforts (Hebert et al. 2003; Hebert & Gregory 2005). A
413
number of studies have documented the utility of DNA barcoding for species identification,
19
414
such as fish (Ward et al. 2005), copepods (Blanco-Bercial et al. 2014), crustaceans
415
(Radulovici et al. 2009), and molluscs (Layton et al. 2014). Recently, the application of DNA
416
barcoding method has been extended dramatically owing to the high-throughput sequencing
417
(HTS), enabling the identification of indicator species from mixed species samples or
418
communities (Cristescu 2014; Taberlet et al. 2012). Using HTS technologies to study the
419
relationship between geographical distributions of bacterial communities and water pollution,
420
Yang et al. (2019) revealed several effective bacteria as bio-indicators to assess river
421
pollution in Songhua River, suggesting the potential of micro-organisms as useful biological
422
indicators. Metabarcoding-based methods have been used to identify a variety of aquatic
423
indicator species for water-quality assessment and biodiversity monitoring, such as
424
arthropods (MäcHler et al. 2014; Thomsen et al. 2012; Xiong et al. 2017), gastropods
425
(Goldberg et al. 2013), amphibians (Goldberg et al. 2011; Thomsen et al. 2012), reptiles
426
(Piaggio et al. 2013), fishes (Jerde et al. 2011; Wilcox et al. 2013), and mammals (Foote et al.
427
2012; MäcHler et al. 2014). Thus, metabarcoding-based methods are robust tools to identify
428
indicative species from microscopic zooplankton.
429
3.3 Rare species detection based on metabarcoding and qPCR
430
Typically, aquatic communities are composed of a few dominant species and a high
431
diversity of low abundance species (i.e., ‘‘rare biosphere’’, Lynch & Neufeld 2015; Sogin et
432
al. 2006). The rare biosphere taxa may switch to new abundant members of a community in
433
response to environmental perturbation or change, and thus could provide a potential resource
434
of genetic and functional diversity to maintain ecosystem functioning. The rare biosphere in
435
running water ecosystems mainly include two types of species: native rare species and newly
436
introduced non-indigenous species (NIS). Owing to environmental pollution or demographic
437
stochasticity, native rare species may be at risk of extinction and become endangered (Wilson 20
438
et al. 2011). In addition, newly introduced NIS generally maintain low population density in
439
communities for a long period of time, even in cases when they eventually become dominant
440
to cause large-scale negative effects (Crooks & Soule 1999; Zhan et al. 2013). Therefore,
441
novel methods and effective measures should be taken to explore and monitor the rare
442
biosphere, in particular to identify native threatened rare species for conservation and
443
recently introduced NIS for biosecurity. However, there remain major technical challenges to
444
detect rare species, especially for microscopic organisms in freshwater ecosystems, owing to
445
their tiny body size, diverse species, complex community structure, and ambiguous
446
morphological traits (McDonald 2004; Zhan & MacIsaac 2015).
447
Metabarcoding has provided effective access to investigating rare species in complex
448
aquatic communities (Creer 2010; Xiong et al. 2016a). Zhan et al. (2013) quantitatively tested
449
the sensitivity of metabarcoding and claimed that metabarcoding enabled the detection of rare
450
species in complex zooplankton communities (biomass as low as 2.3 × 10-5%). Mounting
451
studies highlight the crucial role of metabarcoding in monitoring endangered species for
452
conservation (see the review by Cristescu & Hebert 2018 and references therein). Meanwhile,
453
metabarcoding helps early detection of NIS in aquatic ecosystems. For instance, Brown et al.
454
(2016) detected 24 non-indigenous species in Canadian ports, 11 of which were firstly
455
reported in the locations. Westfall et al. (2019) proposed a metabarcoding-based new
456
approach to molecular biosurveillance of invasive zooplankton species. Besides, for
457
accurately identifying protected species, DNA metabarcoding-based methods can provide
458
useful information about speciation time and phylogenetic diversity to perform quantitative
459
comparison rather than simply depending on the number of species within this area (Pečnikar 21
460
& Buzan 2014). In addition, commonly used genetic markers for HTS, such as COI, mt16S,
461
18S rDNA, would largely increase the comparability among different species, allowing us to
462
make the quantitative measurement of genetic diversity and evolutionary potential of rare
463
species and to confirm the relationships between endangered species and their surrounding
464
species. Thus, metabarcoding provides important insights in rare species detection, which
465
allows managers to make scientific decisions of species, populations and individuals for
466
protection.
467
Except screening rare species in mixed complex communities using metabarcoding,
468
species-specific PCR methods, including conventional PCR (cPCR) and real-time
469
quantitative PCR (qPCR), are DNA-based approaches to directly detect targeted endangered
470
or NIS species in low abundance (Xia et al. 2018). Conventional PCR has been applied to the
471
detection of a variety of aquatic NIS, including amphibians (Rana catesbeiana, Ficetola et al.
472
2008), crustaceans (Procambarus clarkii, Tréguier et al. 2014), mollusca (Limnoperna
473
fortune, Xia et al. 2018), and many other taxa. Real-time quantitative PCR (qPCR), which is
474
usually considered to be more sensitive than cPCR, provides a promising molecular tool for
475
detection and quantification of rare species (Arya et al. 2005; Wilcox et al. 2013). For
476
example, a quantitative real-time PCR (qPCR) amplification of 16s rDNA was performed to
477
quantitatively assess harmful algal bloom (HAB) risks in the Great Lakes (Doblin et al. 2007).
478
Recently, novel solutions, such as carbon nanotube platforms (Mahon et al. 2011), nucleic
479
acid sequence-based amplification (NASBA, Fykse et al. 2012), and droplet digital PCR
480
(ddPCR, Nathan et al. 2014), have extended the use of DNA-based methods in monitoring
481
targeted rare species. 22
482 483
3.4 Technical difficulties and possible solutions Although DNA-based methods exhibit evident advantages in assessing biodiversity,
484
there remain technical difficulties and challenges that need to be addressed for the
485
implementation of biodiversity monitoring programs. As mentioned above, PCR-free
486
approaches are able to overcome some limitations of PCR-based methods. However, these
487
methods have not been well tested in complex real-community samples (Zhou et al. 2013)
488
and showed low sensitivity to detect rare species (Srivathsan et al. 2014; Zhan and MacIsaac,
489
2015). In this study, we focus on the commonly used PCR-based methods (i.e., DNA
490
metabarcoding, Fig. 4).
491
3.4.1 False positives and negatives
492
The most notable problem confronting the process of DNA metabarcoding analyses is
493
the risk of error sources, including false positives (species detected but absent) and false
494
negatives (species undetected but present). A variety of issues can lead to false positives and
495
negatives (Darling & Mahon 2011; Zhan & MacIsaac 2015; Xiong et al. 2016a).
496
False positives, which is also known as Type II errors, can result from
497
cross-contamination from multiple sources, such as improper handling of samples, inadequate
498
specificity primers, and errors in data analysis (Xiong et al. 2016a; Cristescu et al. 2018; Li et
499
al. 2018). As a result of the increasing throughput of sequencing technologies, the pooling of
500
samples may lead to cross-contamination (Schmieder & Edwards 2011). Careful
501
manipulation, standard experimental protocols and contamination removal pipelines may
502
reduce cross-contamination risks and false positives. Moreover, negative and positive
503
controls should be added in the entire process (Jerde et al. 2011; Rees et al. 2014; Thomsen & 23
504
Willerslev 2015; Taberlet et al. 2018). In addition to cross-contamination, tag jumping among
505
pooled samples is another reason for false positives (Carlsen et al. 2012; Xiong et al. 2016a;
506
Zhan et al. 2016). There are some causes of tag jumping for HTS-based studies, such as
507
remaining unused tagged primers, using only one tagged primer, or sequencing long
508
amplicons (Xiong et al. 2016a). To minimize the probability of false positives caused by tag
509
jumping, paired tags should be added at both sides of amplicons (Carlsen et al. 2012).
510
Increasing the number of biological replicates, adding negative controls and applying strict
511
filtering pipelines would provide effective approaches to reducing the effect of tag jumping
512
(Kumar et al. 2011). In addition, other approaches that can contribute to avoidance of tag
513
jumping includes carefully purifying PCR products, immediately freezing PCR products, and
514
shortening their storage time (Kumar et al. 2011; Xiong et al. 2016).
515
The sources of false negatives (Type I errors) are mainly derived from random sampling
516
and biased PCR amplification (Xiong et al. 2016; Zhan et al. 2016a). When investigating
517
community structure with DNA metabarcoding, random sampling processes can result in low
518
reproducibility among replicate samples, especially for rare species, thus leading to false
519
negatives (Clarke et al. 2014; Engelbrektson et al. 2010; Zhan et al. 2014). Several technical
520
approaches should be performed to decrease false negatives by using more biological and
521
technical replicates, deeper sequencing, primers blocking against dominant taxa and
522
optimized species occupancy models (MacKenzie et al. 2002; Xiong et al. 2016a; Zhan et al.
523
2016). Another common and severe problem influencing taxonomic resolution power in DNA
524
metabarcoding studies is PCR amplification biases among species (Xiong et al. 2016). This
525
error source can be introduced by many factors, such as universality of the primers, annealing 24
526
temperature, the number of replication cycles, and relative abundance of different species in a
527
community (Bellemain et al. 2010; Engelbrektson et al. 2010). PCR amplification bias is
528
strongly influenced by the annealing temperature and the number of replication cycles during
529
library preparation. Low annealing temperature and cycle number can reduce the bias (Ishii &
530
Fukui 2001). Additional efforts include optimizing conditions of PCR amplification by
531
increasing template concentrations and adopting wise primers (Lim et al. 2010; Shokralla et
532
al. 2012). More importantly, the utilization of multiple versatile primers or two-step nested
533
PCR would reduce amplification biases and enhance the opportunity of rare species detection
534
(Sun et al. 2015; Xiong et al. 2016a; Zhang et al. 2018).
535
3.4.2 Reference database
536
Retrieving the taxonomic composition from sequences data is one of the primary aims
537
when we monitor biodiversity using DNA-based methods. This step is completely dependent
538
on comparing sequences against a metabarcode reference dataset containing taxonomy
539
information (Taberlet et al. 2018). The high-quality and complete reference databases for
540
taxonomic assignment directly determine the reliability of DNA metabarcoding. Even though
541
a large number of DNA sequences has been submitted to public databases, unbalanced
542
representation of different taxonomic groups in these public sequence databases is a major
543
issue (Briski et al. 2011). Available sequences for poorly studied species in public databases
544
remain low when compared to commercially important or better studied species (Briski et al.
545
2011). Thus, broad collaborations and sharing among different research groups who
546
particularly have their own taxa of interest, should be made to develop and improve
547
community-level reference libraries (Valentini et al. 2016). Additionally, most sequence 25
548
information was obtained from traditional molecular makers, such as COI and ribosomal
549
RNA genes in these databases, which is not enough to identify complex communities and
550
closely related species. Thus, more sequence information with diverse molecular makers
551
should collect in order to build comprehensive reference libraries.
552
From a taxonomic point view, reference datasets (Table 1) are poorly connected, though
553
part of them, such as EMBL, GenBank and DDBJ, have been united into the International
554
Nucleotides Sequence Database Collaboration (INSDC) and synchronized daily (Taberlet et
555
al. 2018). Lacking coherence among datasets largely limits meta-analyses on
556
metabarcoding-based studies. Thus, collaborative efforts remain necessary in the future for
557
biodiversity monitoring at the global scale.
558
4 Future perspectives
559
In summary, metabarcoding is revolutionizing the investigation of freshwater
560
biodiversity and presents a powerful tool of detection of “hidden diversity” under water
561
surface (Lindeque et al. 2013). We propose that DNA-based metabarcoding should be
562
embraced by researchers and managers, as its inherent practicable and applicable features can
563
largely solve technical issues in biodiversity assessment in polluted freshwater ecosystems.
564
Indeed, DNA-based metabarcoding has been approved by several international organizations,
565
such as the European Water Framework Directive of European Union. Yet, many technical
566
issues still remain in the application of metabarcoding-based biomonitoring in freshwater
567
ecosystems. We should firstly continue the development of taxonomically comprehensive
568
reference databases based on multiple genetic markers to support taxonomic retrieval of
569
metabarcoding analyses. Additionally, we should screen more variables gene regions, which 26
570
can ensure correct identification, discrimination and detection of closely related or cryptic
571
species. Alternatively, as HTS becomes more accessible and less expensive, the use of
572
short-gun sequencing strategy to sequence meta-DNA extracted from bulk samples would
573
increase the resolution of taxonomical identification. In addition, shot-gun sequencing is a
574
PCR-free method, which is beneficial to quantification of taxon abundance. Spiking the
575
standard DNA into different samples is a good method to make advance of quantification in
576
metabarcoding analyses. Finally, there is no doubt that traditional morphology-based methods
577
cannot be discarded, although many technical issues still exist among morphology-based
578
methods. Both traditional morphology-based and DNA-based methods must be
579
cross-referenced to ensure accurate and rapid identification of zooplankton species, and to
580
promote the dissection of causes and consequences of biodiversity loss in polluted freshwater
581
ecosystems.
582
Author Contributions
583
A.Z., B.S. and W.X. conceived the study. All authors wrote and revised the manuscript.
584
Acknowledgments
585
This work was supported by the National Natural Science Foundation of China [grant
586
numbers 31800307, 31572228], National Key R&D Program of China [grant number
587
2016YFC0500406], and Chinese Academy of Science [grant number ZDRW-ZS-2016-5-6].
588
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Xia, Z., Johansson, M. L., Gao, Y., Zhang, L., Haffner, G. D., MacIsaac, H. J., & Zhan, A.
994
(2018). Conventional versus real‐time quantitative PCR for rare species detection.
995
Ecology and Evolution, 8(23), 11799-11807.
996
Xiong, W., & Zhan, A. (2018). Testing clustering strategies for metabarcoding‐based
997
investigation of community–environment interactions. Molecular Ecology Resources,
998
18(6), 1326-1338.
999
Xiong, W., Li, H., & Zhan, A. (2016a). Early detection of invasive species in marine
1000
ecosystems using high-throughput sequencing: technical challenges and possible
1001
solutions. Marine Biology, 163(6), 139.
1002
Xiong, W., Li, J., Chen, Y., Shan, B., Wang, W., & Zhan, A. (2016b). Determinants of
1003
community structure of zooplankton in heavily polluted river ecosystems. Scientific
1004
Reports, 6, 22043.
1005
Xiong, W., Ni, P., Chen, Y., Gao, Y., Li, S., & Zhan, A. (2019). Biological consequences of
1006
environmental pollution in running water ecosystems: A case study in zooplankton.
1007
Environmental Pollution, 252, 1483-1490.
1008
Xiong, W., Ni, P., Chen, Y., Gao, Y., Shan, B., & Zhan, A. (2017). Zooplankton community
1009
structure along a pollution gradient at fine geographical scales in river ecosystems: the 46
1010 1011
importance of species sorting over dispersal. Molecular Ecology, 26, 4351-4360. Yang, J., Zhang, X., Xie, Y., Song, C., & Burton, G. A. (2017a). Zooplankton community
1012
profiling in a eutrophic freshwater ecosystem-lake Tai basin by DNA metabarcoding.
1013
Scientific Reports, 7(1773), 1-11.
1014
Yang, J., Zhang, X., Xie, Y., Song, C., Sun, J., Zhang, Y., ... & Yu, H. (2017b). Ecogenomics
1015
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1016
Environmental Science & Technology, 51(5), 3057-3064.
1017
Yang, Y., Li, S., Gao, Y., Chen, Y., & Zhan, A. (2019). Environment-driven geographical
1018
distribution of bacterial communities and identification of indicator taxa in Songhua
1019
River. Ecological Indicators, 101, 62-70.
1020
Zhan, A., & MacIsaac, H. J. (2015). Rare biosphere exploration using high-throughput
1021
sequencing: research progress and perspectives. Conservation Genetics, 16(3), 513-522.
1022
Zhan, A., Bailey, S. A., Heath, D. D., & Macisaac, H. J. (2014a). Performance comparison of
1023
genetic markers for high-throughput sequencing-based biodiversity assessment in
1024
complex communities. Molecular Ecology Resources, 14(5), 1049-1059.
1025
Zhan, A., He, S., Brown, E. A., Chain, F. J., Therriault, T. W., Abbott, C. L., ... & MacIsaac,
1026
H. J. (2014b). Reproducibility of pyrosequencing data for biodiversity assessment in
1027
complex communities. Methods in Ecology and Evolution, 5(9), 881-890.
1028
Zhan, A., Hulák, M., Sylvester, F., Huang, X., Adebayo, A. A., Abbott, C. L., ... & MacIsaac,
1029
H. J. (2013). High sensitivity of 454 pyrosequencing for detection of rare species in
1030
aquatic communities. Methods in Ecology and Evolution, 4(6), 558-565.
1031
Zhan, A., Xiong, W., He, S., & MacIsaac, H. J. (2014). Influence of artifact removal on rare 47
1032
species recovery in natural complex communities using high-throughput sequencing.
1033
PloS One, 9(5), e96928.
1034
Zhang, G. K., Chain, F. J., Abbott, C. L., & Cristescu, M. E. (2018). Metabarcoding using
1035
multiplexed markers increases species detection in complex zooplankton communities.
1036
Evolutionary Applications, 11(10), 1901-1914.
1037
Zhou, X., Li, Y., Liu, S., Yang, Q., Su, X., Zhou, L., ... & Huang, Q. (2013). Ultra-deep
1038
sequencing enables high-fidelity recovery of biodiversity for bulk arthropod samples
1039
without PCR amplification. Gigascience, 2(1), 4.
48
1040
Table 1 The most recent and important reference databases for zooplankton Database
Organisms
name
covered
EMBL-E
Bacteria/Archaea,
16S/23S rRNA
BI
Eukaryota
16S/18S/ COI
GenBank
Bacteria/Archaea,
16S/23S rRNA
Eukaryota
16S/18S/ COI
Bacteria/Archaea,
16S/23S rRNA
Eukaryota
16S/18S/ COI
Bacteria/Archaea,
16S/23S
Eukaryota
18S/28S
Animals,
COI
Plants,
rbcl, matk
Fungi
ITS
Protists
18S
DDBJ
SILVA
BOLD
PR2
Genetic markers
Establishe
Website
Reference
1980
https://www.ebi.ac.uk/ena
--
1982
https://www.ncbi.nlm.nih.g
Leray et al.
ov/genbank/
(2019)
https://www.ddbj.nig.ac.jp/i
Mashima
ndex-e.html
al. (2016)
https://www.arb-silva.de/
Quast et al.
d year
1987
2007
et
(2012) 2007
http://www.boldsystems.org
Ratnasingha
/
m & Hebert (2007)
2012
ssu-rrna.org/pr2
Guillou et al. (2013)
1041
49
1042
Figure captions:
1043
Figure 1 Photos of zooplankton observed by traditional morphological methods referred
1044
from Rotifer World Catalog (Jersabek & Leitner 2013). A: Brachionus angularis Gosse, 1851;
1045
B: Brachionus diversicornis (Daday, 1883); C: Keratella cochlearis (Gosse, 1851); D:
1046
Brachionus forficula Wierzejaki, 1891; E: Brachionus quadridentatus Hermann, 1783; F:
1047
Keratella cochlearis (Gosse, 1851); G: Trichotria tetractis (Ehrenberg, 1830).
1048
Figure 2 Morphology-based methods for zooplankton biodiversity monitoring.
1049
Figure 3 Workflow and key technical points of metabarcoding in biodiversity monitoring of
1050
zooplankton.
1051
Figure 4 Technical difficulties and possible solutions in flowchart of biodiversity monitoring
1052
of zooplankton.
50
1053
Figure 1
1054 1055
51
1056
Figure 2
1057 1058
52
1059
Figure 3
1060 1061
53
1062
Figure 4
1063
54
Highlights 1.
Freshwater ecosystems and associated biodiversity have been highly degraded.
2.
Biodiversity monitoring is crucial for diagnosing degradation degrees
3.
Here we review available methods for monitoring zooplankton biodiversity.
4.
We propose possible solutions for existing technical issues.
S2666-4984(19)30008-0
DOI:
https://doi.org/10.1016/j.ese.2019.100008
Reference:
ESE 100008
To appear in:
Environmental Science and Ecotechnology
Please cite this article as: W. Xiong, X. Huang, Y. Chen, R. Fu, X. Du, X. Chen, A. Zhan, Zooplankton Biodiversity Monitoring in Polluted Freshwater Ecosystems: A technical review, Environmental Science and Ecotechnology, https://doi.org/10.1016/j.ese.2019.100008. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 The Author(s). Published by Elsevier B.V. on behalf of Chinese Society for Environmental SciencesHarbin Institute of TechnologyChinese Research Academy of Environmental Sciences.
1
Zooplankton Biodiversity Monitoring in Polluted Freshwater
2
Ecosystems: A technical review
3 4
Wei Xiong1, Xuena Huang1, Yiyong Chen1, Ruiying Fu1, Xun Du1, Xingyu Chen1,2, Aibin
5
Zhan1,3*
6 7
1
8
Shuangqing Road, Haidian District, Beijing 100085, China;
9
2
Research Center for Eco-Environmental Sciences, Chinese Academy of Sciences, 18
College of Resources, Environment and Tourism, Capital Normal University, 105 West
10
Third Ring Road, Haidian District, Beijing 100048, China;
11
3
12
Road, Shijingshan District, Beijing 100049, China.
University of Chinese Academy of Sciences, Chinese Academy of Sciences, 19A Yuquan
13 14
*Corresponding authors:
15
Prof. Aibin Zhan; Email: [email protected] or [email protected]; Phone & Fax:
16
(+86)-10-6284-9882;
1
17
ABSRACT
18
Freshwater ecosystems harbor a vast diversity of micro-eukaryotes (rotifers, crustaceans and
19
protists), and such diverse taxonomic groups play important roles in ecosystem functioning
20
and services. Unfortunately, freshwater ecosystems and biodiversity therein are threatened by
21
many environmental stressors, particularly those derived from intensive human activities
22
such as chemical pollution. In the past several decades, significant efforts have been devoted
23
to halting biodiversity loss to recover services and functioning of freshwater ecosystems.
24
Biodiversity monitoring is the first and a crucial step towards diagnosing pollution impacts
25
on ecosystems and making conservation plans. Yet, bio-monitoring of ubiquitous
26
micro-eukaryotes is extremely challenging, owing to many technical issues associated with
27
micro-zooplankton such as microscopic size, fuzzy morphological features, and extremely
28
high biodiversity. Here, we review current methods used for monitoring zooplankton
29
biodiversity to advance management of impaired freshwater ecosystems. We discuss the
30
development of traditional morphology-based identification methods such as scanning
31
electron microscope (SEM) and ZOOSCAN and FlowCAM automatic systems, and
32
DNA-based strategies such as metabarcoding and real-time quantitative PCR. In addition, we
33
summarize advantages and disadvantages of these methods when applied for monitoring
34
impacted ecosystems, and we propose practical DNA-based monitoring workflows for
35
studying biological consequences of environmental pollution in freshwater ecosystems.
36
Finally, we propose possible solutions for existing technical issues to improve accuracy and
37
efficiency of DNA-based biodiversity monitoring.
38
Keywords: biodiversity, micro-eukaryotes, metabarcoding, freshwater ecosystem, water 2
39
pollution.
40
1 Introduction
41
1.1 Biodiversity loss in freshwater ecosystems
42
Since the first proposition of the term ‘biodiversity’ in the United Nations’ Conference
43
on Environment and Development in 1992, the importance of biodiversity has been well
44
recognized and conservation of biodiversity has drawn substantial attention (Warren 1996).
45
Among various types of ecosystems, freshwater ecosystems provide unique habitats,
46
supporting a high level of biodiversity. Freshwater ecosystems occupy only approximately
47
0.8% of the Earth’s surface but support almost 6% of all known species (Dudgeon et al. 2006).
48
For example, more than 10,000 fish species live in freshwater ecosystems, accounting for 40%
49
of the known global fish species (Cazzolla 2016). In addition, freshwater ecosystems provide
50
irreplaceable goods and services for human beings, such as drinking and irrigation water,
51
food, creation, and regulation of micro-climate (Vörösmarty et al. 2010; Green et al. 2015).
52
However, many factors, particularly those derived from anthropogenic activities such as
53
water pollution and invasive species, have largely degraded freshwater ecosystems over the
54
past several decades (Dudgeon et al. 2006; Bush et al. 2017). Freshwater ecosystems such as
55
rivers and inland lakes are among the most threatened ecosystems on the Earth (Vörösmarty
56
et al. 2010; Alahuhta et al. 2019). As a result, biodiversity loss in freshwater ecosystems is
57
much faster than that in terrestrial counterparts (Geist 2011). Even worse, biodiversity loss in
58
threaten freshwater ecosystems have not slowed down in recent years (Butchart et al. 2010),
59
despite the fact that great effort has been placed on maintaining or recovering biodiversity in
60
freshwater ecosystems. These efforts have been largely unsuccessful due to frequent 3
61
disturbance derived from increasing anthropogenic activities and knowledge gaps on
62
biodiversity in freshwater ecosystems (Clausen & York 2008).
63
Indeed, biodiversity loss in freshwater ecosystem is likely much more severe than we
64
have realized, as biological response to disturbance in freshwater ecosystems is not
65
completely known, especially on the widespread but hidden microscopic taxa such as
66
zooplankton (Cazzolla 2016). A large body of scientific literature has illustrated the
67
biodiversity loss of macro-eukaryotes under human activity disturbance, such as fishes,
68
amphibians, mollusks and crustaceans (Williams 2002; Stuart et al. 2004; Nobles & Zhang,
69
2011; Freyhof & Brooks 2017). Nevertheless, studies on biodiversity loss dynamics of
70
micro-eukaryotes are rare (Xiong et al. 2019). In terms of monitoring and conservation
71
priority, better-known macro-eukaryotes have drawn more attention than micro-eukaryotes
72
such as microscopic zooplankton (Darwall et al. 2009). Indeed, the highly neglected
73
microscopic zooplankton play vital ecological roles in aquatic food-webs, such as linking
74
phytoplankton and bacteria to high trophic levels such as fish (Johnson et al. 2011). The
75
protection and recovery of overlooked microscopic zooplankton biodiversity largely
76
determine the conservation of biodiversity at high trophic levels, as well as the integration
77
and functioning of freshwater ecosystems.
78
1.2 Potential indicative roles of zooplankton in freshwater ecosystems
79
Zooplankton include diverse taxa such as protists, rotifers, copepods and cladocerans,
80
many of which are microscopic (De Vargas et al. 2015). Multiple studies have made a
81
consistent and crucial realization that zooplankton taxa are rapid responders to many
82
environmental stressors, such as hydrological changes, climate changes and anthropogenic 4
83
activity-induced water pollution (Duggan et al. 2001; Pawlowski et al. 2016). Specifically,
84
previous laboratory or field studies have indicated that zooplankton communities were
85
significantly impacted by excessive loading of nutrients (Duggan et al. 2001; Wang et al.
86
2010; Xiong et al. 2019), and also negatively affected by microplastics (Scherer et al. 2018),
87
pesticides (Hanazato 2001), and pharmaceuticals and personal care products (PPCPs) (Garric
88
2013). As such, researchers have identified their usefulness as ecological indicators to water
89
pollution. For instances, rotifers are used to diagnose ecological impacts of freshwater
90
toxicants, such as endocrine disruptors, bioconcentration of lead, and nanoparticles toxicity
91
(Snell & Marcial 2017). Yang et al. (2017b) indicated that zooplankton communities could be
92
used to predict ecological thresholds of ammonia nitrogen. Payne (2013) listed and
93
recommended seven key reasons for the use of protists as good bio-indicators in aquatic
94
ecosystems. Azevêdo et al. (2015) showed that zooplankton communities played a
95
complementary role to macroinvertebrates in indicating variation of the trophic status of
96
waters. Thus, bio-monitoring zooplankton communities has become a widely accepted and
97
irreplaceable aspect in ecological conservation and management of aquatic ecosystems.
98
1.3 Technical difficulties for biodiversity monitoring of zooplankton
99
Despite rapid development of novel technologies in the past several decades, most
100
traditional morphology-based methods have been used to investigate interactions between
101
biodiversity of zooplankton and environmental pollution in freshwater ecosystems (Wang et
102
al. 2010; Xiong et al. 2016b). In recent years, several novel strategies, such as metabarcoding
103
(see section 3.1 in this article), represent novel and robust approaches to profile microscopic
104
organisms more efficiently and with finer resolution (Bucklin et al. 2016). Studies have 5
105
facilitated the use of metabarcoding for assessing diversity of many zooplankton
106
communities (Zhan et al. 2013, 2014b; Brown et al. 2015; Xiong et al. 2018), such as protists
107
(Pawlowski et al. 2016) and copepods (Hirai et al. 2015). Metabarcoding-based methods have
108
generated detailed information about biodiversity of zooplankton, providing important
109
support to biodiversity conservation, such as the development of DNA-based ecological
110
status assessment under the European Water Framework Directive (Hering et al. 2018), and
111
advancement of routine freshwater bio-monitoring by using molecular methods (Blackman et
112
al. 2019).
113
Yet, there remain many methodological difficulties for biodiversity monitoring of
114
zooplankton in both morphology-based and DNA-based strategies in polluted freshwater
115
ecosystems, and many taxonomic groups of zooplankton are largely undescribed or unknown
116
(Dudgeon et al. 2006). The primary issue for morphology-based biodiversity monitoring is
117
resolution and efficiency. When gathering information on zooplankton composition and
118
abundance in a traditional way, it relies heavily on taxonomists who identify specimens under
119
a binocular microscope. The process is time- and cost-consuming and requires high expertise.
120
Moreover, both the number of samples that can be analyzed and the availability of competent
121
taxonomists are limited. Meanwhile, relatively low resolution imposes limitations on species
122
identification, particularly at larval/juvenile stages and for cryptic species or species complex.
123
In addition, morphology-based methods are challenged by rare species detection (Zhan et al.
124
2013), which is of great significance for biological conservation. Rare species, which are
125
often either endangered species or species under severe environmental stresses in polluted
126
ecosystems, should be protected or analyzed in priority. 6
127
Such difficulties in accurate morphological identification of species not only impede
128
biodiversity monitoring in a traditional way, but also hinder biodiversity investigation by
129
using DNA-based approaches (Zhan et al. 2013; Xiong et al. 2016a). Despite that DNA-based
130
methods obviously advance the efficiency and resolution, particularly for studies aiming at
131
large geographical scales, the precondition for DNA-based methods relies on available
132
reference databases that must be constructed based on morphological identification (Briski et
133
al. 2011). In addition, there are challenges in quantification of taxon abundance in using
134
DNA-based methods such as metabarcoding, as metabarcoding analysis has not shown good
135
agreement between specie abundance data and sequence abundance (e.g., Sun et al. 2015).
136
1.4 Our aims
137
To advance management of impaired freshwater ecosystems, this review aims to provide
138
an overview of available methods for monitoring biodiversity of eukaryotic zooplankton,
139
including both morphology-based and DNA-based approaches. In addition, we discuss
140
technical difficulties, as well as causes and consequences of these difficulties in biodiversity
141
monitoring. Finally, we propose a practical monitoring workflow to study biological
142
consequences of environmental pollution in aquatic ecosystems as take-home information.
143
2 Morphology-based methods for zooplankton biodiversity monitoring
144
2.1 Traditional morphological methods
145
The acquisition of biodiversity data has historically been based on morphological
146
characterization of species. Researchers use many tools such as nets, pumps or water bottles
147
to collect specimens and gatherer formation of composition and abundance of species, and
148
then collected specimens are subjected for identification by taxonomists under a microscope 7
149
(Gorsky et al. 2010; EÁlvarez et al. 2013; Andújar et al. 2018b). This traditional technique is
150
considered to be useful for the identification and enumeration of microplankton (Fig. 1), and
151
thus providing invaluable information on species identification (Gorsky et al. 2010; EÁlvarez
152
et al. 2013). For instance, Humes (1994) have reported approximate 11500 morphological
153
species of copepods. Kreutz & Foissner (2006) edited a book of protozoological monographs,
154
recording 670 species of protists, micro-metazoans and bacteria in ponds of Simmelried in
155
Germany. Wang (1961) studied and recorded 252 freshwater rotifer species in China, which
156
laid the foundation for rotifer study in China.
157
With the advent of morphological identification by electron microscopes, the scanning
158
electron microscope (SEM) has become a powerful analytical tool (Fig. 2). The use of SEM
159
significantly increases the resolution in specimen identification and helps detect taxonomy
160
keys. For instance, by using SEM, several rotifer species with differentiated trophi were
161
identified in an apparently morphological uniform genus (Segers 1995). Papa et al. (2012)
162
updated taxonomic status of crustacean zooplankton in a lake in Philippines using a
163
combination of light and scanning electron microscopes. Hines (2019) studied the
164
biogeography of freshwater ciliates (protozoa) in Florida, USA with a high resolution of
165
species identification by SEM. Thus, SEM has become an important complementary tool for
166
morphology-based monitoring of zooplankton, particularly on microscopic taxa with debates.
167
2.2 New morphological identification methods
168
It is obvious that both traditional microscopes and SEMs can detect biological features
169
in detail but fail to analyze a large number of species rapidly. With the advent of digital
170
imaging and scanning technologies, several automatic or semiautomatic instruments have 8
171
been developed to rapidly analyze zooplankton samples. The two representative ones are
172
ZOOSCAN system (Gorsky et al. 2010) and Flow Ctometer And Microscope (FlowCAM)
173
(EÁlvarez et al. 2013). ZOOSCAN takes digital images of zooplankton samples and analyze
174
images based on available databases in a fast and (semi-)automatic way. By integrating
175
ZooProcess and Plankton Identifier software, ZOOSCAN system can acquire and classify
176
digital zooplankton images from collected zooplankton communities by comparing scanned
177
images of each organism with a reference library. Meanwhile, the biomass and accurate body
178
size of each species can be estimated by ZOOSCAN system for a quantitative study of
179
zooplankton samples. However, ZOOSCAN is suitable for organisms with body size ranging
180
from 200 µm to several centimeters, which excludes most taxa of rotifera and protozoa
181
zooplankton in freshwater ecosystems. Currently, ZOOSCAN systems are popularly applied
182
in marine ecosystems to rapidly estimate biomass and size distribution of mesozooplankton
183
for biodiversity monitoring (Schultes et al. 2009).
184
FlowCAM, which is developed based on the fluid imaging technology, is an automated
185
imaging flow cytometer. FlowCAM uses laser detection to capture digital images of
186
particles/organisms in a fluid. Image analysis of collected digitized images enable accurate
187
estimation of the abundance and size of organisms and automatic classification of organisms
188
(EÁlvarez et al. 2011). Depending on the setup of the instrument, FlowCAM can detect
189
organisms with body size from 3 to 3000 µm, including almost all species in zooplankton
190
communities in freshwater ecosystems, especially in polluted ones dominated by
191
smaller-sized species (Xiong et al. 2019). Though FlowCAM was created for analyzing
192
phytoplankton (Buskey & Hyatt 2006; Poulton 2016), more studies have used advanced 9
193
FlowCAM to quantitatively analyze zooplankton (Le Bourg et al. 2015; Di Mauro et al. 2016;
194
Broadway et al. 2018). Ide et al. (2008) carried out an adequate evaluation of zooplankton and
195
phytoplankton in feeding of two omnivory copepod species using FlowCAM. Stanislawczyk
196
(2016) demonstrated the capability of FlowCAM to distinguish between closely related
197
zooplankton taxa and detect rare species such as exotic species at early developmental stages.
198
Wang et al. (2017) used FlowCAM to quantitatively monitor zooplankton grazers in low
199
abundance in algal cultures for early warning. In addition, Wong et al. (2017) optimized
200
FlowCAM to overcome difficulties in low abundance samples. Altogether, the ability to
201
automatically detect and count zooplankton in mixed-species samples in a rapid way is an
202
obvious advantage in monitoring biodiversity in polluted freshwater ecosystems. In addition,
203
FlowCAM can detect low abundance species, such as threatened or newly introduced
204
nonnative invasive species, for conservation management and risk assessment.
205
2.3 Technical challenges
206
Traditional freshwater biodiversity monitoring is often based on direct observation
207
methods, which are usually done by using an instrument to directly (e.g., microscope or SEM)
208
or indirectly (e.g., ZOOSCAN and FlowCAM) observe morphological features of
209
zooplankton organisms. There is no doubt that such methods cannot be totally replaced by
210
new strategies such as genetic methods, thus we should know technical issues that have not
211
been solved to possibly avoid errors.
212
By using SEM, the accuracy of traditional morphological approaches can be highly
213
improved (Naito et al. 2019). Obviously, the detailed features, particularly new taxonomic
214
keys, should be deeply investigated and validated by competent taxonomists. Such detailed 10
215
investigations can subside debates on taxonomy but are unlikely appropriate for large-scale
216
surveys for ecological studies, such as causes and consequences of environmental pollution in
217
freshwater ecosystems. ZOOSCAN and FlowCAM highly increase the efficiency of sample
218
processing by automating and digitalizing samples. However, both ZOOSCAN and
219
FlowCAM compromise resolution of species identification (Gorsky et al. 2010; EÁlvarez et
220
al. 2013). Images captured by ZOOSCAN or FlowCAM are usually identified to high
221
taxonomic levels such as genus or above (EÁlvarez et al. 2013; Detmer et al. 2019). In
222
addition, ZOOSCAN has sound performance for species with body size ranging from 200µm
223
to several centimeters. While in polluted freshwater, zooplankton communities are commonly
224
dominated by small organisms such as rotifers and ciliates (Xiong et al. 2017, 2019; Yang et
225
al. 2018). Meanwhile, libraries for taxonomy classification of digital images were constituted
226
from zooplankton species in oceans, thus great effort is needed to create reference libraries
227
derived from freshwater ecosystems. FlowCAM is more compatible to monitoring
228
zooplankton in polluted freshwater ecosystems, but it is also limited by the same problems as
229
ZOOSCAN (i.e., reference libraries). In addition, automatic classification of samples is
230
error-prone, as all types of objects, including artifacts, are encountered in collected
231
zooplankton samples (Culverhouse et al. 2006; EÁlvarez et al. 2011, 2013). As a result,
232
validation or data quality control must be done to avoid errors generated from automatic
233
processes.
234
3 DNA-based methods for zooplankton biodiversity monitoring
235
3.1 Biodiversity monitoring based on (meta)barcoding
236
To overcome the limitation of conventional morphology-based methods, improved 11
237
methods are urgently required for more rapid, sensitive and efficient detection of zooplankton
238
species in freshwater ecosystems. With the development of molecular biology and sequencing
239
technologies, DNA-based approaches provide opportunities for species identification and
240
biodiversity survey in complex communities (Kelly et al. 2014; Creer et al. 2016; Brown et al.
241
2015). Taxa can be distinguished by a specific short DNA sequence derived from several
242
evolutionarily conserved genes in genomes or organelles (i.e., DNA barcode, Hebert et al.
243
2003). Thus, DNA barcoding-based method is particularly powerful for identifying cryptic
244
species by PCR amplification and sequencing of the selected DNA barcodes, which can
245
potentially avoid artificial errors by traditional methods. Recently, technical advances of
246
high-throughput sequencing (HTS) have largely revolutionized DNA barcoding-based
247
methods, allowing rapid species identification of individuals across diverse ranges of taxa in
248
environmental samples simultaneously in a single effort (i.e., DNA metabarcoding, Deiner et
249
al. 2017).
250
When compared to traditional methods, DNA metabarcoding-based methods are
251
minimally invasive, faster, comprehensive, and time/cost-effective (Lim et al. 2016; Valentini
252
et al. 2016; Ji et al. 2013; Xiong et al. 2016a). As a result, DNA metabarcoding-based
253
methods have been popularly applied in the detection and bio-monitoring of biodiversity in a
254
wide range of taxonomic groups, such as sharks, fishes, amphibians, and insects in aquatic
255
ecosystems (Hanfling et al. 2016; Valentini et al. 2016; Bista et al. 2017; Boussarie et al.
256
2018). Shaw et al. (2017) compared fish communities detected by DNA metabarcoding with
257
that by conventional fyke netting in the North Para River (NPR) in South Australia, and their
258
results showed that DNA metabarcoding approach could detect 100% of the net-caught fish 12
259
species under the premise that the sampling strategies were appropriate. The detection
260
probability of amphibians and the number of detected fishes via DNA metabarcoding were
261
higher than that by traditional methods (Valentini et al. 2016), clearly indicating that DNA
262
metabarcoding has the potential to become an important approach in biodiversity monitoring
263
in freshwater ecosystem. In addition, Yang et al. (2017a) compared the detection capacity of
264
DNA metabarcoding with traditional morphology-based methods in studying the zooplankton
265
community structure in eutrophic Lake Tai Basin of China, and their results showed that the
266
species composition and biomass represented by sequence read counts obtained by DNA
267
metabarcoding were consistent with morphological data. Indeed, DNA metabarcoding-based
268
methods largely facilitated our understanding of biological consequences of environmental
269
pollutions in freshwater ecosystems. Li et al. (2018) detected multiple taxa in protist and
270
metazoan communities in the Yangtze River Delta using DNA metabarcoding, and they
271
revealed that the community structure and biodiversity changes were mainly driven by
272
nutrient levels. Xiong et al. (2017, 2019) illustrated that large-sized arthropods in slightly
273
polluted river segments were shifted to small-sized species such as rotifers and ciliates in
274
highly disturbed areas, clearly putting forward an important ecological mechanism that the
275
role of species sorting can override dispersal as the dominant driver in determining
276
community structure (i.e., fine-scale species sorting hypothesis). Therefore, DNA
277
metabarcoding-based methods offer a sensitive, fast and powerful strategy to investigate
278
biodiversity fluctuation dynamics and further demonstrate important ecological problems
279
caused by water pollution derived from human activities (Chain et al. 2016; Xiong et al.
280
2019). 13
281
The typical operational procedure of DNA metabarcoding technology for freshwater
282
biodiversity monitoring consists of the following five steps: sample collection, DNA
283
extraction, PCR amplification for selected genetic markers, sequencing and bioinformatics
284
analysis (Fig. 3). Here we briefly discuss the key technical issues that require attention to
285
avoid or decrease errors/bias during biodiversity assessment. It should be noted that despite
286
DNA metabarcoding method has been widely used in biodiversity research and monitoring
287
(Goldberg et al. 2016; Leese et al. 2016; Deiner et al. 2017), many technical issues have not
288
solved or well solved (Xiong et al. 2016). Thus, perfect and standardized protocols are still
289
largely needed (Xiong et al. 2016a; Majaneva et al. 2018).
290
3.1.1 Sample collection and DNA isolation/capture
291
There are two strategies of sampling zooplankton in biodiversity monitoring. One is
292
sampling bulk specimen samples (community DNA metabarcoding), by which zooplankton
293
can be quantitatively collected and enriched by filtering the same volume of water at each
294
sampling site using plankton nets (Yang et al. 2017; Xiong et al. 2017, 2019). The collected
295
samples can be directly preserved in anhydrous alcohol, or further filtered through 5-µm
296
microporous filter membranes, then stored at -20 ℃ for subsequent DNA extraction. The
297
other strategy is sampling environmental DNA samples (eDNA metabarcoding) (Hanfling et
298
al. 2016; Zhang et al. 2018). Environmental DNA (eDNA) is the suspended DNA traces from
299
skin cells, organelles, gametes or even extracellular DNA of all organisms living in aquatic
300
ecosystems (Deiner et al. 2017). Environmental DNA can be captured onto filter membranes
301
by filtering 1-2 L of water in field or laboratory and preserved in anhydrous alcohol. To date,
302
there is still a debate on the selection of filers and associated parameters including type, pore 14
303
size, pre-filtration and filter preservation strategy during the eDNA capture process. The most
304
commonly used filter for eDNA capture is 0.45-µm cellulose nitrate membrane, followed by
305
0.75/1.2-µm glass microfiber filers or polyethersulfone (Hanfling et al. 2016; Majaneva et al.
306
2018). Besides, in order to avoid false negatives caused by random sampling of rare taxa, it is
307
important to conduct repeated sampling for at least three times at each sampling site
308
(Thomsen et al. 2012).
309
It is important to keep in mind when we collect eDNA samples for biodiversity
310
monitoring that 1) the stability, dispersal and degradation rate of eDNA are substantially
311
influenced by various environmental factors such as temperature, pH, light intensity and
312
water chemistry (Goldberg et al. 2016; Seymour et al. 2018); 2) the temporal and spatial
313
distribution of eDNA highly vary in different ecosystems such as rivers and lakes, largely
314
owing to the transport of eDNA over large geographical scales in rivers and long retention
315
time in lakes (Turner et al. 2015; Deiner et al. 2016; Carraro et al. 2018); 3) eDNA from
316
different vertical depth of river and lakes has different biological significance, with that of
317
surface water indicating recent site biodiversity while sediments representing historical
318
biodiversity (Deiner et al. 2017). Thus, steps of eDNA capture need to be optimized in each
319
study, especially for highly polluted water with special hydrochemical features.
320
Currently, most studies relating to zooplankton biodiversity analysis used bulk specimen
321
samples (Xiong et al. 2017, 2019; Chain et al. 2015). However, when using eDNA to perform
322
biodiversity monitoring, sampling will be easier and less invasive. Djurhuus et al. (2018)
323
assessed the potential of eDNA metabarcoding to monitoring zooplankton biodiversity, by
324
comparing method of eDNA metabarcoding to bulk sample metabarcoding and 15
325
morphological methods, and they suggested that eDNA metabarcoding should be able to
326
provide complementary insights in biodiversity monitoring of zooplankton.
327
3.1.2 Selection of robust genetic markers and universal primers
328
“DNA metabarcode” is a fragment of DNA sequence being used for taxonomic
329
identification of multiple species existing in a mixed sample collected from communities or
330
environments (Deiner et al. 2017). The selection of DNA metabarcode will greatly influence
331
the detected species number and composition of taxonomic groups, as well as the accuracy of
332
species identification (Andújar et al. 2018a). Thus, the choice of appropriate genetic makers
333
is of vital importance for DNA metabarcoding analysis (Zhan & MacIsaac 2015). A desired
334
genetic marker for PCR primer design is expected to simultaneously possess both
335
evolutionarily conserved and hypervariable regions, of which conserved regions were used to
336
design universal primers for amplifying a wide range of species or taxonomic groups
337
(versatility), and hypervariable regions in the amplicons were used to accurately distinguish
338
the closely related species (high resolution) (Zhan & MacIsaac 2015).
339
Owing to the relatively high evolutionary rate and high taxonomic resolution capability,
340
the mitochondrial cytochrome c oxidase subunit I gene (COI) is considered as a competent
341
candidate genetic marker for metabarcoding survey for metazoa (Zhan & Maclsaac 2015;
342
Andújar et al. 2018b; Fernández et al. 2018). However, the amplification of COI in some
343
taxonomic groups such as crustaceans is still a difficult task, particularly in bulk samples (see
344
the review by Zhan & Maclsaac 2015 and references therein). To find a desired genetic
345
marker to metabarcode zooplankton biodiversity, Zhan et al. (2013, 2014) designed primer
346
pairs based on 18S and compared three commonly used genetic marker, including 18S, COI 16
347
and 16S by testing performance of different primer pairs, and they proposed that 18S was the
348
most efficient and powerful genetic marker for zooplankton biodiversity monitoring. Clarke
349
et al. (2017) claimed that COI (Leray et al. 2013) and 18S (Zhan et al. 2013) recovered
350
similar taxonomic coverage and beta-diversity, but different biomass and sequence reads
351
relationship and resolution, by comparing performance of these two best-known primer sets
352
in biodiversity study of zooplankton. Yet, Andújar et al. (2018b) argued that COI still should
353
be the most appropriate DNA metabarcode for bulk community analysis based on the
354
following reasons: 1) high resolution for taxonomic identification; 2) extensive coverage of
355
COI in reference sequence databases; 3) advantage of a protein-coding gene to identify
356
spurious sequences.
357
For eDNA metabarcoding, there are more challenges for selecting genetic markers and
358
primers, mainly due to low quality and quantity of eDNA and high proportion of
359
co-amplification of microbial DNA (Stat et al. 2017). Here, we urgently suggest that genetic
360
markers and associated universal primers should be well tested before application,
361
particularly on several parameters such as coverage of taxonomic groups and amplification
362
efficiency and bias. It is true that there are no perfect genetic markers and associated
363
universal primers for all taxonomic groups, but careful consideration of all influential
364
parameters can largely improve the power of DNA metabarcoding-based biodiversity survey.
365
While researchers struggle to select efficient genetic marker and primer sets in
366
metabarcoding, PCR-free methods are emerging recently, such as shotgun sequencing after
367
mitochondrial enrichment (Zhou et al. 2013). This method is independent on PCR, as
368
mitochondrial DNA is enriched during metaDNA extraction and sequenced by ultra-deep 17
369
high-throughput sequencing (HTS), and then COI sequences are retrieved by bioinformatic
370
analyses (Zhou et al. 2013). To avoid high cost of ultra-deep HTS and advance PCR-free
371
methods in routine environmental biomonitoring, a gene-enrichment technique was
372
recommended by Dowle et al. (2016). This method is derived from probe enrichment
373
techniques used in human genomic research (Blow 2009) and uses gene capture probes to
374
enrich target genes, followed by HTS to monitor biodiversity of aquatic communities (Dowle
375
et al. 2016). These two methods overcome PCR-derived biases to provide better estimate of
376
species abundance or biomass of target organisms, enhancing both the DNA sequence
377
information per taxon and the number of taxa.
378
3.1.3 Bioinformatics analysis
379
Enormous short sequence reads are generated by high throughput sequencing (HTS) in
380
DNA metabarcoding analysis, particularly after processing a large number of samples
381
collected from large geographical scales. Such big data sets pose vast challenges to
382
subsequent data processing procedures. A general data analysis process includes raw data
383
filtering, clustering of operational taxonomic units (OTUs), and taxonomy assignment.
384
Available evidence shows that sequencing errors greatly influence the biodiversity
385
estimates (Xiong et al. 2016a; Kunin et al. 2010). Thus, the removal of sequencing errors is
386
the first and one of the most important steps, which is challenged by discerning real rare taxa
387
from sequencing errors. Both rare species and artificial reads are usually recovered by low
388
number of sequences (e.g., low abundance OTUs), and the process of removal artificial reads
389
is prone to filter out a large proportion of rare species in samples (Zhan et al. 2014).
390
Depending on research aims, the clustering strategy for OTUs is another essential step for 18
391
assessing community biodiversity using DNA metabarcoding. These clustered molecular
392
OTUs were assigned to traditional taxonomic species in biodiversity monitoring, while
393
predefined similarity threshold (such as 97%) used in the clustering step may split one
394
traditional species into two or more OTUs or sequences for different taxa were clustered into
395
the same OTUs. To resolve this issue, newly developed methods, such as DADA2 (Callahan
396
et al. 2017) and UNOISE3 (Edgar 2016) were advanced algorithms of discerning and
397
removing sequencing errors and picked OTUs at similarity threshold of 100%, and LULU
398
was created for removing erroneous OTUs (Frøslev et al. 2017). Xiong & Zhan (2018) tested
399
different clustering strategies in studying zooplankton diversity, including newly developed
400
non-clustering (DADA2 and UNOISE 3) and clustering with different thresholds. Their
401
results showed that largely varied alpha biodiversity estimates were obtained by different
402
clustering strategies, but the ecological conclusions were consistently drawn by
403
non-clustering and clustering thresholds of 97-99%.
404
3.2 Indicator species detection based on metabarcoding
405
Owing to high sensitivity to environmental stressors, biological indicator species play
406
crucial roles in assessing pollution effects in aquatic ecosystems and provide early warning of
407
environmental changes (Casazza et al. 2002; Xiong et al. 2017, 2019). Identifying indicator
408
species, rather than traditional qualitative analysis of all species in biological communities,
409
provides a convenient and appealing approach in environmental monitoring, conservation and
410
management (Mächler et al. 2014). DNA barcoding has enhanced the sensitivity and
411
efficiency of species-level identification and highlights its wide use in indicator species
412
detection in biodiversity monitoring efforts (Hebert et al. 2003; Hebert & Gregory 2005). A
413
number of studies have documented the utility of DNA barcoding for species identification,
19
414
such as fish (Ward et al. 2005), copepods (Blanco-Bercial et al. 2014), crustaceans
415
(Radulovici et al. 2009), and molluscs (Layton et al. 2014). Recently, the application of DNA
416
barcoding method has been extended dramatically owing to the high-throughput sequencing
417
(HTS), enabling the identification of indicator species from mixed species samples or
418
communities (Cristescu 2014; Taberlet et al. 2012). Using HTS technologies to study the
419
relationship between geographical distributions of bacterial communities and water pollution,
420
Yang et al. (2019) revealed several effective bacteria as bio-indicators to assess river
421
pollution in Songhua River, suggesting the potential of micro-organisms as useful biological
422
indicators. Metabarcoding-based methods have been used to identify a variety of aquatic
423
indicator species for water-quality assessment and biodiversity monitoring, such as
424
arthropods (MäcHler et al. 2014; Thomsen et al. 2012; Xiong et al. 2017), gastropods
425
(Goldberg et al. 2013), amphibians (Goldberg et al. 2011; Thomsen et al. 2012), reptiles
426
(Piaggio et al. 2013), fishes (Jerde et al. 2011; Wilcox et al. 2013), and mammals (Foote et al.
427
2012; MäcHler et al. 2014). Thus, metabarcoding-based methods are robust tools to identify
428
indicative species from microscopic zooplankton.
429
3.3 Rare species detection based on metabarcoding and qPCR
430
Typically, aquatic communities are composed of a few dominant species and a high
431
diversity of low abundance species (i.e., ‘‘rare biosphere’’, Lynch & Neufeld 2015; Sogin et
432
al. 2006). The rare biosphere taxa may switch to new abundant members of a community in
433
response to environmental perturbation or change, and thus could provide a potential resource
434
of genetic and functional diversity to maintain ecosystem functioning. The rare biosphere in
435
running water ecosystems mainly include two types of species: native rare species and newly
436
introduced non-indigenous species (NIS). Owing to environmental pollution or demographic
437
stochasticity, native rare species may be at risk of extinction and become endangered (Wilson 20
438
et al. 2011). In addition, newly introduced NIS generally maintain low population density in
439
communities for a long period of time, even in cases when they eventually become dominant
440
to cause large-scale negative effects (Crooks & Soule 1999; Zhan et al. 2013). Therefore,
441
novel methods and effective measures should be taken to explore and monitor the rare
442
biosphere, in particular to identify native threatened rare species for conservation and
443
recently introduced NIS for biosecurity. However, there remain major technical challenges to
444
detect rare species, especially for microscopic organisms in freshwater ecosystems, owing to
445
their tiny body size, diverse species, complex community structure, and ambiguous
446
morphological traits (McDonald 2004; Zhan & MacIsaac 2015).
447
Metabarcoding has provided effective access to investigating rare species in complex
448
aquatic communities (Creer 2010; Xiong et al. 2016a). Zhan et al. (2013) quantitatively tested
449
the sensitivity of metabarcoding and claimed that metabarcoding enabled the detection of rare
450
species in complex zooplankton communities (biomass as low as 2.3 × 10-5%). Mounting
451
studies highlight the crucial role of metabarcoding in monitoring endangered species for
452
conservation (see the review by Cristescu & Hebert 2018 and references therein). Meanwhile,
453
metabarcoding helps early detection of NIS in aquatic ecosystems. For instance, Brown et al.
454
(2016) detected 24 non-indigenous species in Canadian ports, 11 of which were firstly
455
reported in the locations. Westfall et al. (2019) proposed a metabarcoding-based new
456
approach to molecular biosurveillance of invasive zooplankton species. Besides, for
457
accurately identifying protected species, DNA metabarcoding-based methods can provide
458
useful information about speciation time and phylogenetic diversity to perform quantitative
459
comparison rather than simply depending on the number of species within this area (Pečnikar 21
460
& Buzan 2014). In addition, commonly used genetic markers for HTS, such as COI, mt16S,
461
18S rDNA, would largely increase the comparability among different species, allowing us to
462
make the quantitative measurement of genetic diversity and evolutionary potential of rare
463
species and to confirm the relationships between endangered species and their surrounding
464
species. Thus, metabarcoding provides important insights in rare species detection, which
465
allows managers to make scientific decisions of species, populations and individuals for
466
protection.
467
Except screening rare species in mixed complex communities using metabarcoding,
468
species-specific PCR methods, including conventional PCR (cPCR) and real-time
469
quantitative PCR (qPCR), are DNA-based approaches to directly detect targeted endangered
470
or NIS species in low abundance (Xia et al. 2018). Conventional PCR has been applied to the
471
detection of a variety of aquatic NIS, including amphibians (Rana catesbeiana, Ficetola et al.
472
2008), crustaceans (Procambarus clarkii, Tréguier et al. 2014), mollusca (Limnoperna
473
fortune, Xia et al. 2018), and many other taxa. Real-time quantitative PCR (qPCR), which is
474
usually considered to be more sensitive than cPCR, provides a promising molecular tool for
475
detection and quantification of rare species (Arya et al. 2005; Wilcox et al. 2013). For
476
example, a quantitative real-time PCR (qPCR) amplification of 16s rDNA was performed to
477
quantitatively assess harmful algal bloom (HAB) risks in the Great Lakes (Doblin et al. 2007).
478
Recently, novel solutions, such as carbon nanotube platforms (Mahon et al. 2011), nucleic
479
acid sequence-based amplification (NASBA, Fykse et al. 2012), and droplet digital PCR
480
(ddPCR, Nathan et al. 2014), have extended the use of DNA-based methods in monitoring
481
targeted rare species. 22
482 483
3.4 Technical difficulties and possible solutions Although DNA-based methods exhibit evident advantages in assessing biodiversity,
484
there remain technical difficulties and challenges that need to be addressed for the
485
implementation of biodiversity monitoring programs. As mentioned above, PCR-free
486
approaches are able to overcome some limitations of PCR-based methods. However, these
487
methods have not been well tested in complex real-community samples (Zhou et al. 2013)
488
and showed low sensitivity to detect rare species (Srivathsan et al. 2014; Zhan and MacIsaac,
489
2015). In this study, we focus on the commonly used PCR-based methods (i.e., DNA
490
metabarcoding, Fig. 4).
491
3.4.1 False positives and negatives
492
The most notable problem confronting the process of DNA metabarcoding analyses is
493
the risk of error sources, including false positives (species detected but absent) and false
494
negatives (species undetected but present). A variety of issues can lead to false positives and
495
negatives (Darling & Mahon 2011; Zhan & MacIsaac 2015; Xiong et al. 2016a).
496
False positives, which is also known as Type II errors, can result from
497
cross-contamination from multiple sources, such as improper handling of samples, inadequate
498
specificity primers, and errors in data analysis (Xiong et al. 2016a; Cristescu et al. 2018; Li et
499
al. 2018). As a result of the increasing throughput of sequencing technologies, the pooling of
500
samples may lead to cross-contamination (Schmieder & Edwards 2011). Careful
501
manipulation, standard experimental protocols and contamination removal pipelines may
502
reduce cross-contamination risks and false positives. Moreover, negative and positive
503
controls should be added in the entire process (Jerde et al. 2011; Rees et al. 2014; Thomsen & 23
504
Willerslev 2015; Taberlet et al. 2018). In addition to cross-contamination, tag jumping among
505
pooled samples is another reason for false positives (Carlsen et al. 2012; Xiong et al. 2016a;
506
Zhan et al. 2016). There are some causes of tag jumping for HTS-based studies, such as
507
remaining unused tagged primers, using only one tagged primer, or sequencing long
508
amplicons (Xiong et al. 2016a). To minimize the probability of false positives caused by tag
509
jumping, paired tags should be added at both sides of amplicons (Carlsen et al. 2012).
510
Increasing the number of biological replicates, adding negative controls and applying strict
511
filtering pipelines would provide effective approaches to reducing the effect of tag jumping
512
(Kumar et al. 2011). In addition, other approaches that can contribute to avoidance of tag
513
jumping includes carefully purifying PCR products, immediately freezing PCR products, and
514
shortening their storage time (Kumar et al. 2011; Xiong et al. 2016).
515
The sources of false negatives (Type I errors) are mainly derived from random sampling
516
and biased PCR amplification (Xiong et al. 2016; Zhan et al. 2016a). When investigating
517
community structure with DNA metabarcoding, random sampling processes can result in low
518
reproducibility among replicate samples, especially for rare species, thus leading to false
519
negatives (Clarke et al. 2014; Engelbrektson et al. 2010; Zhan et al. 2014). Several technical
520
approaches should be performed to decrease false negatives by using more biological and
521
technical replicates, deeper sequencing, primers blocking against dominant taxa and
522
optimized species occupancy models (MacKenzie et al. 2002; Xiong et al. 2016a; Zhan et al.
523
2016). Another common and severe problem influencing taxonomic resolution power in DNA
524
metabarcoding studies is PCR amplification biases among species (Xiong et al. 2016). This
525
error source can be introduced by many factors, such as universality of the primers, annealing 24
526
temperature, the number of replication cycles, and relative abundance of different species in a
527
community (Bellemain et al. 2010; Engelbrektson et al. 2010). PCR amplification bias is
528
strongly influenced by the annealing temperature and the number of replication cycles during
529
library preparation. Low annealing temperature and cycle number can reduce the bias (Ishii &
530
Fukui 2001). Additional efforts include optimizing conditions of PCR amplification by
531
increasing template concentrations and adopting wise primers (Lim et al. 2010; Shokralla et
532
al. 2012). More importantly, the utilization of multiple versatile primers or two-step nested
533
PCR would reduce amplification biases and enhance the opportunity of rare species detection
534
(Sun et al. 2015; Xiong et al. 2016a; Zhang et al. 2018).
535
3.4.2 Reference database
536
Retrieving the taxonomic composition from sequences data is one of the primary aims
537
when we monitor biodiversity using DNA-based methods. This step is completely dependent
538
on comparing sequences against a metabarcode reference dataset containing taxonomy
539
information (Taberlet et al. 2018). The high-quality and complete reference databases for
540
taxonomic assignment directly determine the reliability of DNA metabarcoding. Even though
541
a large number of DNA sequences has been submitted to public databases, unbalanced
542
representation of different taxonomic groups in these public sequence databases is a major
543
issue (Briski et al. 2011). Available sequences for poorly studied species in public databases
544
remain low when compared to commercially important or better studied species (Briski et al.
545
2011). Thus, broad collaborations and sharing among different research groups who
546
particularly have their own taxa of interest, should be made to develop and improve
547
community-level reference libraries (Valentini et al. 2016). Additionally, most sequence 25
548
information was obtained from traditional molecular makers, such as COI and ribosomal
549
RNA genes in these databases, which is not enough to identify complex communities and
550
closely related species. Thus, more sequence information with diverse molecular makers
551
should collect in order to build comprehensive reference libraries.
552
From a taxonomic point view, reference datasets (Table 1) are poorly connected, though
553
part of them, such as EMBL, GenBank and DDBJ, have been united into the International
554
Nucleotides Sequence Database Collaboration (INSDC) and synchronized daily (Taberlet et
555
al. 2018). Lacking coherence among datasets largely limits meta-analyses on
556
metabarcoding-based studies. Thus, collaborative efforts remain necessary in the future for
557
biodiversity monitoring at the global scale.
558
4 Future perspectives
559
In summary, metabarcoding is revolutionizing the investigation of freshwater
560
biodiversity and presents a powerful tool of detection of “hidden diversity” under water
561
surface (Lindeque et al. 2013). We propose that DNA-based metabarcoding should be
562
embraced by researchers and managers, as its inherent practicable and applicable features can
563
largely solve technical issues in biodiversity assessment in polluted freshwater ecosystems.
564
Indeed, DNA-based metabarcoding has been approved by several international organizations,
565
such as the European Water Framework Directive of European Union. Yet, many technical
566
issues still remain in the application of metabarcoding-based biomonitoring in freshwater
567
ecosystems. We should firstly continue the development of taxonomically comprehensive
568
reference databases based on multiple genetic markers to support taxonomic retrieval of
569
metabarcoding analyses. Additionally, we should screen more variables gene regions, which 26
570
can ensure correct identification, discrimination and detection of closely related or cryptic
571
species. Alternatively, as HTS becomes more accessible and less expensive, the use of
572
short-gun sequencing strategy to sequence meta-DNA extracted from bulk samples would
573
increase the resolution of taxonomical identification. In addition, shot-gun sequencing is a
574
PCR-free method, which is beneficial to quantification of taxon abundance. Spiking the
575
standard DNA into different samples is a good method to make advance of quantification in
576
metabarcoding analyses. Finally, there is no doubt that traditional morphology-based methods
577
cannot be discarded, although many technical issues still exist among morphology-based
578
methods. Both traditional morphology-based and DNA-based methods must be
579
cross-referenced to ensure accurate and rapid identification of zooplankton species, and to
580
promote the dissection of causes and consequences of biodiversity loss in polluted freshwater
581
ecosystems.
582
Author Contributions
583
A.Z., B.S. and W.X. conceived the study. All authors wrote and revised the manuscript.
584
Acknowledgments
585
This work was supported by the National Natural Science Foundation of China [grant
586
numbers 31800307, 31572228], National Key R&D Program of China [grant number
587
2016YFC0500406], and Chinese Academy of Science [grant number ZDRW-ZS-2016-5-6].
588
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1040
Table 1 The most recent and important reference databases for zooplankton Database
Organisms
name
covered
EMBL-E
Bacteria/Archaea,
16S/23S rRNA
BI
Eukaryota
16S/18S/ COI
GenBank
Bacteria/Archaea,
16S/23S rRNA
Eukaryota
16S/18S/ COI
Bacteria/Archaea,
16S/23S rRNA
Eukaryota
16S/18S/ COI
Bacteria/Archaea,
16S/23S
Eukaryota
18S/28S
Animals,
COI
Plants,
rbcl, matk
Fungi
ITS
Protists
18S
DDBJ
SILVA
BOLD
PR2
Genetic markers
Establishe
Website
Reference
1980
https://www.ebi.ac.uk/ena
--
1982
https://www.ncbi.nlm.nih.g
Leray et al.
ov/genbank/
(2019)
https://www.ddbj.nig.ac.jp/i
Mashima
ndex-e.html
al. (2016)
https://www.arb-silva.de/
Quast et al.
d year
1987
2007
et
(2012) 2007
http://www.boldsystems.org
Ratnasingha
/
m & Hebert (2007)
2012
ssu-rrna.org/pr2
Guillou et al. (2013)
1041
49
1042
Figure captions:
1043
Figure 1 Photos of zooplankton observed by traditional morphological methods referred
1044
from Rotifer World Catalog (Jersabek & Leitner 2013). A: Brachionus angularis Gosse, 1851;
1045
B: Brachionus diversicornis (Daday, 1883); C: Keratella cochlearis (Gosse, 1851); D:
1046
Brachionus forficula Wierzejaki, 1891; E: Brachionus quadridentatus Hermann, 1783; F:
1047
Keratella cochlearis (Gosse, 1851); G: Trichotria tetractis (Ehrenberg, 1830).
1048
Figure 2 Morphology-based methods for zooplankton biodiversity monitoring.
1049
Figure 3 Workflow and key technical points of metabarcoding in biodiversity monitoring of
1050
zooplankton.
1051
Figure 4 Technical difficulties and possible solutions in flowchart of biodiversity monitoring
1052
of zooplankton.
50
1053
Figure 1
1054 1055
51
1056
Figure 2
1057 1058
52
1059
Figure 3
1060 1061
53
1062
Figure 4
1063
54
Highlights 1.
Freshwater ecosystems and associated biodiversity have been highly degraded.
2.
Biodiversity monitoring is crucial for diagnosing degradation degrees
3.
Here we review available methods for monitoring zooplankton biodiversity.
4.
We propose possible solutions for existing technical issues.