Next Article in Journal
Environmental Compatibility and Genome Flexibility of Klebsiella oxytoca Isolated from Eight Species of Aquatic Animals
Previous Article in Journal
Nationwide Tracing of Two Top Freshwater Fish Invaders in Greece Using Environmental DNA Sampling
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Diversity
Volume 16
Issue 1
10.3390/d16010029
diversity-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Risk Screening of Invasive Aquatic Species and a Survey of Fish Diversity Using Environmental DNA Metabarcoding Analysis in Shanghai

by
Ruohan Yu
1,2,
Qianqian Wu
3,*,
Fan Li
2,
Aibin Zhan
4,5,
Jinxin Zhou
6 and
Shan Li
1,2,*
1
College of Marine Sciences, Shanghai Ocean University, Shanghai 201306, China
2
Shanghai Natural History Museum, Branch of Shanghai Science and Technology Museum, Shanghai 200041, China
3
Graduate School of Human Development and Environment, Kobe University, 3-11, Kobe 657-8501, Japan
4
Research Center for Eco-Environmental Sciences, Chinese Academy of Science, Beijing 100085, China
5
University of Chinese Academy of Sciences, Beijing 100049, China
6
Institute of Industrial Science, The University of Tokyo, 5-1-5, Kashiwa 277-8574, Japan
*
Authors to whom correspondence should be addressed.
Diversity 2024, 16(1), 29; https://doi.org/10.3390/d16010029
Submission received: 5 December 2023 / Revised: 26 December 2023 / Accepted: 27 December 2023 / Published: 2 January 2024
Browse Figures
Versions Notes

Abstract

:
As the largest coastal city in China, Shanghai’s rapid development in transportation, tourism, trade, and commerce has facilitated the spread and invasion of non-native aquatic organisms. Aquatic organisms are highly elusive, and once established, eradicating them becomes a challenging task. Currently, our understanding of the invasion risk posed by non-native aquatic species in Shanghai is limited. Therefore, it is imperative to investigate the pathways of introduction, distribution, and dispersion and the invasion risk and impacts of non-native aquatic organisms in Shanghai. This study investigated aquatic organisms in Shanghai’s primary water bodies, including Huangpu River, Suzhou River, and Dianshan Lake. The risk assessment was conducted using the Aquatic Species Invasiveness Screening Kit (AS-ISK), and field monitoring was performed with environmental DNA (eDNA) technology. Results of the risk assessment indicate that among the 21 evaluated species, 9 fall into the medium-to-high-risk category with scores ≥26, while 12 are classified as low-risk with scores <26. The top four species with the highest invasion risk are Gambusia affinis, Pomacea canaliculata, Lepomis macrochirus, and Coptodon zillii. This study identified 54 fish species belonging to seven orders, 16 families, and 42 genera at 16 sampling sites in Shanghai, among which Channa maculata, Micropterus salmoides, and Misgurnus bipartitus are non-native. The results suggest that Shanghai faces a high invasion risk of aquatic species, necessitating enhanced scientific prevention and control measures. Early monitoring is essential for species with medium-to-high invasion risk, and a further evaluation and analysis of the risks associated with introduced fish species already present in Shanghai are recommended for aquaculture practices.

Graphical Abstract

1. Introduction

Biological invasions have led to a series of negative impacts on ecological security, native species, the social economy, and more [1,2,3,4,5,6]. Currently, it is listed as one of the five major global environmental issues of the 21st century [7]. The Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services (IPBES), in its 2019 report, highlighted that with the increase in global trade volume, population, and climate change, the number of non-native species has increased by approximately 40% since 1980, with about one-fifth of the world facing the risk of biological invasion. The proportion of newly introduced invasive species has reached historic highs and shows no signs of slowing down [8].
Over 5000 species are non-native in China, among which more than 660 have successfully invaded, representing a 35% increase compared with a decade ago [9,10,11]. In the list of 100 of the World’s Worst Invasive Alien Species announced by the International Union for Conservation of Nature (IUCN), over 50 species have already invaded China, with approximately 20% of them being aquatic organisms. Most non-native aquatic species are introduced into China by human activities, and they establish natural populations due to China’s unique climate, geography, and complex habitat types, subsequently impacting local ecosystems and native species [12,13]. For example, the introduction of Gambusia affinis led to a significant decline in the population of native Oryzias sinensis [14]. The introduction of Trachemys scripta elegans in Henan province resulted in the disruption of aquatic ecosystems and potentially the local extinction of native turtles [15]. Clearing the introduced Atractosteus spatula in Ruzhou City, Henan Province, took a month and caused substantial economic losses. In light of this, an urgent need exists for the risk assessment and field monitoring of non-native aquatic species.
As the largest coastal city in China, Shanghai’s rapid development in transportation, tourism, trade, and commerce has provided convenient conditions for the spread and invasion of non-native aquatic species, accelerating the ecological process of their invasion [16,17]. Zhang et al. [17] compiled a list of non-native invasive species in Shanghai in 2012, indicating a total of 212 non-native species, of which nine (4.25%) are aquatic animals. These include Procambarus clarkii, Pomacea canaliculata, Rana catesbeiana, G. affinis, Micropterus salmoides, Colossoma brachypomus, Oreochromis aureus, Ictalurus punctatus, and Oncorhynchus mykiss. Among these, P. canaliculata can produce up to 300,000 eggs in a year and has a strong reproductive capacity, with wide distribution across ten districts in Shanghai [18,19]. Due to its preference for rice crops and aquatic vegetation, it poses varying degrees of harm to invaded waterways and threatens fish biodiversity [20,21]. Aquatic organisms have strong concealment and once successfully invaded, they are challenging to eradicate. Therefore, understanding the pathways, distribution status, dispersion routes, invasion risk, and impact of non-native aquatic species in Shanghai is of utmost importance.
With the acceleration of the invasion of non-native species and the progress of industrialization and urbanization, the native fish diversity in Shanghai faces numerous threats and challenges. For example, a survey in 2019 by Yu et al. [22] found that the number of fish species in the Suzhou River has decreased by 17 species compared with the 1960s, with a total of only 45 species [23]. To maintain the health of aquatic ecosystems and protect fish diversity, the Shanghai Municipal Agricultural and Rural Affairs Commission issued a notice on implementing a five-year fishing ban in the Yangtze River Estuary and other inland waters, which came into effect on 10 February 2021. Additionally, Shanghai has allocated significant funds for continuous stocking activities to protect fish diversity. However, the current state of fish diversity in Shanghai and the impact of related policies on its diversity are not yet fully understood. Therefore, it is necessary to conduct a survey of fish diversity in the three main rivers of Shanghai and study the current situation and trends.
This study utilizes the Aquatic Species Invasiveness Screening Kit (AS-ISK), a widely applied pre-assessment tool for invasive aquatic species [24]. It is suitable for almost any climate/marine ecological zone and for any aquatic species (excluding parasites and pathogens) [25] and has been used in more than 26 risk assessment (RA) regions, including China [26,27,28], Turkey [29,30,31], the United Kingdom [32], India [33], Russia [34], and Italy [35,36,37], to effectively assess the invasion risk of non-native aquatic species.
The emergence and application of environmental DNA (eDNA) metabarcoding analysis have brought unprecedented innovation to the monitoring of aquatic organisms. Compared with traditional survey methods (such as direct observation, baited traps, and trawl fishing [38]), this technology offers higher detection capability, cost-effectiveness, environmental friendliness, and non-invasiveness. It overcomes many limitations of traditional survey methods [39,40] and has been widely used in species monitoring. For example, Liu et al. [41] used eDNA metabarcoding analysis to investigate fish diversity in Beijing and detected a total of 52 freshwater fish species, including 13 non-native species. Jeunen et al. [42] monitored biodiversity in Belarusian waters using eDNA metabarcoding analysis and detected nine non-native fish species. In the early stages of invasive aquatic species, when species density and abundance are low, monitoring these low-density target organisms in complex communities is critical for building an early detection and warning system and preventing the further spread of invasive species [41]. Due to its high sensitivity, eDNA metabarcoding analysis can detect the presence of a species in water bodies at low densities [43], making it highly advantageous in monitoring non-native aquatic species.
This study encompasses both modeling assessment and field surveys. It utilizes AS-ISK for risk assessment of non-native aquatic species in Shanghai and eDNA metabarcoding analysis for field monitoring to gain a comprehensive understanding of fish diversity, the composition of non-native species, and their invasion risk. This study provides recommendations for the management of non-native aquatic species in Shanghai and serves as a reference for control measures and biodiversity protection in nearby river basins.

2. Materials and Methods

2.1. Risk Assessment Modeling of Non-Native Aquatic Species

In this study, 21 non-native aquatic species were selected for risk assessment. The selection criteria were based on four categories: (1) non-native aquatic species that have already been confirmed to have invaded Shanghai (three species); (2) non-native aquatic species found in Shanghai but have not yet established (three species); (3) non-native aquatic species that have invaded surrounding water bodies in Shanghai (four species); and (4) non-native aquatic species introduced to Shanghai due to trade activities, aquaculture, and the aquarium industry (eleven species). The non-native aquatic species that were assessed included intentionally or unintentionally introduced species. Once the selection was completed, the Aquatic Species Invasiveness Screening Kit (AS-ISK, available at www.cefas.co.uk/nns/Tools/, accessed on 21 September 2021.) was used to assess the invasion risk of potentially invasive species in the RA region.
AS-ISK consists of 49 factors about life history characteristics, biology, ecology, biogeography, and introduction history, along with an additional 6 factors regarding climate change, to predict the likelihood of species invasion under current and future climate conditions [26,29,30,44]. To effectively screen species in the RA region, assessors must provide responses to each question in the toolkit, as well as the confidence level and reasoning for each response based on the relevant literature or field survey results. Based on the assessor’s responses, each species receives both a Basic Risk Assessment (BRA) score (score range: −20 to 68) and an Integrated Assessment under Climate Change (BRA + CCA) score (score range: −32 to 80).
The accuracy of the assessment results was evaluated using the area under curve (AUC) of the receiver operating characteristic (ROC) curve analysis. The threshold score for the RA region was determined using Youden’s index. When a species’ invasion score is greater than or equal to the threshold, it is classified as a species with medium to high invasion risk; otherwise, it is classified as a species with low invasion risk. Confidence factors were calculated based on the confidence level for each response, with the formula as follows:
CF =   ( C Q i ) / ( 4 × 55 ) ( i = 1,2 55 )
where CF represents the confidence factor and CQi is the confidence level for each assessment question (1 = low, 2 = moderate, 3 = high, 4 = very high), with values ranging from 0.25 (low confidence for all questions) to 1 (high confidence for all questions).

2.2. Field Monitoring Using eDNA Metabarcoding Analysis

2.2.1. Water Sample Collection

This survey was conducted from 16 September to 20 September 2022, based on the geographical features of the main river basins in Shanghai and the composition of non-native aquatic species. The survey area was located between 120°55′12″ E–121°7′48″ E and 30°56′24″ N–31°8′24″ N, with a total of 16 sampling points. Among them, seven sites were set along the Huangpu River, six sites in Dianshan Lake, and three sites along the Suzhou River (Figure 1). At each sampling point, we collected one liter of surface water. To prevent DNA degradation, 1 mL of benzalkonium chloride (BAC) solution (concentration 10%) [45] was added to the water samples at each point. The samples were then stored at low temperatures until filtration.

2.2.2. Water Sample Processing and eDNA Extraction

Glass fiber filters with a pore size of 0.7 μm (Shanghai Xingya, China) were used for vacuum filtration of the collected samples. Filters were stored in 2 mL cryotubes (Sangon Biotech, Shanghai, China) and kept in a laboratory at −20 °C until eDNA extraction. All filtration equipment was soaked in a 10% sodium hypochlorite solution for five minutes before and after use to remove residual DNA, followed by thorough rinsing with tap water and a final rinse with commercially available distilled water (Hangzhou wahaha group co., LTD, Hangzhou, China). Disposable gloves were used for each sample filtration. Pre-processing of eDNA was carried out according to Xia et al. [46]. After pre-processing, total eDNA was extracted from the filters using the DNeasy Blood and Tissue kit (Qiagen, Dusseldorf, Germany). After extraction, the total eDNA was eluted in 50 μL of double-distilled water (ddH2O) and stored at −20 °C.

2.2.3. Amplicon Library Preparation and Sequencing Run

The amplicon libraries for fish eDNA metabarcoding were prepared using MiFish-U primers [47]. First-round PCR reaction, purification products, and sample dilutions were completed according to Wu et al. [48]. The second-round PCR was performed to add the adapter and 8 bp indices to both ends of the amplicons using the diluted samples [49]. The products of the 2nd PCR were pooled into one tube to include all samples. Using the E-Gel Precast Agarose Electrophoresis System (Thermo Fisher Scientific, Waltham, MA, USA) and E-Gel SizeSelect 2% (Thermo Fisher Scientific, Waltham, MA, USA), the target size amplicons were extracted. An Agilent 2100 Bioanalyzer (Agilent Technologies, Santa Clara, CA, USA) was subsequently used to verify whether only DNA of the target length (approximately 370 bp) was obtained. The DNA library concentration was measured with a Qubit fluorometer 3.0 (Thermo Fisher Scientific, Waltham, MA, USA) using Qubit dsDNA HS assay kit. The concentration of the DNA library was adjusted to 4 nM. Finally, the library was sequenced using an Illumina HiSeq 4500 with 150 bp paired-end (Illumina, San Diego, CA, USA).

2.2.4. Data Analysis

The raw reads obtained from HiSeq sequencing were pre-processed and analyzed using USEARCH v10.0.240 [50], according to the method of Wu et al. [48]. Based on the distribution information of aquatic organisms in Shanghai, the sequences of fish and other species not distributed in Shanghai were manually calibrated or deleted. All analyses were performed using R ver. 4.1.2, and the results were visualized. In all analyses, the reads were converted to either presence or absence [51].

3. Results

3.1. Risk Assessment of Non-Native Fish Species

The assessment results based on AS-ISK are presented in Table 1. The AUC values of the BRA and BRA + CCA curves obtained from ROC curve analysis were both greater than 0.5 (Figure 2), indicating that AS-ISK can reasonably distinguish between invasive and non-invasive species. The maximum Youden’s index values for the RA region corresponded to threshold scores of 26 (BRA) and 28.75 (BRA + CCA). This means that species with BRA scores below 26 were classified as low-invasion risk, while those with scores equal to or greater than 26 were classified as medium-to-high-invasion risk. Similarly, species with BRA + CCA scores below 28.75 were classified as low-invasion risk, while those with scores equal to or greater than 28.75 were classified as medium-to-high-invasion risk.
Under current climate conditions, nine species (score range [26, 32]) were classified as medium-to-high-invasion risk, while twelve species (score range [15, 26)) were classified as low-invasion risk. The top four species with the highest scores were G. affinis, P. canaliculata, Lepomis macrochirus, and Coptodon zillii. The other five species with medium-to-high-invasion risk included L. cyanellus, Procambarus clarkii, R. catesbeiana, Hypostomus plecostomus, and M. salmoides. The three species with the lowest scores were O. mykiss, Tinca tinca, and Labeo rohita.
Under climate change conditions, twelve species (range [28.75, 41]) were classified as medium-to-high-invasion risk, while nine species (range [10.5, 28.75)) were classified as low-invasion risk. The top three species with the highest invasion risk were Pomacea canaliculata, C. zillii, and M. salmoides. Furthermore, the invasion risk increased for fourteen species, decreased for three species, and remained unchanged for four species, with M. salmoides, C. zillii, and Piaractus brachypomus exhibiting the most significant score increase from BRA to BRA + CCA.

3.2. eDNA Sampling Results

3.2.1. Fish Species Diversity in Shanghai

In this survey, a total of 1,210,756 different Amplicon Sequence Variants (ASVs) were obtained from 16 sequencing samples. These ASVs were subjected to database matching and annotation and then merged for analysis. The survey revealed a total of 54 fish species in Shanghai, belonging to seven orders, 16 families, and 42 genera (Appendix A). The Cypriniformes order had the highest number of species at 33, accounting for 61.11% of the total fish species in Shanghai. Perciformes was the second most abundant order with 14 species. Siluriformes had three species, while Clupeiformes, Anguilliformes, Cyprinodontiformes, and Sciaenidae each had one species. In terms of families, Cyprinidae had the most species, with 29 in total, followed by Gobiidae and Cyprinodontidae, each having 4 species (Figure 3).
With regard to species distribution, the survey detected 51 fish species in the Huangpu River, 36 in the Suzhou River, and 43 in Dianshan Lake (Figure 4). Fish composition in the Huangpu River, the Suzhou River, and Dianshan Lake was very similar, and 33 fish species were detected in all three rivers, while 2 species were only detected in Dianshan Lake, which were Sarcocheilichthys sinensis and Siniperca chuatsi. One species, Macropodus ocellatus, was exclusively found in the Suzhou River, and eight species, including Megalobrama terminalis, Mugilogobius_myxodermus, Channa maculata, Lateolabrax maculatus, Eleotris oxycephala, Anguilla japonica, Tachysurus nitidus, and Mugil cephalus, were only detected in the Huangpu River (Figure 4).

3.2.2. Native and Non-Native Fish Species

The eDNA survey revealed that there was a total of 54 fish species in Shanghai. Among these, 51 species (94.44%) were native to the region, while 3 species (5.56%) were non-native. The presence of non-native fish species at different survey sites is depicted in Table 2. The dominant species in Shanghai, including Abbottina rivularis, Acheilognathus chankaensis, A. barbatulus, C. argus, Odontobutis potamophila, Pseudorasbora parva, Rhodeus ocellatus, Zacco acanthogenys, and Misgurnus anguillicaudatus, were detected in all water samples collected from the survey sites. The non-native fish species included Micropterus salmoides, C. maculata, and Misgurnus bipartitus, with C. maculata being restricted to the Huangpu River, while M. bipartitus and Micropterus salmoides were found in the Huangpu River, the Suzhou River, and Dianshan Lake, which are the three major river systems in the region.

3.2.3. Comparison with Historical Data

To compare the eDNA survey results with historical data obtained using traditional sampling methods [22,23,52,53,54,55], the number of fish species in Shanghai at different time periods was compiled. The survey results from the early 21st century, the 2010s, and the present study revealed 56, 68, and 54 fish species, respectively. However, it is important to note that there were cases of taxonomic changes and synonymous names for certain fish species. For example, Culter dabryi, Chanodichthys dabryi, and Erythroculter dabryi were different names for the same species. Similar cases of synonymous names were observed for C. mongolicus and Culter mongolicus, C. alburnus and Cultrichthys erythropterus, Micropercops swinhonis and H. swinhonis, and T. nitidus and Pelteobagrus nitidus. Furthermore, the classification of Chanodichthys erythropterus and Culter alburnus has changed in recent years, with C. alburnus being reclassified as Chanodichthys erythropterus and C. erythropterus as Culter alburnus. As a result, the data were recompiled for a comprehensive comparison, as shown in Appendix B.
From Appendix B, it can be observed that the early 21st century, the 2010s, and the present study reported 53, 66, and 54 fish species in Shanghai, respectively. The overall composition of fish species in these different time periods is depicted in Figure 5.
In comparison with the historical data, the present study detected 38 fish species that were previously recorded and discovered 16 fish species that were not identified using traditional methods. Additionally, 42 fish species had historical records but were not identified with the eDNA analysis used in this study (Figure 6).

4. Discussion

4.1. Invasion Risk Factors of Non-Native Fish Species in Shanghai

4.1.1. Introduction and Geographic Factors

The rapid development of the economy, trade, and shipping has led to an increasing frequency of transnational or trans-basin introductions of organisms [17]. For instance, Shanghai’s annual consumption of aquatic products is approximately 850,000 tons, with 80% of the products consumed coming from outside Shanghai. The introduction of fish species across regions could contribute to the invasion risk of non-native fish species in Shanghai [3]. The largemouth black bass, due to its rapid growth, disease resistance, short breeding cycle, high yield, and delicious taste, has become one of the most extensively introduced non-native freshwater fish in China over the past five years [56,57]. As of 2021, largemouth black bass had been introduced for cultivation in 29 provinces and cities, including Guangdong, Jiangsu, Zhejiang, Shanghai, and Shandong. The continuous expansion of aquaculture areas and operational scales increases the likelihood of largemouth black bass entering risk assessment areas [58,59,60]. The results of this eDNA survey indicate that largemouth black bass are found at 11 sites (Table 2). In addition, in the fall of 2023, we observed the presence of live largemouth black bass at SH4, leading to speculation that the species may have undergone dispersal in Shanghai.
Furthermore, Shanghai shares a similar climate type with the native habitat of largemouth black bass, which is a crucial factor of high invasion risk. The native habitat of largemouth black bass is located in the eastern United States, where the climate is mostly subtropical and humid (Cfa), similar to the climate type in Shanghai [61]. Therefore, after being introduced to Shanghai, largemouth black bass can adapt to local climatic conditions and maintain populations in the region. Similarly, the high risk of invasion of the mosquitofish is partly attributed to its introduction to a region with a climate type similar to its native habitat.

4.1.2. Life History Traits

The invasion process of non-native fish species consists of five stages: introduction, establishment, latency, spread, and outbreak [62]. Successfully invading freshwater fish often possess life history traits favorable for invasion, such as high reproductive capacity, broad diet, rapid growth, and physiological tolerance [63,64,65,66]. Of the evaluated fish species, the mosquitofish demonstrate strong ecological adaptability and reproductive capacity [67]. It outcompetes other fish species for living space, preys on their food, and directly suppresses these fish species. The Shanghai native Oryzias sinensis has been particularly affected by the mosquitofish. Their ecological niches are nearly identical, but the mosquitofish exhibits higher reproductive capacity and aggression; therefore, it may crowd out O. sinensis. In addition to the mosquitofish, green sunfish have been found to prey on the eggs and fry of other fish species, posing a significant threat to the survival and reproduction of other fish species [68]. The suckermouth catfish (H. plecostomus) exhibits high environmental tolerance and can even survive temporarily without water [69]. The assessment results indicate that these species are categorized as having a medium-to-high invasion risk. Therefore, high reproductive capacity and environmental tolerance are considered to be contributing factors to the accelerated invasion of fish species.

4.1.3. Climate Change

Climate change may interact with other environmental factors, thereby influencing the distribution and reproduction of non-native fish species [60,70,71]. It is anticipated that by the mid-21st century, the national average temperature will exhibit a consistent warming trend, with a temperature increase ranging from 1.2 to 2.8 °C. The annual average precipitation is also expected to increase, with a variation range of −0.1 to 1.1 mm/d in the summer and −0.2 to 0.2 mm/d in the winter. In the Yangtze River’s middle and lower reaches, there will be a consistent increase in annual average precipitation between the winter and summer [72]. The temperature rise is likely to enhance the invasion risk of warm-water species such as green sunfish (Lepomis cyanellus), North African catfish (Clarias gariepinus), redbelly tilapia (Coptodon zillii), and largemouth black bass (Micropterus salmoides). On the other hand, the invasion risk of cold-water species like rainbow trout (Oncorhynchus mykiss) is expected to decrease. Increased precipitation may trigger flood disasters, providing conditions for the spread of some introduced fish species. For instance, during flood events, I. punctatus and H. plecostomus are known to escape [69,72,73]. Therefore, under future climate change conditions, the invasion risk of these two fish species in Shanghai may increase.

4.2. Discrepancies and Factors in Fish Diversity Survey Results between Traditional Sampling Methods and eDNA Metabarcoding Analysis

From Appendix B, it can be seen that this eDNA survey found some fish species that cannot be identified as known species. This could be one of the reasons for the deviation between the eDNA survey results and historical data. These fish species belong to the genera Carassius, Hemibarbus, Cobitis, Micropercops, and Coilia. After analysis and investigation by fishery experts, it is inferred that these fish species are likely to be Carassius auratus, H. maculatus, Cobitis taenia, M. sp., and Coilia nasus. This is because each genus mentioned above is likely to correspond to only one species in the water bodies in and around Shanghai. For these species, we can redesign primers specifically for these groups in the future, increasing the amplicon length to enhance primer specificity and identify specific species. Regarding the other fish species with differences between this study and historical traditional survey results, we will discuss them in two parts.

4.2.1. Fish Species Detected with eDNA Metabarcoding Analysis but Not with Traditional Methods

There are three main reasons why some fish species can be detected with eDNA metabarcoding analysis but not with traditional methods:
(1)
Environmental impact
In terms of the environment, we found that changes in water quality may be a key factor affecting fish diversity. According to the “Statistical Data on the Protection of Water Environment in Shanghai” released by the Shanghai Ecological and Environmental Bureau, around 2008, the discharge of industrial wastewater in Shanghai reached 419 million tons. This pollution could lead to the continuous depletion of dissolved oxygen in the water, further harming the ecosystem and causing a reduction in fish diversity. For example, some perciforms have a high requirement for dissolved oxygen [74,75]. In the early 21st century, the absence of perciform fish species may have been attributed to low dissolved oxygen conditions in the water. To address this issue, Shanghai has adjusted its industrial structure and layout, closing a large number of enterprises that discharged pollutants along the river. Substantial funds have been continuously invested in sewage treatment projects, steadily improving the water quality in Shanghai. By 2021, the discharge of industrial wastewater in Shanghai had decreased to 321 million tons. Therefore, in this survey, we observed the presence of Lateolabrax maculatus and S. chuatsi, species belonging to Perciformes. This may be a result of improved water quality.
(2)
Policy impact
To protect fish diversity in water bodies, Shanghai has periodically conducted artificial breeding and releases [76]. According to the “2020–2022 Catalog of Aquatic Resources Artificial Breeding and Release in Natural Water Bodies in Shanghai” released by the Shanghai Agriculture and Rural Affairs Committee in 2019, species such as S. chuatsi, Sarcocheilichthys sinensis, and L. maculatus were listed as target species for artificial breeding and release. Looking at the comparative results in Appendix B, it can be seen that these three fish species were not found in the early 21st century but were discovered in this study. These data indirectly demonstrate the positive effect of Shanghai’s measures for artificial breeding and release on fish diversity.
(3)
Methodology impact
Historical surveys often utilized traditional sampling methods, using tools such as gill nets, trawl nets, and traps. While these methods directly observe the targeted species, their sensitivity is relatively low [77]. In contrast, the eDNA metabarcoding analysis used in this survey has a relatively higher sensitivity [78,79] and is capable of detecting target organisms at low densities within complex biological communities [43]. However, the high sensitivity of eDNA metabarcoding analysis also makes it susceptible to the influence of the surrounding environment. For example, fish species such as Cobitis sinensis, Rhynchocypris oxycephalus, Opsariichthys uncirostris, and Microphysogobio microstomus, which were detected in this survey, are only distributed upstream of the Huangpu River in Huzhou, making it unlikely for them to exist in the wild waters of Shanghai. Their DNA might have been introduced into the monitoring area with the discharge of wastewater from aquaculture facilities or carried by water flow. Additionally, artificial hybridized individuals of the introduced species Channa maculata and the local Shanghai species C. argus are common in aquaculture [80]. Therefore, the DNA detected in this study is highly likely to be from hybridized C. and not from pure C. argus. The differences in sensitivity and accuracy between the two methods contribute to discrepancies in the monitoring results.

4.2.2. Fish Species Detected with Traditional Methods but Not with eDNA Metabarcoding Analysis

There are two main reasons why some fish species can be detected with traditional methods but not with eDNA metabarcoding analysis:
(1)
Manual identification in traditional sampling methods
One limitation of traditional sampling methods is the potential for subjective biases during the classification process by monitoring personnel, which may affect the accuracy of the monitoring results. In the historical survey results, E. ilishaeformis, Odontobutis obscura, Odontamblyopus rubicundus, Coilia brachygnathus, M. fukiensis, and Tridentiger trigonocephalus were all recorded. However, after identification by fishery experts, it was judged that these species are unlikely to be found within Shanghai. The historical results might be attributed to past identification errors. For example, based on FishBase records, O. rubicundus is widely distributed in the Indo-West Pacific region, with records of its distribution found only along the coastal areas of Liaoning in China [81], and there is no record of its distribution in Shanghai or its surrounding areas. Many scholars in the past have misidentified O. lacepedii as O. rubicundus. Therefore, the records of O. rubicundus from the early 21st century and the 2010s may also be the result of identification errors.
(2)
Sampling intensity and location
Statistically, among the 41 fish species not detected in this study, 32 (78.05%) are demersal fish species, including Culter oxycephalus, Taenioides cirratus, Synechogobius hasta, and Rhodeus lighti. The phenomenon of a large number of demersal fish species not being detected may be due to the lack of stratified sampling in this study. In addition, our sampling sites were mainly concentrated in the main river channel, where riverbanks were cement-filled; however, G. affinis were mainly found in swamps with natural banks and aquatic plants, which may have resulted in the non-detection of G. affinis in this study. In terms of sampling intensity, this study only conducted surveys for a single season and had a limited number of sampling points. In contrast, the historical data integrated year-round data, and previous studies did not simultaneously monitor fish in the three main rivers of Shanghai. Instead, they focused mainly on specific watersheds and set more sampling points. For instance, in studies on the fish diversity of the Suzhou River, this survey only set 3 sampling points, while previous studies set 10 and 13 sampling points, respectively. This may be the reason for the lower number of fish species detected in the Suzhou River in this study (Figure 7).

4.3. Strategies for Prevention and Control of Invasive Fish Species

4.3.1. Enhancement of Regulatory Framework

In recent years, China has recognized the hazards of biological invasions, including those by fish species. Various departments have jointly formulated laws and regulations related to alien species to strengthen the prevention and control management and hazard governance of invasive species. For instance, the “Biosafety Law of the People’s Republic of China” issued in 2020 provides comprehensive arrangements for biosafety risk prevention and control [82]. The “Management Measures for Alien Invasive Species” released in 2022 establishes and improves the management system for alien invasive species, strengthening joint prevention and control, and upgrading the national management level for invasive species. Although China has achieved some positive results in the prevention and control of invasive species, legislation and research in this regard are still in their early stages, and policies and regulations for preventing and controlling invasive species are still inadequate and preliminary [83]. In the prevention and control management of invasive fish species, legislative authorities should subsequently formulate targeted quarantine standards and norms based on the invasion process of alien fish species (such as introduction pathways, possible sources, and hazard levels) and establish a systematic prevention and control management system [84]. Additionally, in the compilation of the list of invasive fish species, potentially harmful alien fish species should be considered to reduce blind spots and gaps in subsequent quarantine processes.

4.3.2. Strengthening Responsibilities of All Parties

China still faces challenges regarding the inadequate management intensity in the prevention and control of invasive fish species. To address this issue, efforts should be made to enhance the training of personnel in industries such as quarantine, international trade, and transportation, increasing their vigilance against early fish invasions [12]. On the other hand, specialized institutions should be established to supervise the work of various management departments, strengthen communication between departments, and ensure the coordination and consistency of management processes [84].

4.3.3. Improvement of Key Technologies

Currently, China lacks a unified standard for the risk assessment of invasive fish species [85]. There is an urgent need to establish an effective and operational risk assessment protocol for the invasion of alien fish species in the Chinese context. Additionally, the establishment of an expert committee to provide technical support for the risk assessment of invasive fish species is necessary. In the field of monitoring invasive fish species, technologies such as eDNA should be improved to establish a mature monitoring system to understand the invasion process and dispersal pathways of alien fish species. Moreover, for key processes such as port quarantine, biological control, and ecological restoration, practical technologies, products, and equipment for rapid identification, efficient capture, and biological control of invasive fish species should be developed to swiftly identify and eliminate invasive species [86].

4.3.4. Raising Awareness and Education Quality

The principle of public participation forms the basis of the early warning mechanism for invasive species and is a crucial driver of the early warning mechanism [12]. On the one hand, using media such as television broadcasts and the internet, online popular science campaigns on the prevention and control of invasive fish species should be conducted. On the other hand, institutions such as museums and schools can organize related science activities to explain to the public the biological characteristics, transmission pathways, hazard levels, and elimination methods of invasive fish species. This can enhance public awareness of ecological security and ignite societal interest in the protection of our natural waterways from the invasion of alien species.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/d16010029/s1, Table S1. Species composition of fishes at various sites in Shanghai based on the eDNA metabarcoding analysis.

Author Contributions

Conceptualization, S.L. and Q.W.; methodology, Q.W., A.Z. and J.Z.; validation, S.L., Q.W. and F.L.; investigation, R.Y. and F.L.; resources, S.L.; writing—original draft preparation, R.Y.; writing—review and editing, R.Y., Q.W. and S.L. All authors have read and agreed to the published version of the manuscript.

Funding

This research is funded by the National Natural Science Foundation of China, Youth Science Fund Programme, “Risk identification and assessment of non-native freshwater fishes in the Qiantang River”, grant number is 32001236.

Institutional Review Board Statement

Not applicable.

Data Availability Statement

The data presented in this study are available in this published paper and Supplementary Materials.

Acknowledgments

We would like to thank Wei Zhang, Chenxi Zhang, Yu Li, and Shuaitao Deng for helping us with the field sampling. We also express our gratitude to Guimei He for sharing the laboratory facilities at the School of Biological Sciences at East China Normal University. Finally, we would also like to thank two anonymous reviewers for their valuable comments on this paper.

Conflicts of Interest

The authors declare no conflict of interest.

Appendix A

Table A1. Composition of fish species in Shanghai.
Table A1. Composition of fish species in Shanghai.
OrderFamilyGenusSpeciesDianshan LakeHuangpu RiverSuzhou River
CypriniformesCyprinidaeParabramisParabramis pekinensis
ChanodichthysChanodichthys dabryi
Chanodichthys erythropterus
Chanodichthys mongolicus
CulterCulter alburnus
HemiculterHemiculter leucisculus
CtenopharyngodonCtenopharyngodon idella
MegalobramaMegalobrama terminalis
ElopichthysElopichthys bambusa
RhynchocyprisRhynchocypris oxycephalus
HemibarbusHemibarbus sp.
CarassiusCarassius sp.
CyprinusCyprinus carpio
HypophthalmichthysHypophthalmichthys molitrix
Hypophthalmichthys nobilis
OpsariichthysOpsariichthys bidens
PseudorasboraPseudorasbora parva
RhodeusRhodeus ocellatus
MylopharyngodonMylopharyngodon piceus
SarcocheilichthysSarcocheilichthys nigripinnis
Sarcocheilichthys sinensis
PseudobramaPseudobrama simoni
MicrophysogobioMicrophysogobio sp.
AcheilognathusAcheilognathus imberbis
Acheilognathus macropterus
Acheilognathus barbatulus
Acheilognathus chankaensis
AbbottinaAbbottina rivularis
ZaccoZacco acanthogenys
CobitidaeParamisgurnusParamisgurnus dabryanus
CobitisCobitis sp.
MisgurnusMisgurnus bipartitus *
Misgurnus anguillicaudatus
PerciformesBelontiidaeMacropodusMacropodus ocellatus
CentrarchidaeMicropterusMicropterus salmoides *
SerranidaeLateolabraxLateolabrax maculatus
SinipercaSiniperca chuatsi
ChannidaeChannaChanna maculata *
Channa argus
EleotridaeEleotrisEleotris oxycephala
OdontobutidaeOdontobutisOdontobutis potamophila
MicropercopsMicropercops swinhonis
GobiidaeRhinogobiusRhinogobius giurinus
Rhinogobius cliffordpopei
MugilogobiusMugilogobius myxodermus
TridentigerTridentiger bifasciatus
Taenioididae OdontamblyopusOdontamblyopus lacepedii
Anguilliformes Anguillidae AnguillaAnguilla japonica
SiluriformesBagridaeTachysurusTachysurus fulvidraco
Tachysurus nitidus
SiluridaeSilurusSilurus asotus
MugiliformesMugilidaeMugilMugil cephalus
ClupeiformesEngraulidae CoiliaCoilia sp.
CyprinodontiformesAdrianichthyidaeOryziasOryzias sinensis
“*” indicates that the fish is exotic.

Appendix B

Table A2. Number of fish species detected in Shanghai each year.
Table A2. Number of fish species detected in Shanghai each year.
OrderFamilyGenusSpecies2000s2010s2022
CypriniformesCyprinidaeParabramisParabramis pekinensis
ChanodichthysChanodichthys dabryi
Chanodichthys mongolicus
Chanodichthys erythropterus
CulterCulter oxycephalus
Culter alburnus
ErythroculterErythroculter ilishaeformis
HemiculterHemiculter bleekeri
Hemiculter leucisculus
CtenopharyngodonCtenopharyngodon idella
SqualiobarbusSqualiobarbus curriculus
MegalobramaMegalobrama mantschuricus
Megalobrama amblycephala
ElopichthysElopichthys bambusa
XenocyprisXenocypris microlepis
Xenocypris davidi
Xenocypris argentea
RhynchocyprisRhynchocypris oxycephalus
HemibarbusHemibarbus maculatus
CarassiusCarassius auratus
CyprinusCyprinus carpio
Cyprinus carpio var. mirror *
HypophthalmichthysHypophthalmichthys molitrix
Hypophthalmichthys nobilis
OpsariichthysOpsariichthys bidens
PseudorasboraPseudorasbora parva
RhodeusRhodeus lighti
Rhodeus ocellatus
PseudolaubucaPseudolaubuca engraulis
Pseudolaubuca sinensis
MylopharyngodonMylopharyngodon piceus
SarcocheilichthysSarcocheilichthys nigripinnis
Sarcocheilichthys sinensis
PseudobramaPseudobrama simoni
ParacanthobramaParacanthobrama guichenoti
ToxabramisToxabramis swinhonis
MicrophysogobioMicrophysogobio fukiensis
Microphysogobio microstomus
AcheilognathusAcheilognathus taenianalis
Acheilognathus imberbis
Acheilognathus macropterus
Acheilognathus barbatulus
Acheilognathus chankaensis
Acheilognathus tonkinensis
DistoechodonDistoechodon hupeinensis
Distoechodon tumirostris
SqualidusSqualidus argentatus
AbbottinaAbbottina rivularis
ZaccoZacco acanthogenys
CobitidaeParamisgurnusParamisgurnus dabryanus
CobitisCobitis taenia
MisgurnusMisgurnus bipartitus *
Misgurnus anguillicaudatus
PerciformesMastacembelidaeMastacembelusMastacembelus aculeatus
SinobdellaSinobdella sinensis
BelontiidaeMacropodusMacropodus ocellatus
CentrarchidaeMicropterusMicropterus salmoides *
SerranidaeLateolabraxLateolabrax maculatus
SinipercaSiniperca knerii
Siniperca chuatsi
ChannidaeChannaChanna maculata *
Channa argus
EleotridaeEleotrisEleotris oxycephala
OdontobutidaeOdontobutisOdontobutis potamophila
Odontobutis obscura
MicropercopsMicropercops swinhonis
GobiidaeRhinogobiusRhinogobius giurinus
Rhinogobius cliffordpopei
SynechogobiusSynechogobius hasta
MugilogobiusMugilogobius myxodermus
TridentigerTridentiger trigonocephalus
Tridentiger bifasciatus
Taenioididae OdontamblyopusOdontamblyopus lacepedii
Odontamblyopus rubicundus
TaenioidesTaenioides cirratus
Anguilliformes Anguillidae AnguillaAnguilla japonica
SiluriformesBagridaeTachysurusTachysurus fulvidraco
Tachysurus nitidus
SiluridaeSilurusSilurus asotus
ClariidaeClariasClarias gariepinus *
TetraodontiformesTetraodontidaeTakifuguTakifugu obscurus
MugiliformesMugilidaeLizaLiza haematocheila
MugilMugil cephalus
PleuronectiformesSoleidaeCynoglossusCynoglossus gracilis
ClupeiformesEngraulidae CoiliaCoilia nasus
Coilia brachygnathus
SynbranchiformesSynbranchidaeMonopterusMonopterus albus
BeloniformesHemiramphidaeHyporhamphusHyporhamphus intermedius
SalmoniformesSalangidaeSalangichthysSalangichthys tangkahkeii
CyprinodontiformesAdrianichthyidaeOryziasOryzias sinensis
PoeciliidaeGambusiaGambusia affinis *
“*” indicates that the fish is exotic.

References

  1. Zhang, X.S.; Hill, W.G. Genetic variability under mutation selection balance. Trends Ecol. Evol. 2005, 20, 468–470. [Google Scholar] [CrossRef] [PubMed]
  2. Vilà, M.; Espinar, J.L.; Hejda, M.; Hulme, P.E.; Jarošík, V.; Maron, J.L.; Pergl, J.; Schaffner, U.; Sun, Y.; Pyšek, P. Ecological impacts of invasive alien plants: A meta-analysis of their effects on species, communities and ecosystems. Ecol. Lett. 2011, 14, 702–708. [Google Scholar] [CrossRef] [PubMed]
  3. Li, S.; Chen, J.K.; Wang, X.M. Global distribution, entry routes, mechanisms and consequences of invasive freshwater fish. Biodivers. Sci. 2016, 24, 672–685. [Google Scholar] [CrossRef]
  4. Gurevitch, J.; Padilla, D.K. Are invasive species a major cause of extinctions? Trends Ecol. Evol. 2004, 19, 470–474. [Google Scholar] [CrossRef] [PubMed]
  5. Ehrenfeld, J.G. Ecosystem consequences of biological invasions. Annu. Rev. Ecol. Evol. Syst. 2010, 41, 59–80. [Google Scholar] [CrossRef]
  6. Doherty, T.S.; Glen, A.S.; Nimmo, D.G.; Ritchie, E.G.; Dickman, C.R. Invasive predators and global biodiversity loss. Proc. Natl. Acad. Sci. USA 2016, 113, 11261–11265. [Google Scholar] [CrossRef]
  7. Reid, W.V.; Mooney, H.A.; Cropper, A.; Capistrano, D.; Carpenter, S.R.; Chopra, K. Ecosystems and Human Well-Being, 1st ed.; Island Press: Washington, DC, USA, 2005; pp. 14–17. [Google Scholar]
  8. Brondízio, E.S.; Settele, J.; Diaz, S. The Global Assessment Report on Biodiversity and Ecosystem Services; IPBES: Bonn, Germany, 2019. [Google Scholar]
  9. Seebens, H.; Blackburn, T.M.; Dyer, E.E.; Genovesi, P.; Hulme, P.E.; Jeschke, J.M.; Pagad, S.; Pyšek, P.; Winter, M.; Arianoutsou, M.; et al. No saturation in the accumulation of alien species worldwide. Nat. Commun. 2017, 8, 14435. [Google Scholar] [CrossRef]
  10. Xing, W.Q.; Chen, R.S.; Lu, J.G.; Guo, X.N. lnternational progress of biological invasion research and the status quo in China: The bibliometric analysis based on CiteSpace. Acta Ecol. Sin. 2023, 43, 6912–6922. [Google Scholar]
  11. Ministry of Ecology and Environment of the People’s Republic of China Report on the State of the Ecology and Environment in China 2019. p. 39. Available online: https://www.mee.gov.cn/hjzl/sthjzk/zghjzkgb/202006/P020200602509464172096.pdf (accessed on 15 October 2023).
  12. Hu, Y.C.; Song, H.M.; Mou, X.D.; Luo, J.R. Invasion of exotic species and their control measures taken in China. J. Biosaf. 2012, 21, 256–261+242. [Google Scholar]
  13. Dominguez Almela, V.; Palmer, S.C.F.; Andreou, D.; Gillingham, P.K.; Travis, J.M.J.; Britton, J.R. Predicting the influence of river network configuration, biological traits and habitat quality interactions on riverine fish invasions. Divers. Distrib. 2022, 28, 257–270. [Google Scholar] [CrossRef]
  14. Xiao, Q.Z.; Chen, L.J.; Jin, J.J.; Qiu, Y.P.; Chen, G.Z. Ecomorphological traits explaining the competition exclusion between Oryzias and mosquitofish. Chin. J. Appl. Ecol. 2020, 31, 2087–2097. [Google Scholar]
  15. Zhong, L.; Yin, Y.Q.; Liao, H.; Kuang, G.X.; Yang, Y. Strictly prevent the Trachemys scripta elegans’s impact on Chongqing aquatic ecosystem. Guizhou J. Anim. Husb. Vet. Med. 2021, 45, 67–68. [Google Scholar]
  16. Li, B.; Xu, B.S.; Chen, J.K. Perspectives on general trends of plant invasions with special reference to alien weed flora of Shanghai. Biodivers. Sci. 2001, 9, 446–457. [Google Scholar]
  17. Zhang, Q.R.; Jiang, S.; Ju, R.T.; Pan, X.Y. Diversity of invasive species in Shanghai. Biodivers. Sci. 2014, 21, 732–737. [Google Scholar]
  18. Li, X.X.; Lv, H.; Wang, W.M.; Chen, Y.M.; Sun, P.; Wang, H.P.; Xu, X.; Yin, C.Y.; Xu, W. Review on the distribution status, hazards and control strategy of Pomacea canaliculate. Jiangxi Sci. 2023, 41, 236–243+265. [Google Scholar]
  19. Li, C.L. Trails on the growth speed and breeding potential of Pomacea canaliculata. Plant Prot. 1995, 21, 21. [Google Scholar]
  20. Carlsson, N.; Kestrup, A.; Martensson, M.; Nystrom, P. Lethal and non-lethal effects of multiple indigenous predators on the invasive golden apple snail (Pomacea canaliculata). Freshw. Biol. 2004, 49, 1269–1279. [Google Scholar] [CrossRef]
  21. Zhang, C.X.; Guo, J.; Zhang, J.E.; Chu, S.Y. Research progress on the interaction between alien invasive snail Pomacea canaliculata and native species. Ecol. Sci. 2017, 36, 226–235. [Google Scholar]
  22. Yu, H.; Bi, B.C.; Tang, W.Q.; Zhang, Y.; Guo, H.Y. Changes in fish diversity and assemblage during comprehensive restoration of the Suzhou River in Shanghai. Biodivers. Sci. 2021, 29, 32–42. [Google Scholar]
  23. Xia, J.H.; Lu, J.F.; Zhou, B.C. A preliminary study on fish communities in Suzhou Creek, Shanghai. J. Lake Sci. 2009, 21, 538–546. [Google Scholar]
  24. Copp, G.; Vilizzi, L.; Tidbury, H.; Stebbing, P.; Tarkan, A.S.; Miossec, L.; Goulletquer, P. Development of a generic decision-support tool for identifying potentially invasive aquatic taxa: AS-ISK. Manag. Biol. Invasions 2016, 7, 343–350. [Google Scholar] [CrossRef]
  25. Copp, G.H.; Godard, M.J.; Russell, I.C.; Peeler, E.J.; Gherardi, F.; Tricarico, E.; Miossec, L.; Goulletquer, P.; Almeida, D.; Britton, J.R.; et al. A preliminary evaluation of the European Non-native Species in Aquaculture Risk Assessment Scheme applied to species listed on Annex IV of the EU Alien Species Regulation. Fish. Manag. Ecol. 2016, 23, 12–20. [Google Scholar] [CrossRef]
  26. Li, S.; Chen, J.; Wang, X.; Copp, G.H. Invasiveness screening of non-native fishes for the middle reach of the Yarlung Zangbo River, Tibetan Plateau, China. River Res. Appl. 2017, 33, 1439–1444. [Google Scholar] [CrossRef]
  27. Li, X.; Tang, W.; Zhao, Y. Risk analysis of fish invasion in Haihe River Basin caused by the central route of the South-to-North Water Diversion Project. Biodivers. Sci. 2021, 29, 1336–1347. [Google Scholar] [CrossRef]
  28. Wei, H.; Chaichana, R.; Vilizzi, L.; Daengchana, P.; Liu, F.; Nimtim, M.; Zhu, Y.; Li, S.; Hu, Y.; Copp, G.H. Do non-native ornamental fishes pose a similar level of invasion risk in neighbouring regions of similar current and future climate? Implications for conservation and management. Aquat. Conserv.-Mar. Freshw. Ecosyst. 2021, 31, 2041–2057. [Google Scholar] [CrossRef]
  29. Tarkan, A.S.; Sari, H.M.; İlhan, A.; Kurtul, I.; Vilizzi, L. Risk screening of non-native and translocated freshwater fish species in a Mediterranean-type shallow lake: Lake Marmara (West Anatolia). Zool. Middle E. 2017, 63, 48–57. [Google Scholar] [CrossRef]
  30. Tarkan, A.S.; Vilizzi, L.; Top, N.; Ekmekçi, F.G.; Stebbing, P.D.; Copp, G.H. Identification of potentially invasive freshwater fishes, including translocated species, in Turkey using the Aquatic Species Invasiveness Screening Kit (AS-ISK). Int. Rev. Hydrobiol. 2017, 102, 47–56. [Google Scholar] [CrossRef]
  31. Bilge, G.; Filiz, H.; Yapici, S.; Tarkan, A.S.; Vilizzi, L. A risk screening study on the potential invasiveness of lessepsian fishes in the South-Eastern coasts of Anatolia. Acta Ichthyol. Piscat. 2019, 49, 23–31. [Google Scholar] [CrossRef]
  32. Dodd, J.A.; Vilizzi, L.; Bean, C.W.; Davison, P.I.; Copp, G.H. At what spatial scale should risk screenings of translocated freshwater fishes be undertaken—River basin district or climo-geographic designation? Biol. Conserv. 2019, 230, 122–130. [Google Scholar] [CrossRef]
  33. Suresh, V.R.; Ekka, A.; Biswas, D.K.; Sahu, S.K.; Yousuf, A.; Das, S. Vermiculated sailfin catfish, Pterygoplichthys disjunctivus (Actinopterygii: Siluriformes: Loricariidae): Invasion, biology, and initial impacts in East Kolkata Wetlands, India. Acta Ichthyol. Piscat. 2019, 49, 221–233. [Google Scholar] [CrossRef]
  34. Interesova, E.; Vilizzi, L.; Copp, G.H. Risk screening of the potential invasiveness of non-native freshwater fishes in the River Ob basin (West Siberian Plain, Russia). Reg. Environ. Chang. 2020, 20. [Google Scholar] [CrossRef]
  35. Haubrock, P.J.; Copp, G.H.; Johović, I.; Balzani, P.; Inghilesi, A.F.; Nocita, A.; Tricarico, E. North American channel catfish, Ictalurus punctatus: A neglected but potentially invasive freshwater fish species? Biol. Invasions 2021, 23, 1563–1576. [Google Scholar] [CrossRef]
  36. Paganelli, D.; Kamburska, L.; Zaupa, S.; Garzoli, L.; Boggero, A. Impacts analysis of alien macroinvertebrate species in the hydrographic system of a subalpine lake on the Italian–Swiss border. Water 2021, 13, 3146. [Google Scholar] [CrossRef]
  37. Paganelli, D.; Pandolfi, A.; Sconfietti, R.; Marchini, A.; Vilizzi, L. Potential invasiveness by non-indigenous macrozoobenthos in the secondary hydrographic system of a temperate-climate river catchment. Ecol. Indic. 2018, 88, 274–281. [Google Scholar] [CrossRef]
  38. Diao, C.Y.; Wang, W.; Xian, W.W.; Zhang, H. Role of the environmental DNA technology application in the biomass assessment of the fishery resource: Current status and future perpectives. Mar. Sci. 2022, 46, 135–144. [Google Scholar]
  39. Jiang, W.; Zhao, H.; Deng, J. Detection of aquatic species using environmental DNA. J. Hydroecol. 2016, 37, 1–7. [Google Scholar]
  40. Valentini, A.; Taberlet, P.; Miaud, C.; Civade, R.; Herder, J.; Thomsen, P.F.; Bellemain, E.; Besnard, A.; Coissac, E.; Boyer, F.; et al. Next-generation monitoring of aquatic biodiversity using environmental DNA metabarcoding. Mol. Ecol. 2016, 25, 929–942. [Google Scholar] [CrossRef]
  41. Liu, B.; Wang, H.; Qin, B. Environmental DNA metabarcoding-based monitoring of fish diversity and screening invasion risk of non-native fishes in the Beijing area. J. Biosaf. 2021, 30, 220–229. [Google Scholar]
  42. Jeunen, G.J.; Lipinskaya, T.; Gajduchenko, H.; Golovenchik, V.; Moroz, M.; Rizevsky, V.; Semenchenko, V.; Gemmell, N.J. Environmental DNA (eDNA) metabarcoding surveys extend the range of invasion for non-indigenous freshwater species in Eastern Europe. BioRxiv 2021. [Google Scholar] [CrossRef]
  43. Ficetola, G.F.; Miaud, C.; Pompanon, F.; Taberlet, P. Species detection using environmental DNA from water samples. Biol. Lett. 2008, 4, 423–425. [Google Scholar] [CrossRef]
  44. Glamuzina, B.; Tutman, P.; Nikolić, V.; Vidović, Z.; Pavličević, J.; Vilizzi, L.; Copp, G.H.; Simonović, P. Comparison of taxon-specific and taxon-generic risk screening tools to identify potentially invasive non-native fishes in the river Neretva catchment (Bosnia and Herzegovina and Croatia). River Res. Applic. 2017, 33, 670–679. [Google Scholar] [CrossRef]
  45. Yamanaka, H.; Minamoto, T.; Matsuura, J.; Sakurai, S.; Tsuji, S.; Motozawa, H.; Hongo, M.; Sogo, Y.; Kakimi, N.; Teramura, I.; et al. A simple method for preserving environmental DNA in water samples at ambient temperature by addition of cationic surfactant. Limnology 2017, 18, 233–241. [Google Scholar] [CrossRef]
  46. Xia, Z.Q.; Gu, J.N.; Wen, Y.; Cao, X.K.; Gao, Y.C.; Li, S.G.; Haffner, G.D.; MacIsaac, H.J.; Zhan, A. eDNA-based detection reveals invasion risks of a biofouling bivalve in the world’s largest water diversion project. Ecol. Appl. 2023, e2826. [Google Scholar] [CrossRef] [PubMed]
  47. Miya, M.; Sato, Y.; Fukunaga, T.; Sado, T.; Poulsen, J.Y.; Sato, K.; Minamoto, T.; Yamamoto, S.; Yamanaka, H.; Araki, H.; et al. MiFish, a set of universal PCR primers for metabarcoding environmental DNA from fishes: Detection of more than 230 subtropical marine species. R. Soc. Open Sci. 2015, 2, 150088. [Google Scholar] [CrossRef] [PubMed]
  48. Wu, Q.Q.; Sakata, M.K.; Wu, D.Y.; Yamanaka, H.; Minamoto, T. Application of environmental DNA metabarcoding in a lake with extensive algal blooms. Limnology 2021, 22, 363–370. [Google Scholar] [CrossRef]
  49. Hamady, M.; Walker, J.J.; Harris, J.K.; Gold, N.J.; Knight, R. Error-correcting barcoded primers for pyrosequencing hundreds of samples in multiplex. Nat. Methods 2008, 5, 235–237. [Google Scholar] [CrossRef] [PubMed]
  50. Edgar, R.C. Search and clustering orders of magnitude faster than BLAST. Bioinformatics 2010, 26, 2460–2461. [Google Scholar] [CrossRef] [PubMed]
  51. Jeunen, G.J.; Lamare, M.D.; Knapp, M.; Spencer, H.G.; Taylor, H.R.; Stat, M.; Bunce, M.; Gemmell, N.J. Water stratification in the marine biome restricts vertical environmental DNA (eDNA) signal dispersal. Environ. DNA 2020, 2, 99–111. [Google Scholar] [CrossRef]
  52. Sun, J.Y.; Dai, X.J.; Zhu, J.F. Analysis of the fish species diversity in Dianshan Lake. J. Shanghai Fish. Univ. 2007, 16, 454–459. [Google Scholar]
  53. Wang, K. Temporal and Spatial Distrubition of Resources, and Trophic Levels of Main Species in the Dianshan Lake. Master’s Thesis, Shanghai Ocean University, Shanghai, China, 2017. [Google Scholar]
  54. Chen, X.H.; Li, X.P.; Cheng, X. Spatial-temporal distribution of fish assemblages in the upstreams of Huangpu River and Suzhou Creek. Biodivers. Sci. 2008, 16, 191. [Google Scholar]
  55. Zhou, T.S.; Zhang, Y.; Tang, W.Q.; Wang, L.Q. Ecological health assessment of Huangpu River based on fish index of biotic integrity. Resour. Environ. Yangtze Basin 2016, 25, 895–903. [Google Scholar]
  56. Chen, D.H.; Chen, Z.; Lin, J.B.; Qin, Z.Q.; Liang, P.; Li, X.G.; Qiu, M.L. Current situation and prospect of largemouth bass industry in Fujian Province. J. Aquacult. 2020, 41, 75–77. [Google Scholar]
  57. Bai, J.J.; Li, S.J. Current status and development trend on China largemouth bass industry. Chin. Fish. Econ. 2013, 31, 104–108. [Google Scholar]
  58. Gu, D.E.; Wang, J.W.; Xu, M.; Mu, X.D.; Wei, H.; Yu, F.D.; Fang, M.; Wang, X.J.; Song, H.M.; Yang, Y.X.; et al. Does aquaculture aggravate exotic fish invasions in the rivers of southern China? Aquaculture 2022, 547, 737492. [Google Scholar] [CrossRef]
  59. Hussein, G.H.G.; Chen, M.; Qi, P.P.; Cui, Q.K.; Yu, Y.; Hu, W.H.; Tian, Y.; Fan, Q.X.; Gao, Z.X.; Feng, M.W.; et al. Aquaculture industry development, annual price analysis and out-of-season spawning in largemouth bass Micropterus salmoides. Aquaculture 2020, 519, 734901. [Google Scholar] [CrossRef]
  60. Fang, K.; Zhang, Y.Y.; Shen, L.; Zhou, Q.; Shao, J.; Xu, Q.Q.; Gorfine, H.; Zhang, H. Increasing invasion risk from the northward expansion of largemouth bass (Micropterus salmoides) in china under multiple influences. Appl. Ecol. Environ. Res. 2023, 21, 835–852. [Google Scholar] [CrossRef]
  61. Peel, M.C.; Finlayson, B.L.; McMahon, T.A. Updated world Köppen-Geiger climate classification map. Hydrol. Earth Syst. Sci. 2007, 11, 259–263. [Google Scholar] [CrossRef]
  62. Wan, F.H.; Hou, Y.M.; Jiang, M.X. Invasion Biology, 1st ed.; Science Press: Beijing, China, 2015; pp. 19–41. [Google Scholar]
  63. Gross, M.R.; Sargent Craig, R. The evolution of male and female parental care in fishes. Am. Zool. 1985, 25, 807–822. [Google Scholar] [CrossRef]
  64. Liu, C.L.; Comte, L.; Olden, J.D. Heads you win, tails you lose: Life-history traits predict invasion and extinction risk of the world’s freshwater fishes. Aquat. Conserv. Mar. Freshw. Ecosyst. 2017, 27, 773–779. [Google Scholar] [CrossRef]
  65. Staub, B.P.; Hopkins, W.A.; Novak, J.; Congdon, J.D. Respiratory and reproductive characteristics of eastern mosquitofish (Gambusia holbrooki) inhabiting a coal ash settling basin. Arch. Environ. Contam. Toxicol. 2004, 46, 96–101. [Google Scholar] [CrossRef]
  66. Swingle, H.S.; Smith, E.V. Factors Affecting the Reproduction of Bluegill Bream and Largemouth Black Bass in Ponds; Alabama Polytechnic Institute: Auburn, AL, USA, 1943; Volume 87. [Google Scholar]
  67. Yan, Y.Z.; Chen, Y.F.; Tao, J. Ecological invasion of Gambusia affinis: A review. Chin. J. Ecol. 2009, 28, 950–958. [Google Scholar]
  68. Karp, C.A.; Tyus, H.M. Behavioral interactions between young Colorado squawfish and six fish species. Copeia 1990, 25–34. [Google Scholar] [CrossRef]
  69. Hoover, J.J.; Murphy, C.E.; Killgore, J. Ecological impacts of suckermouth catfishes (Loricariidae) in North America: A conceptual model. Aquat. Nuis. Species Res. Program 2014, 14, 1–13. [Google Scholar]
  70. Hellmann, J.J.; Byers, J.E.; Bierwagen, B.G.; Dukes, J.S. Five potential consequences of climate change for invasive species. Conserv. Biol. 2008, 22, 534–543. [Google Scholar] [CrossRef] [PubMed]
  71. Britton, J.R.; Cucherousset, J.; Davies, G.D.; Godard, M.J.; Copp, G.H. Non-native fishes and climate change: Predicting species responses to warming temperatures in a temperate region. Freshw. Biol. 2010, 55, 1130–1141. [Google Scholar] [CrossRef]
  72. Li, B.; Zhou, T.J. Projected climate change over China under IPCC A1B scenario: Multi-model ensemble and uncertainties. Clim. Chang. Res. 2010, 6, 270–276. [Google Scholar]
  73. Zanatta, A.S.; Ramos, I.P.; Silva, R.J. Pisces, Siluriformes, Ictaluridae, Ictalurus punctatus (Rafinesque, 1818): First record in middle Paranapanema river reservoir, aquaculture and exotic species dispersion. Check List 2010, 6, 3069–3071. [Google Scholar] [CrossRef]
  74. Chang, Z.C.; Wen, H.S.; Zhang, M.Z. Effects of dissolved oxygen levels on oxidative stress response and energy utilization of juvenile Chinese sea bass (Lateolabrax maculatus) and associate physiological mechanisms. Period. Ocean Univ. China 2018, 48, 20–28. [Google Scholar]
  75. Song, Y.D.; Zhang, M.D.; Zhou, H.T. Effects of different dissolved oxygen levels on respiratory metabolism and related gene expression in mandarinfish Siniperca chuatsi. Fish. Sci. 2022, 41, 438–444. [Google Scholar]
  76. Huang, S.L.; Dai, X.J.; Chen, Q. Current situation and existing problems of aquatic species enhancement and releasing in Shanghai water area. Chin. Fish. Econ. 2009, 4, 79–87. [Google Scholar]
  77. Li, H.X.; Huang, X.N.; Li, S.G.; Zhan, A.B. Environmental DNA (eDNA)-metabarcoding-based early monitoring and warning for invasive species in aquatic ecosystems. Biodivers. Sci. 2019, 27, 491–504. [Google Scholar]
  78. Xiong, W.; Li, H.T.; Zhan, A.B. Early detection of invasive species in marine ecosystems using high-throughput sequencing: Technical challenges and possible solutions. Mar. Biol. 2016, 163. [Google Scholar] [CrossRef]
  79. Zhan, A.B.; MacIsaac, H.J. Rare biosphere exploration using high-throughput sequencing: Research progress and perspectives. Conserv. Genet. 2015, 16, 513–522. [Google Scholar] [CrossRef]
  80. Liu, S.; Zhu, X.P.; Chen, K.C. Morphological variations of Channa maculata, Channa argus and their hybrid (C. maculata♀ × C. argus♂). J. Huazhong Agric. Univ. 2011, 30, 488–493. [Google Scholar]
  81. Lu, M.J.; Liu, H.B.; Jiang, T. Preliminary investigations on otolith microchemistry of Odontamblyopus rubicundus in the Daliao River Estuary, China. Mar. Fish. 2015, 37, 310–317. [Google Scholar]
  82. Liu, M.; Shi, H.T. The improvement of the prevention and control mechanism of the risk of alien species invasion in China. J. Fuyang Inst. Technol. 2023, 34, 97–101. [Google Scholar]
  83. Wang, R.; Huang, H.S.; Zhang, H.B. Analysis of gaps in regulations and management mechanisms for the prevention and control of invasive alien species in China. Plant Prot. 2022, 48, 2–9. [Google Scholar]
  84. Liu, R. Research on legal provisions on invasive alien species. L. Vision 2017, 109–110. [Google Scholar] [CrossRef]
  85. Dou, Y.; Wu, J.; Huang, C. Risk assessment system and method for invasion of alien fishes. J. Ecol. Rural Environ. 2011, 27, 12–16. [Google Scholar]
  86. Zhou, M.H.; Ding, Z.P.; Wang, M.S. Review on the current status of prevention and control of invasive alien species in China. Plant Quar. 2023, 37, 1–7. [Google Scholar]
Diversity 16 00029 g001
Figure 1. Schematic map of the sampling points in the major rivers of Shanghai.
Figure 1. Schematic map of the sampling points in the major rivers of Shanghai.
Diversity 16 00029 g001
Diversity 16 00029 g002
Figure 2. Receiver operating characteristic curve of Aquatic Species Invasiveness Screening Kit scores for 21 exotic aquatic organisms in Shanghai: (a) ROC curve for Basic Risk Assessment (BRA) and (b) ROC curves for Integrated Assessment under Climate Change conditions (BRA + CCA).
Figure 2. Receiver operating characteristic curve of Aquatic Species Invasiveness Screening Kit scores for 21 exotic aquatic organisms in Shanghai: (a) ROC curve for Basic Risk Assessment (BRA) and (b) ROC curves for Integrated Assessment under Climate Change conditions (BRA + CCA).
Diversity 16 00029 g002
Diversity 16 00029 g003
Figure 3. Fish species composition in Shanghai based on eDNA metabarcoding analysis. In this picture, different colors represent different orders, and the size of the circle reflects the number of fish species in that order or family.
Figure 3. Fish species composition in Shanghai based on eDNA metabarcoding analysis. In this picture, different colors represent different orders, and the size of the circle reflects the number of fish species in that order or family.
Diversity 16 00029 g003
Diversity 16 00029 g004
Figure 4. Number of fish species in the three major rivers of Shanghai.
Figure 4. Number of fish species in the three major rivers of Shanghai.
Diversity 16 00029 g004
Diversity 16 00029 g005
Figure 5. Composition of fish species in different time periods. (a) Composition at the order level and (b) composition at the family level. The results for 2022 are from this study.
Figure 5. Composition of fish species in different time periods. (a) Composition at the order level and (b) composition at the family level. The results for 2022 are from this study.
Diversity 16 00029 g005
Diversity 16 00029 g006
Figure 6. The number of fish species detected in Shanghai in each year. The results for 2022 are from the eDNA analysis conducted in this study.
Figure 6. The number of fish species detected in Shanghai in each year. The results for 2022 are from the eDNA analysis conducted in this study.
Diversity 16 00029 g006
Diversity 16 00029 g007
Figure 7. Interannual variation in the number of fish species in the three main rivers of Shanghai.
Figure 7. Interannual variation in the number of fish species in the three main rivers of Shanghai.
Diversity 16 00029 g007
Table 1. The invasiveness results of the 21 exotic aquatic organisms in Shanghai assessed with the Aquatic Species Invasiveness Screening Kit.
Table 1. The invasiveness results of the 21 exotic aquatic organisms in Shanghai assessed with the Aquatic Species Invasiveness Screening Kit.
SpeciesOutcomeConfidence Factor
CriteriaCommon NameScientific NameBRA ScoreInvasion RiskBRA + CCA ScoreInvasion RiskBRACCABRA + CCA
1Mosquito fishGambusia affinis32high32high0.550.250.52
1Channeled applesnailPomacea canaliculata32high40high0.530.250.50
3BluegillLepomis macrochirus31high33high0.560.250.53
3Redbelly tilapiaCoptodon zillii31high41high0.590.330.56
3Green sunfishLepomis cyanellus29.5high35.5high0.560.250.53
1Red swamp crayfishProcambarus clarkii29.5high29.5high0.550.250.51
2BullfrogRana catesbeiana28.5high34.5high0.540.250.50
4Suckermouth catfishHypostomus plecostomus28high36high0.470.380.46
4Largemouth black bassMicropterus salmoides27high39high0.600.250.56
4Red-eared sliderTrachemys scripta elegans25low25low0.470.250.45
2North African catfishClarias gariepinus24low32high0.550.250.51
4American shadAlosa sapidissima23.5low23.5low0.540.250.50
4Channel catfishIctalurus punctatus23.5low31.5high0.490.330.48
4PirapitingaPiaractus brachypomus23.5low33.5high0.580.250.55
4Amur sturgeonAcipenser schrenckii21low17low0.510.290.49
4Blue tilapiaOreochromis aureus20.5low22.5low0.580.250.55
3Red drumSciaenops ocellatus20low28low0.490.250.46
4European eelAnguilla anguilla20low24low0.510.250.48
2Rainbow troutOncorhynchus mykiss18.5low10.5low0.560.380.54
4TenchTinca tinca15.5low21.5low0.530.330.50
4Roho labeoLabeo rohita15low13low0.530.250.50
Table 2. List of alien fish species at each site monitored using eDNA metabarcoding analysis.
Table 2. List of alien fish species at each site monitored using eDNA metabarcoding analysis.
Drainage BasinSiteSpecies
Channa maculataMisgurnus bipartitusMicropterus salmoides
Huangpu RiverSH1
SH3
SH12
SH13
SH14
SH15
SH16
Suzhou RiverSH2
SH4
SH5
Dianshan LakeSH6
SH7
SH8
SH9
SH10
SH11
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Yu, R.; Wu, Q.; Li, F.; Zhan, A.; Zhou, J.; Li, S. Risk Screening of Invasive Aquatic Species and a Survey of Fish Diversity Using Environmental DNA Metabarcoding Analysis in Shanghai. Diversity 2024, 16, 29. https://doi.org/10.3390/d16010029

AMA Style

Yu R, Wu Q, Li F, Zhan A, Zhou J, Li S. Risk Screening of Invasive Aquatic Species and a Survey of Fish Diversity Using Environmental DNA Metabarcoding Analysis in Shanghai. Diversity. 2024; 16(1):29. https://doi.org/10.3390/d16010029

Chicago/Turabian Style

Yu, Ruohan, Qianqian Wu, Fan Li, Aibin Zhan, Jinxin Zhou, and Shan Li. 2024. "Risk Screening of Invasive Aquatic Species and a Survey of Fish Diversity Using Environmental DNA Metabarcoding Analysis in Shanghai" Diversity 16, no. 1: 29. https://doi.org/10.3390/d16010029

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop