2.2. Sample collection

A total of 46 sampling sites were covered in this survey for collecting freshwater shrimp (Figure 1). The sampling sites covered the main streams and tributaries of the four major rivers (i.e., the Yangtze River, the Huaihe River, the Yellow River, and the Haihe River) of the province (Table S1). In this study, about 1,200 samples representing nine species, six genera, and four families were collected. Most of the shrimp were collected by shrimp traps, but many individuals were obtained from markets. The samples were preserved in 95% ethanol for subsequent morphological observation and molecular identification. All voucher specimens were stored in the Fisheries College of Henan Normal University.

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FIGURE 1

Sampling sites of freshwater shrimp in Henan province

2.3. Morphological identification

Morphological identification was mainly classified in situ by visual inspection in the field, and then detailed morphological identification and classification were conducted in the laboratory by stereomicroscope microscopic examination. All samples were taxonomically classified based on the distinguishing morphological characters of the male collected specimens according to Liu (1955), Liang (2004), and Li et al. (2007).

2.4. DNA extraction, amplification, and sequencing

According to the results of morphological identification, multiple representative individuals of each taxonomic group were selected for abdominal muscle sampling. The obtained tissue samples were immediately stored in 95% ethanol and numbered for DNA extraction. To ensure the coverage of each species, individuals with moderate body size were selected as far as possible for EP tube preservation and numbering, and the larger individuals were marked with winding coils.

Genomic DNA was extracted by phenol‐chloroform (Sambrook & Russel, 2001) from muscle tissue (0.1–0.15 g) and verified using 1.0% agarose gel electrophoresis.

The amplification of the COI gene was carried out by polymerase chain reaction (PCR). A 632 bp fragment was amplified using the forward primer (LCO1490: 5′‐GGTCAACAAATCA TAAAGATATTGG‐3′) and reverse primer (HCO2198: 5′‐TAAACTTCAGGGTGACCAAAAAA TCA‐3′) (Folmer et al., 1994). PCRs were performed in a total volume of 50 μl containing 50–100 ng DNA template, 5 µl of 10× PCR buffer, 1.5 mmol/L of MgCl₂, 0.2 mmol/L of each dNTP, 2 unit (U) of Taq polymerase, and 0.2 µmol/L of each primer. Thermal cycling began with one cycle of pre‐denaturation at 94°C for 5 min, 35 cycles of denaturation at 94°C for 30 s, annealing at 50°C for 45 s, extension at 72°C for 45 s, and a final extension holding at 72°C for 7 min (Feng et al., 2008). The PCR products were separated by electrophoresis on 1.0% agarose gels.

Primer synthesis and DNA sequencing were conducted by commercial companies. Among the 222 specimens, 141 were sequenced in one direction (63.51%), and the other specimens were two‐way sequenced. Except for the sequences obtained from the genomic DNA in this study, the other COI sequences were obtained from GenBank for comparative analyses (Table S2).

2.5. Sequencing analysis

The chromatogram inspection, alignment, and calibration of the original sequences used SeqMan (Swindell & Plasterer, 1997) of the DNASTAR Lasergene software package (DNASTAR, Inc., Madison, Wisconsin, USA). BioEdit v 7.0.9 (Tippmann, 2004) was used to align and shear sequences.

In this study, traditional morphological identification and a variety of different molecular methods were used for comprehensive analysis and species delimitation. Due to the uneven sampling and the differences in effective population sizes of species (Blair & Bryson, 2017), we chose Automatic Barcode Gap Discovery (ABGD) and Poisson tree processes (PTP) for quantifying and delimiting taxonomic diversity. The specific analysis is described below.

2.6. Distance‐based approaches

Given that previous studies showed that the use of the Kimura‐2‐parameter (K2P) model in DNA‐barcoding studies is poorly justified, but no more suitable model has been derived at present; therefore, in order to obviate the requirement for model correction in DNA barcoding, a p‐distance model was used in our analysis and calculations, while the K2P model was also used (Srivathsan & Meier, 2012; Collins et al., 2012). The K2P and p‐distance models were used to construct a neighbor‐joining tree and to calculate the pairwise genetic distances using MEGA 7.0 (Kumar et al., 2016). The haplotype diversity and nucleotide diversity of COI sequences were calculated using DnaSP 5.0 (Librado & Rozas, 2009). Then, ML tree analysis was implemented using RaxmlGUI (Stamatakis, 2014) with the default parameters and 1,000 replications. In all trees, bootstrap values below 70% are not shown.

Each sequence was selected for further species confirmation by the IDENTIFICATION of BOLD and the BLAST of NCBI to evaluate the accuracy of the morphological identification and to obtain reference sequences with high relative similarity. In the selection of similar sequences, we have defined 97% as a relatively loose standard to indicate potential species identification (Wong & Hanner, 2008).

In this study, a total 42 COI sequences with high similarity were obtained by aligning from GenBank. Gammarus pisinnus (GenBank accession number: KF824592) was selected as outgroup. All novel sequences obtained in this study were submitted to GenBank, and their accession numbers are provided in the Electronic Appendix (Table S2).

In addition, ABGD analysis was implemented on the website (https://bioinfo.mnhn.fr/abi/public/abgd/abgdweb.html), using K80, relative gap width (X = 1.5), and the remaining parameters as default values (Puillandre et al., 2012).

4.2. Species diversity

The morphological identification results showed that there are nine species of freshwater shrimp in Henan Province. Compared with the study of Wang (1989), our sampling points covered his 15 sampling points plus the main river systems and tributaries in Henan Province. Unfortunately, we have not collected and identified Macrobrachium superbum, Macrobrachium asperulum, or Macrobrachium iusulare. In order to avoid the single sampling error, we repeatedly went to the collection sites where the distributions were recorded, and the collection range was further expanded. Even so, we have not collected these species. The records indicate that the above three freshwater shrimp are mainly distributed in some provinces and waters of southern China (Li et al., 2007), and the morphological characteristics of Macrobrachium are similar, making the species difficult to identify. Therefore, we hypothesize that these species may have existed in Henan Province before, but the environmental changes of the sample sites may have proven unsuitable for these species and that they have migrated or disappeared from the province. In addition, they may never have been distributed in Henan Province, and similar morphological characteristics may have led to their incorrect identification. All in all, more samples and more direct evidence are needed to support the existence of these species in Henan Province.

At present, the classification status of a variety of freshwater shrimp has changed, indirectly hindering the effective identification of their species and the estimation of biodiversity. First, the taxonomic status of Caridina denticulata sinensis (Kemp, 1918) and Palaemon (Exopalaemon) modestus (Heller, 1862) collected by Wang has been controversial and has changed to some extent (Wang, 1989). As early as 1918, Kemp regarded the Caridina specimens collected from Taihu Lake as a new subspecies of Caridina denticulata and named it C. denticulata sinensis. Kubo separated C. denticulata from Caridina to form the genus Neocaridina in 1938. Due to the small number of species and this being based on morphological traits, the name Neocaridina has not been widely adopted. Cai confirmed the taxonomic status of the genus Neocaridina in 1996 and revised it (Cai, 1996). In this revision, Cai considered that C. davidi (Bouvier, 1904) was a subspecies of N. denticulata (N. denticulata davidi) and transferred it to the genus Neocaridina. However, Liang considered C. davidi (Bouvier, 1904), N. denticula davidi (Kubo, 1938), and N. denticula sinensis (Kemp, 1913) as synonyms of Neocaridina heteropoda heteropoda (Liang, 2002). Our molecular and morphological identification results also confirmed this point (Klotz et al., 2013; Liang, 2004). Klotz pointed out that N. denticulata sinensis reported by Englund and Cai (1999) and N. davidi reported here are conspecifics (Klotz et al., 2013). Here, we followed Klotz et al. (2013) and considered that C. davidi (Bouvier, 1904) as the senior synonym has clear priority (article 23 of the ICZN), and we continue to name it N. davidi (Klotz et al., 2013). In addition, Palaemonetes, Exopalaemon, and Coutierella have been transferred to Palaemon, and this is widely accepted (Ashelby et al., 2012). Due to the genus classification status changes, Palaemon (Exopalaemon) modestus should be renamed Palaemon modestus, and Palaemonetes sinensis should also be renamed as Palaemon sinensis.

Second, due to the failure to identify enough morphological differentiation in M. sp. “qilianensis,” and the lack of a sufficient description in the relevant references and original literature, we tentatively inferred that M. sp. “qilianensis” may be an invalid species and that it may be a synonym of Palaemon modestus. In addition, given that only one sample was obtained, and N. ikiensis and N. palmata were damaged, they cannot be effectively identified by morphology. Thus, N. ikiensis and N. palmata need to be further collected and confirmed.

In conclusion, the comprehensive results of morphological characteristics and molecular delimitation indicated that there are at least nine species of freshwater shrimp that have been morphologically identified in Henan Province.

We are grateful to the anonymous reviewers for their constructive comments. We thank Xi Wang, Hui‐hui Wu, Ru‐yao Liu, and Xue‐meng Yan for assistance with fieldwork and their help. In addition, this work was supported by the following funding: the National Natural Science Foundation of China (31872199, U2004146). Support for this study was provided by The High Performance Computing Center of Henan Normal University. We thank these funding agencies for their support.