Hostname: page-component-78c5997874-g7gxr Total loading time: 0 Render date: 2024-11-17T15:14:19.764Z Has data issue: false hasContentIssue false

First record of Diapterus brevirostris (Teleostei: Gerridae) in Atlantic European waters: a case of introduced species

Published online by Cambridge University Press:  26 July 2024

Juan Carlos Arronte*
Affiliation:
Instituto Español de Oceanografía (IEO- CISC), C.O. de Santander, Santander, Spain
Ana Antolínez
Affiliation:
Instituto Español de Oceanografía (IEO- CISC), C.O. de Santander, Santander, Spain
Rafael Bañón
Affiliation:
Grupo de Estudo do Medio Mariño (GEMM), Ribeira, Spain
José Heredia
Affiliation:
Servicio de Ordenación Pesquera, Dirección General de Pesca Marítima, Consejería de Medio Rural y Cohesión Territorial, Gijón, Spain
Alejandro de Carlos
Affiliation:
Departamento de Bioquímica, Xenética e Inmunoloxía. Facultade de Bioloxía, Universidade de Vigo, Vigo, Spain Centro de Investigación Mariña, Universidade de Vigo, Vigo, Spain
*
Corresponding author: Juan Carlos Arronte; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Diapterus brevirostris (Sauvage, 1879) is a fish of the family Gerreidae, native to the tropical and subtropical waters of the Pacific coast of America. A specimen of this species was captured off the coast of Asturias, Spain. To the best of our knowledge, this is the first record of the genus Diapterus in the North Atlantic. Given its small size (6.4 cm), it is likely that the species was present in the area for a relatively short time. Although the introduction pathway is unknown, the species' native area and the proximity of a major port to the site of capture suggest that ship's ballast water is the most likely vector of introduction.

Type
Marine Record
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press on behalf of Marine Biological Association of the United Kingdom

Introduction

In the marine context, the introduction and spread of non-native species (NIS) is not only considered to be one of the major threads to biodiversity and ecosystem functioning, but also responsible for changes in the biota and economic losses in some fisheries (Katsanevakis et al., Reference Katsanevakis, Wallentinus, Zenetos, Leppäkoski, Cinar, Oztürk, Grabowski, Golani and Cardoso2014; Öztürk, Reference Öztürk2021). According to Falk-Petersen et al. (Reference Falk-Petersen, Bøhn and Sandlund2006), the term introduction can be defined as the direct or indirect movement of an organism by human activities beyond the limits of its native geographical range into an area where it does not occur naturally. However, the terminology associated with introduced species is evolving, and terms such as acclimatised, adventive, naturalised, or immigrant species are now considered to be a subset of introduced species.

The genus Diapterus Ranzani 1842 is one of the seven genera that make up the Family Gerreidae, commonly known as mojarras (Fricke et al., Reference Fricke, Eschmeyer and Fong2024). The taxonomy of the Gerreidae is confusing and the subject of debate within the scientific community (e.g. Chen et al., Reference Chen, Ruiz-Carus and Orti2007; González-Acosta et al., Reference González-Acosta, Béarez, Álvarez-Pliego, de La Cruz-Agüero and Castro-Aguirre2007; De La Cruz-Agüero et al., Reference De La Cruz-Agüero, García-Rodríguez, De La Cruz-Agüero and Díaz Murillo2012; Chollet-Villalpando et al., Reference Chollet-Villalpando, García-Rodríguez and De La Cruz-Agüero2024). Diapterus has also been affected by these taxonomic uncertainties and, with the establishment of the validity of the short nose mojarra Diapterus brevirostris over the Peruvian mojarra D. peruvianus (González-Acosta et al., Reference González-Acosta, Béarez, Álvarez-Pliego, de La Cruz-Agüero and Castro-Aguirre2007), and the separation of D. aureolus from the genus (Vergara-Solana et al., Reference Vergara-Solana, García-Rodríguez, Tavera, de Luna and de La Cruz-Agüero2014), the genus currently comprises three species distributed throughout the tropical and subtropical seas coastal waters of both coasts of America: the Irish pompano D. auratus Ranzani 1842 and the rhombic mojarra D. rhombeus (Cuvier 1829) from the western Atlantic Ocean, while D. brevirostris (Sauvage, 1879) is distributed along the Pacific Ocean (Vergara-Solana et al., Reference Vergara-Solana, García-Rodríguez, Tavera, de Luna and de La Cruz-Agüero2014).

D. brevirostris occurs on sandy or muddy bottoms of bays, estuaries, and coastal lagoons bordered by mangroves along the tropical eastern Pacific coast from the west coast of Baja California (Bahia Magdalena, including the Gulf of California) to northern Peru (González-Acosta et al., Reference González-Acosta, Béarez, Álvarez-Pliego, de La Cruz-Agüero and Castro-Aguirre2007 and references therein) (Figure 1a). Here we document the first record of D. brevirostris in the Cantabrian Sea (northeastern Atlantic) and discuss the possible pathways for its presence in this area.

Figure 1. (A) Native distribution* of Diapterus brevirostris in the Pacific Ocean. (B) Location of the occurrence of D. brevirostris off the coast of Asturias, Spain (NE Atlantic). *Data on the occurrence of D. brevirostris in the Pacific Ocean were downloaded from the Global Biodiversity Information Facility (GBIF) (GBIF, 2023).

Material and methods

On 3 September 2021, a specimen of an unknown fish species was recorded from off the coast of Asturias, northern Spain (43° 33’ 17N – 5° 24’ 55W) (Figure 1b). The individual was collected by a recreational angler at a depth of approximately 25 m. It was regurgitated from the stomach of a captured specimen of Comber Serranus cabrilla (Linnaeus, 1758).

The fish was frozen and shipped to the Instituto Español de Oceanografía (IEO-CSIC) for identification and further analysis. It appeared that the individual had been digested by the S. cabrilla specimen shortly before its predator was captured, resulting in a slight degree of damage that allowed its morphological identification. Once in the laboratory, the specimen was identified morphologically using published identification keys and descriptions (Castro-Aguirre et al., Reference Castro-Aguirre, Espinosa-Pérez and Schmiter-Soto1999; Vergara-Solana et al., Reference Vergara-Solana, García-Rodríguez, Tavera, de Luna and de La Cruz-Agüero2014). The fish was weighed to the nearest 0.1 g, measured to the nearest 0.1 mm with a digital caliper and subsequently deposited in the marine collection of the Instituto Español de Oceanografía in Santander (IEO-COST ST3931).

To confirm the species identification, a sample of muscle tissue was collected and preserved in absolute ethanol for molecular DNA barcoding of the mitochondrial cytochrome oxidase 1 gene (COI). The DNA of the specimen was extracted from a muscle tissue sample using the E.Z.N.A. Tissue DNA Kit from Omega-Biotek, following the manufacturer's instructions. The region of the genome that serves as a barcode for molecular identification, COI-5P, was amplified using the universal primers LCO1490 and HCO2198 (Folmer et al., Reference Folmer, Black, Hoeh, Lutz and Vrijenhoek1994), following the protocol used by Hebert et al. (Reference Hebert, Cywinska, Ball and deWaard2003). The sequences of both DNA strands were obtained at the ‘Centro de Apoyo Científico y Tecnológico a la Investigación’ (CACTI, University of Vigo, Spain), by the Sanger chain termination method (Sanger et al., Reference Sanger, Nicklen and Coulson1977), using the same primers. The consensus sequence, comprising 652 nucleotides, was aligned with other sequences of the same genus. The relationships between all sequences were then represented through the construction of a Neighbour-Joining diagram (Saitou & Nei, Reference Saitou and Nei1987). The differences between the sequences were calculated as the ratio of distinct nucleotides to the total length without the application of any evolutionary model (uncorrected p-distance) (Nei & Kumar, Reference Nei and Kumar2000). To facilitate the molecular identification of the specimen captured in Asturias, sequences of the COI-5P marker of all Barcode Index Numbers (BINs) of the genus Diapterus were downloaded from the BOLD database.

The partial COI sequence data with all meta-data were registered on the Barcode of Life Database (BOLD Systems; www.boldsystems.org) as part of the project entitled ‘Unusual Atlantic Fishes’ (code UNAFI) with process ID UNAFI013-24 and deposited in GenBank (https://www.ncbi.nlm.nih.gov/genbank/) under accession number PP789894.

Results

The specimen (Figure 2) was taxonomically attributed to the genus Diapterus, as evidenced by the serrated margin of the preopercle, the smooth preorbital bone, and the rhomboid body (Vergara-Solana et al., Reference Vergara-Solana, García-Rodríguez, Tavera, de Luna and de La Cruz-Agüero2014). The individual is consistent with the description of D. brevirostris by González-Acosta et al. (Reference González-Acosta, Béarez, Álvarez-Pliego, de La Cruz-Agüero and Castro-Aguirre2007) and Vergara-Solana et al. (Reference Vergara-Solana, García-Rodríguez, Tavera, de Luna and de La Cruz-Agüero2014), and the COI results showed 100% similarity with records of D. brevirostris available in BOLD. The captured individual presented a rhomboidal and laterally compressed body, with a maximum height contained within 2.1 times the standard length. The mouth was protractile, the posterior and inferior margins of the preopercular bone were serrated, and the preorbital bone had a smooth edge. The dorsal fin was elevated at the front, with nine spines (the second being the longest) and ten soft rays. The anal fin exhibited long lobes with three spines (the second being the longest) and eight soft rays. The pectoral fins were located slightly posterior the origin of the anal fin. All the meristic and morphometric data for the specimen are presented in Table 1.

Figure 2. Diapterus brevirostris captured off the coast of Asturias coast (northeastern Spain).

Table 1. Morphometric measurements in mm and as percentage of standard length (%SL) and meristic counts recorded on the specimen of D. brevirostris captured off Asturias, Spain (northeastern Atlantic)

As the specimen was regurgitated, many features of its body colouration were lost. However, its body was silvery with yellowish anal and pelvic fins with blackish membranes.

The Neighbour-joining (NJ) analysis indicates that the sequence of the Asturias specimen in the BIN belongs to BOLD: AAM5553, which is comprised of sequences of D. brevirostris. The genetic distances between these sequences vary within the range 0–0.6% (Figure 3). This cluster is clearly distinguished from adjacent clusters, exhibiting distances to nearest neighbours of 9.6% with BOLD: AAO1630, formed by D. auratus, and 11.9% with BOLD: AAF5627, corresponding to D. rhombeus. A comparison of the 19 sequences used in the analysis revealed a barcoding gap between distances of 0.66% and 2.29%. It is noteworthy that three of the BINs comprise sequences of the species D. auratus.

Figure 3. Neighbour-Joining (NJ) tree of COI-5P sequences from Diapterus specimens. The percentage of replicate trees in which the associated taxa clustered together in the bootstrap test (1000 replicates) is shown next to the branches. The tree is drawn to scale, with branch lengths in the units of the number of base differences per site (p-distance). All ambiguous positions were removed for each sequence pair (pairwise deletion option). The analysis involved 19 nucleotide sequences and 655 nucleotide positions. The Diapterus BIN clusters are indicated. The specimen captured off the Asturias coast (northeastern Atlantic) is in bold.

Discussion

The present study provides evidence of the occurrence of D. brevirostris in the northeastern Atlantic, based on both morphological and molecular identification. This represents the first documented occurrence of the species outside their native habitat in the eastern Pacific Ocean and the genus in the eastern Atlantic. In this area, the family Gerreidae is represented by only two species with their distribution along the west African coasts, Flagfin mojarra Eucinostomus melanopterus (Bleeker, 1863) and Guinean striped mojarra Gerres nigri Günther, 1859 (Iwatsuki, Reference Iwatsuki, Carpenter and De Angelis2016).

The presence of fish species outside their native range can occur through natural mechanisms such as ocean currents (Wolff, Reference Wolff2005) or through human-induced vectors such as deliberate introductions (e.g. aquaculture, sport fishing, and ecosystem management), aquarium releases, and ship ballast water (Wolff, Reference Wolff2005; Morais & Teodósio, Reference Morais and Teodósio2016).

The small size (6.4 cm) and weight (less than 3 gr) of the D. brevirostris specimen, rules out the possibility that it entered the North Atlantic through the Panama Canal and then reached the northeastern coast of Spain by natural means. Consequently, the presence of the species is likely to be the result of human-mediated translocation. The species is not known to be farmed or part of the aquarium trade industry, which makes ballast water the most likely vector of introduction into the Cantabrian Sea. In addition, the specimen was captured near the major commercial port of Gijón, where not only have non-native species been previously n recorded (Cabal et al., Reference Cabal, Millán and Arronte2006), but also where merchant vessels from the species' range had docked in the weeks prior to the capture (personal communication, Port Authority of Gijón). Ballast water from ships is a significant transport vector of non-native and invasive aquatic species (Gollasch et al., Reference Gollasch, MacDonald, Belson, Botnen, Christensen, Hamer, Houvenaghel, Jelmert, Lucas, Masson, McCollin, Olenin, Persson, Wallentinus, Wetsteyn, Wittling, Leppäkoski, Gollasch and Olenin2002). In the eastern Atlantic, ballast water has been identified out as a mechanism for the arrival of several native fishes from the western Atlantic, including Micropogonias undulatus (Linnaeus, 1766) (Stevens et al., Reference Stevens, Rappé, Maes, Van Asten and Ollevier2004), Trinectes maculatus (Bloch & Schneider, 1801) (Wolff, Reference Wolff2005) and Cynoscion regalis (Bloch and Schneider, 1801) (Morais & Teodósio, Reference Morais and Teodósio2016; Bañón et al., Reference Bañón, Barros-García, Gómez, Berta-Ríos and de Carlos2018).

The introduction of numerous Indo-Pacific fish species through the Suez Canal (Lessepsian migration) is a well-documented phenomenon in the Mediterranean (Golani et al., Reference Golani, Orsi-Relini, Massuti and Quignard2002). In European Atlantic waters, the occurrence of fish species with an Indo-Pacific origin is very rare. Prior to the present record, only the presence of Sebastes schlegelii Hilgendorf, 1880 in Dutch coastal waters (Kai & Soes, Reference Kai and Soes2009) and Sebastiscus marmoratus (Cuvier, 1829) in Norwegian waters (Hansen & Karlsbakk, Reference Hansen and Karlsbak2018) have been reported. However, in contrast to these two records, our individual is less than one year old (Gallardo-Cabello et al., Reference Gallardo-Cabello, Espino-Barr, Cabral-Solís, García-Boa and Puente-Gómez2014) and immature (Gallardo-Cabello et al., Reference Gallardo-Cabello, Espino-Barr, Puente-Gómez, García-Boa and Cabral-Solís2015). In view of these two factors, and the exceptional occurrence of the species in the Cantabrian Sea, it is highly unlikely that an established population will be present in the area in the future.

Non-native marine fishes can have negative ecological impacts through several mechanisms, including habitat and/or food web alteration, competition, and predation on native species, vectoring of parasites and pathogens, and genetic impacts on native species (Arndt et al., Reference Arndt, Givan, Edelist, Sonin and Belmaker2018). However, given the medium size of the species (maximum size of 38 cm TL) and its carnivorous feeding habits based mainly on benthic organisms such as copepods, ostracods, polychaetes, and molluscs (González-Acosta et al., Reference González-Acosta, Béarez, Álvarez-Pliego, de La Cruz-Agüero and Castro-Aguirre2007), it is likely that its impact on the ecosystem would be low in the hypothetical case of establishment in the temperate northeastern Atlantic.

In addition to reporting the first record for D. brevirostris in the eastern Atlantic, this study also highlights the importance of motivating the public to contribute to knowledge, a non-scientific tool that has proven its usefulness in detecting non-native species (Azzurro et al., Reference Azzurro, Bolognini, Dragičević, Drakulović, Dulčić, Fanelli and Marković2018; Encarnação et al., Reference Encarnação, Baptista, Teodósio and Morais2021).

Data

The authors confirm that the data supporting the findings of this study are available within the article.

Acknowledgements

The authors thank Carlos Rojo Cófreces for providing the specimen of D. brevirostris. We also thank Ana de la Torriente (IEO-CSIC) for her help with the map.

Author contributions

AdC conducted lab work and performed the molecular analysis. AA performed morphological analyses. JH and AA contributed to manuscript preparation. The manuscript was written by JCA with significant contributions by RB and AdC. All authors commented on and approved the final version of the manuscript.

Financial support

This research received no specific grant from any funding agency, commercial or not-for- profit sectors.

Competing interests

None.

Ethical standards

Not applicable.

References

Arndt, E, Givan, O, Edelist, D, Sonin, O and Belmaker, J (2018) Shifts in eastern Mediterranean fish communities: abundance changes, trait overlap, and possible competition between native and non-native species. Fishes 3, 19.10.3390/fishes3020019CrossRefGoogle Scholar
Azzurro, E, Bolognini, L, Dragičević, B, Drakulović, D, Dulčić, J, Fanelli, E and Marković, O (2018) Detecting the occurrence of indigenous and non-indigenous megafauna through fishermen knowledge: a complementary tool to coastal and port surveys. Marine Pollution Bulletin 147, 229236.10.1016/j.marpolbul.2018.01.016CrossRefGoogle ScholarPubMed
Bañón, R, Barros-García, D, Gómez, D, Berta-Ríos, M and de Carlos, A (2018) Evidence of a rapid colonization of the Atlantic European waters by the non-native weakfish Cynoscion regalis (Perciformes: Sciaenidae). Marine Biodiversity 48, 22372242.10.1007/s12526-017-0738-8CrossRefGoogle Scholar
Cabal, JJ, Millán, AP and Arronte, JC (2006) A new record of Callinectes sapidus Rathbun, 1896 (Crustacea: Decapoda: Brachyura) from the Cantabrian Sea, Bay of Biscay, Spain. Aquatic Invasions 1, 186187.10.3391/ai.2006.1.3.14CrossRefGoogle Scholar
Castro-Aguirre, JL, Espinosa-Pérez, HS and Schmiter-Soto, JJ (1999) Ictiofauna Estuarino-Lagunar y Vicaria de México. México: Ed. Limusa-Noriega.Google Scholar
Chen, WJ, Ruiz-Carus, R and Orti, G (2007) Relationships among four genera of mojarras (Teleostei: Perciformes: Gerreidae) from the western Atlantic and their tentative placement among percomorph fishes. Journal of Fish Biology 70(Supplement B), 202218.10.1111/j.1095-8649.2007.01395.xCrossRefGoogle Scholar
Chollet-Villalpando, JG, García-Rodríguez, FJ and De La Cruz-Agüero, J (2024) Character variation in separate body regions of Gerreidae (Osteichthyes: Teleostei) fishes inferred from geometric morphometrics. Journal of Fish Biology 104, 723736.10.1111/jfb.15615CrossRefGoogle ScholarPubMed
De La Cruz-Agüero, J, García-Rodríguez, FJ, De La Cruz-Agüero, G and Díaz Murillo, BP (2012). Identification of gerreid species (Actinopterygii: Perciformes: Gerreidae) from the Pacific coast of Mexico based on sagittal otolith morphology analysis. Acta Ichthyologica et Piscatoria 42, 297306.10.3750/AIP2012.42.4.03CrossRefGoogle Scholar
Encarnação, J, Baptista, V, Teodósio, MA and Morais, P (2021) Low-cost citizen science effectively monitors the rapid expansion of a marine invasive species. Frontiers in Environmental Science 9, 752705.10.3389/fenvs.2021.752705CrossRefGoogle Scholar
Falk-Petersen, J, Bøhn, T and Sandlund, OT (2006) On the numerous concepts in invasion biology. Biological Invasions 8, 14091424.10.1007/s10530-005-0710-6CrossRefGoogle Scholar
Folmer, O, Black, M, Hoeh, W, Lutz, R and Vrijenhoek, R (1994) DNA primers for the amplification of mitochondrial cytochrome c oxidase subunit I from diverse metazoan invertebrates. Molecular Marine Biology and Biotechnology 3, 294299.Google ScholarPubMed
Fricke, R, Eschmeyer, WN and Fong, JD (2024) Eschmeyer's Catalog of Fishes: Genera/Species by Family/Subfamily. Available at http://researcharchive.calacademy.org/research/ichthyology/catalog/SpeciesByFamily.asp. Electronic version accessed 7 May 2024.Google Scholar
Gallardo-Cabello, M, Espino-Barr, E, Cabral-Solís, EG, García-Boa, A and Puente-Gómez, M (2014) Growth of the shortnose mojarra Diapterus brevirostris (Perciformes: Gerreidae) in Central Mexican Pacific. Avances en Investigación Agropecuaria 18, 2740.Google Scholar
Gallardo-Cabello, M, Espino-Barr, E, Puente-Gómez, M, García-Boa, A and Cabral-Solís, EG (2015) Reproduction of Diapterus brevirostris (Perciformes: Gerreidae) in the Mexican Pacific coast. Global Journal of Fisheries and Aquaculture 3, 221229.Google Scholar
GBIF (2023) GBIF Occurrence Download. https://doi.org/10.15468/dl.efas9y (Accessed on 26 July 2023).CrossRefGoogle Scholar
Golani, D, Orsi-Relini, L, Massuti, E and Quignard, JP (2002) CIESM atlas of Exotic Species in the Mediterranean. Vol. 1. Fishes. Monaco: CIESM Publications.Google Scholar
Gollasch, S, MacDonald, E, Belson, S, Botnen, H, Christensen, JT, Hamer, JP, Houvenaghel, G, Jelmert, A, Lucas, I, Masson, D, McCollin, T, Olenin, S, Persson, A, Wallentinus, I, Wetsteyn, LPMJ and Wittling, T (2002) Life in ballast tanks. In Leppäkoski, E., Gollasch, S. and Olenin, S. (eds.) Invasive Aquatic Species of Europe: Distribution, Impacts and Management. Dordrecht: Kluwer, pp. 217231.10.1007/978-94-015-9956-6_23CrossRefGoogle Scholar
González-Acosta, AF, Béarez, P, Álvarez-Pliego, N, de La Cruz-Agüero, J and Castro-Aguirre, JL (2007) On the taxonomic status of Diapterus peruvianus (Cuvier, 1830) and rein- statement of Diapterus brevirostris (Sauvage, 1879) (Teleostei: Gerreidae). Cybium 31, 369377.Google Scholar
Hansen, H and Karlsbak, E (2018) Pacific false kelpfish, Sebastiscus marmoratus (Cuvier, 1829) (Scorpaeniformes, Sebastidae) found in Norwegian waters. BioInvasions Records 7, 7378.10.3391/bir.2018.7.1.11CrossRefGoogle Scholar
Hebert, PDN, Cywinska, A, Ball, SL and deWaard, JR (2003) Biological identifications through DNA barcodes. Proceedings of the Royal Society London 270, 313321.10.1098/rspb.2002.2218CrossRefGoogle ScholarPubMed
Iwatsuki, Y (2016) Gerreidae. In Carpenter, KE and De Angelis, N (eds), The Living Marine Resources of the Eastern Central Atlantic, vol. 4. FAO: Rome, pp. 25462550.Google Scholar
Kai, Y and Soes, DM (2009) A record of Sebastes schlegelii Hilgendorf, 1880 from Dutch coastal waters. Aquatic Invasions 4, 417419.10.3391/ai.2009.4.2.23CrossRefGoogle Scholar
Katsanevakis, S, Wallentinus, I, Zenetos, A, Leppäkoski, E, Cinar, M, Oztürk, B, Grabowski, M, Golani, D and Cardoso, A (2014) Impacts of invasive alien marine species on ecosystem services and biodiversity: a pan-European review. Aquatic Invasions 9, 391423.10.3391/ai.2014.9.4.01CrossRefGoogle Scholar
Morais, P and Teodósio, MA (2016) The transatlantic introduction of weakfish Cynoscion regalis (Bloch & Schneider, 1801) (Sciaenidae, Pisces) into Europe. Bioinvasions Records 5, 259265.10.3391/bir.2016.5.4.11CrossRefGoogle Scholar
Nei, M and Kumar, S (2000) Molecular Evolution and Phylogenetics. New York: Oxford University Press.10.1093/oso/9780195135848.001.0001CrossRefGoogle Scholar
Öztürk, B (2021) Non-indigenous species in the Mediterranean and the Black Sea. Studies and Reviews No. 87. (General Fisheries Commission for the Mediterranean). Rome: FAO.Google Scholar
Saitou, N and Nei, M (1987) The neighbor-joining method: a new method for reconstructing phylogenetic trees. Molecular Biology and Evolution 4, 406425.Google Scholar
Sanger, F, Nicklen, S and Coulson, AR (1977) DNA sequencing with chain-terminating inhibitors. Proceedings of the National Academy of Sciences USA 74, 54635467.10.1073/pnas.74.12.5463CrossRefGoogle ScholarPubMed
Stevens, M, Rappé, G, Maes, J, Van Asten, B and Ollevier, F (2004) Micropogonias undulatus (L.), another exotic arrival in European waters. Journal of Fish Biology 64, 11431146.10.1111/j.1095-8649.2004.00369.xCrossRefGoogle Scholar
Vergara-Solana, FJ, García-Rodríguez, FJ, Tavera, JJ, de Luna, E and de La Cruz-Agüero, J (2014) Molecular and morphometric systematics of Diapterus (Perciformes, Gerreidae). Zoologica Scripta 43, 338350.10.1111/zsc.12054CrossRefGoogle Scholar
Wolff, WJ (2005) Non-indigenous marine and estuarine species in The Netherlands. Zoologische Medelingen Leiden 79, 1116.Google Scholar
Figure 0

Figure 1. (A) Native distribution* of Diapterus brevirostris in the Pacific Ocean. (B) Location of the occurrence of D. brevirostris off the coast of Asturias, Spain (NE Atlantic). *Data on the occurrence of D. brevirostris in the Pacific Ocean were downloaded from the Global Biodiversity Information Facility (GBIF) (GBIF, 2023).

Figure 1

Figure 2. Diapterus brevirostris captured off the coast of Asturias coast (northeastern Spain).

Figure 2

Table 1. Morphometric measurements in mm and as percentage of standard length (%SL) and meristic counts recorded on the specimen of D. brevirostris captured off Asturias, Spain (northeastern Atlantic)

Figure 3

Figure 3. Neighbour-Joining (NJ) tree of COI-5P sequences from Diapterus specimens. The percentage of replicate trees in which the associated taxa clustered together in the bootstrap test (1000 replicates) is shown next to the branches. The tree is drawn to scale, with branch lengths in the units of the number of base differences per site (p-distance). All ambiguous positions were removed for each sequence pair (pairwise deletion option). The analysis involved 19 nucleotide sequences and 655 nucleotide positions. The Diapterus BIN clusters are indicated. The specimen captured off the Asturias coast (northeastern Atlantic) is in bold.