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Occurrence of the hydromedusa Moerisia cf. inkermanica (Hydrozoa, Moerisiidae) in the ballast water of oil tankers in the Gulf of Mexico

Published online by Cambridge University Press:  26 July 2024

José María Ahuatzin-Hernández*
Affiliation:
Departamento de Recursos del Mar, CINVESTAV-IPN, Unidad Mérida, Antigua carretera a Progreso, Km 6, 97310 Yucatán, A.P., México
Uriel Ordóñez-López
Affiliation:
Departamento de Recursos del Mar, CINVESTAV-IPN, Unidad Mérida, Antigua carretera a Progreso, Km 6, 97310 Yucatán, A.P., México
Miguel Herrera-Rodríguez
Affiliation:
PEMEX, Exploración y Producción, Región Marina Noreste (PEP/RMNE), Estudios Ambientales, Cd Del Carmen, 24130 Campeche, C.P., México
Miguel A. Olvera-Novoa
Affiliation:
Departamento de Recursos del Mar, CINVESTAV-IPN, Unidad Mérida, Antigua carretera a Progreso, Km 6, 97310 Yucatán, A.P., México
*
Corresponding author: José María Ahuatzin-Hernández; Email: [email protected]
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Abstract

The introduction of non-native species is a constant concern around the world since it represents one of the main threats to biodiversity, impacting negatively on native populations, some of them with commercial importance. Hence, monitoring these introductions is fundamental to the management and conservation of the biodiversity of a region. Herein, we report the presence of Moerisia cf. inkermanica in the ballast water of oil tankers loaded at the Cayo Arcas oil terminal. The taxonomy of Moerisia members is uncertain due to the lack of comprehensive morphological descriptions and the few molecular data available. So, we provide a detailed morphological comparison among its congeners. The taxonomic identity of the specimens was determined based on the length of the perradial lobes of the manubrium, the number of tentacles, and the features of their nematocyst rings. Some Moerisids are considered invasive in different localities of the world. However, this genus had not been reported in coastal ecosystems of the Gulf of Mexico over the years until now. Sampled tankers came from different ports of the region, mainly from the northern Gulf of Mexico. Therefore, we encourage systematic monitoring of these ecosystems to recognize the establishment of this species as invasive in the region, know its population dynamics over time, and evaluate the possible ecological impacts that could exert on native populations.

Type
Marine Record
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press on behalf of Marine Biological Association of the United Kingdom

Introduction

The Gulf of Mexico is a semi-closed basin of the Atlantic Ocean that provides diverse ecosystem services related to its biodiversity, biological productivity, and geological features (Fautin et al., Reference Fautin, Dalton, Incze, Leong, Pautzke, Rosenberg, Sandifer, Sedberry, Tunnell, Abbott, Brainard, Brodeur, Eldredge, Feldman, Moretzsohn, Vroom, Wainstein and Wolff2010). Among the ecosystem services that generate greater economic benefits are oil extraction and tourism (Shepard et al., Reference Shepard, Valentine, D'Elia, Yoskowitz and Dismukes2013). Hence, maritime transport has been constant in the Gulf of Mexico throughout history (Botello et al., Reference Botello, Susana-Villanueva, Gilberto-Diaz and Ware1997), impacting some ecosystems due to the introduction of non-native species (Graham et al., Reference Graham, Martin, Felder, Asper, Perry and Pederson2003; Brockinton et al., Reference Brockinton, Peterson, Wang and Grant2022). In the last few years, the presence of some non-native invertebrates in the Gulf of Mexico has been reported; some examples include Phyllorhiza punctata (Graham et al., Reference Graham, Martin, Felder, Asper, Perry and Pederson2003; Ocaña-Luna et al., Reference Ocaña-Luna, Sánchez-Ramírez and Aguilar-Durán2010), Blackfordia virginica (Ocaña-Luna et al., Reference Ocaña-Luna, Sánchez-Ramírez and Islas-García2021), Tubastraea coccinea (Fenner and Banks, Reference Fenner and Banks2004; Derouen et al., Reference Derouen, Peterson, Wang and Grant2020), Penaeus monodon (Wakida-Kusunoki et al., Reference Wakida-Kusunoki, Rojas-González, González-Cruz, Amador-del Ángel, Sánchez-Cruz and López-Tellez2013), and the bryozoans Hippoporina indica, Arbopercula bengalensis, Sinoflustra annae, and Celleporaria pilaefera (McCann et al., Reference McCann, Hitchcock, Winston and Ruiz2007). Unfortunately, few studies have evaluated their potential economic and ecological impact in the region (Graham et al., Reference Graham, Martin, Felder, Asper, Perry and Pederson2003), so the status of their populations and their establishment as invasive species is uncertain.

The Hydromedusae of Moerisia Boulenger, 1908 distributes in tropical and template regions of the world, including continental water bodies (GBIF, 2024). Little is known about their taxonomy due to the lack of reports with detailed morphological descriptions and the few molecular data associated with these reports (Restaino et al., Reference Restaino, Bologna, Gaynor, Buchanan and Bilinski2018), causing the taxonomic boundaries of the group to be uncertain (Rees, Reference Rees1958; Calder, Reference Calder2010; Nawrocki et al., Reference Nawrocki, Schuchert and Cartwright2010). This genus includes seven valid species (Schuchert, Reference Schuchert2024), of which M. inkermanica Paltschikowa-Ostroumowa, Reference Paltschikowa-Ostroumowa1925 and M. lyonsi Boulenger, 1908 are more frequently reported in the literature (e.g., Purcell et al., Reference Purcell, Båmstedt and Båmstedt1999; Ma and Purcell, Reference Ma and Purcell2005; Nascimento et al., Reference Nascimento, Nogueira, Viana and Bersano2019). M. inkermanica was described for the first time in the Bay of Sevastopol, Black Sea (Paltschikowa-Ostroumowa, Reference Paltschikowa-Ostroumowa1925). Since then, it has been recorded in several localities around the world, mainly in the Atlantic Ocean (see Schuchert, Reference Schuchert2010; Nogueira, Reference Nogueira2012; Restaino et al., Reference Restaino, Bologna, Gaynor, Buchanan and Bilinski2018). The nearest record to the Gulf of Mexico was in Barnegat Bay, New Jersey (as Moerisia sp. Restaino et al., Reference Restaino, Bologna, Gaynor, Buchanan and Bilinski2018). This species is considered invasive in some localities (e.g., Nogueira, Reference Nogueira2012; Killi et al., Reference Killi, Tarkan, Kozic, Copp, Davison and Vilizzi2020), so having a record of its presence in a new region is fundamental to knowing the possible impacts that it could generate on the native biodiversity.

Reports about invasive hydrozoans are frequent around the world (e.g., Gonionemus vertens, Blackfordia virginica, Cordylophora caspia; Bardi & Marques, Reference Bardi and Marques2009; Folino-Rorem et al., Reference Folino-Rorem, Darling and D'Ausilio2009; Marchessaux et al., Reference Marchessaux, Gadreaud, Martin-Garin, Thiéry, Ourgaud, Belloni and Thibault2017). These reports are of importance since hydrozoans are key consumers of zooplankton, and under certain environmental conditions, they can generate massive local aggregations with high abundance (blooms), negatively impacting native populations, some with commercial importance (Rees and Gershwin, Reference Rees and Gershwin2000). Thus, identifying the invasion pathways, vectors, and source localities is key to understanding their ecological impact and conducting correct management (Reusch et al., Reference Reusch, Bolte, Sparwel, Moss and Javidpour2010). B. virginica and C. caspia are the only non-native hydrozoans recorded in the Gulf of Mexico, yet their invasion monitoring in coastal zones of the Gulf has been scarce (Rioja, Reference Rioja1959; López-Ochoterena and Madrazo-Garibay, Reference López-Ochoterena and Madrazo-Garibay1989; Álvarez-Silva et al., Reference Álvarez-Silva, Gómez-Aguirre and Miranda-Arce2003; Pruski and Miglietta, Reference Pruski and Miglietta2019; Ocaña-Luna et al., Reference Ocaña-Luna, Sánchez-Ramírez and Islas-García2021). Moreover, other unrecorded non-native species likely exist in this region because of the constant maritime transport, the influence of ocean currents, and the scarcity of studies about coastal hydrozoans. Here, we report the occurrence of M. cf. inkermanica in the ballast water of oil tankers loaded at the Cayo Arcas oil terminal, giving a comprehensive morphological description through its comparison with its congeners.

Materials and methods

Zooplanktonic samples were obtained from 30 tankers (three tanks per tanker) loaded at the Cayo Arcas oil terminal between 18 June and 6 July 2005 (the Cayo Arcas oil terminal is used as a port for the tankers loading oil for exportation; Figure 1) conducting vertical trawls from the bottom to the surface of each tank (90 tanks) using a conical net of 30 cm in diameter and 300 μm of clear mesh. Sampling was initially intended to collect as many zooplanktonic groups as possible for morphological analyses, so the samples were fixed in a 10% formalin solution buffered with sodium borate. Then, the samples were analysed in the laboratory, sorting the specimens of Moerisia from the rest of the material. Standard measurements were recorded (i.e., the width and height of the umbrella and number of tentacles) of the best-preserved specimens (n = 29). Four specimens were deposited in the Regional collection of ‘Cnidarios del Golfo de México y Mar Caribe Mexicano’, based at the Universidad Nacional Autónoma de México, Facultad de Ciencias, Unidad Multidisciplinaria de Docencia e Investigación-Sisal, Yucatán (Catalogue numbers for two vials with three and one specimens: YUC-CC-254-11-001660, YUC-CC-254-11-001661). For each tanker, the port of origin was recorded. The depth of the tanks ranged between 1.7 and 20 m (8 m on average). Temperature (°C) and salinity (ups) were recorded in each tank with a multiparametric YSI-85 (±0.01) (Table 1). Additionally, we surveyed the available genetic data in GenBank (Clark et al., Reference Clark, Karsch-Mizrachi, Lipman, Ostell and Sayers2016) using the term ‘Moerisia’, assessing the locality where the samples were collected and the barcode marker used in order to provide a thorough summary of the available information (morphological and molecular) among the species of the genus.

Figure 1. Locations from where the tankers set sailed towards the Cayo Arcas oil terminal (star). Green dots indicate the locations from where the tankers transporting specimens of Moerisia cf. inkermanica Paltschikowa-Ostroumowa, Reference Paltschikowa-Ostroumowa1925 set sailed.

Table 1. Physicochemical features of the ballast water and number of medusae recorded on each tanker. The ID corresponds to each tanker.

Results

SYSTEMATICS (according to Schuchert, Reference Schuchert2024)
Class HYDROZOA Owen, 1843
Subclass HYDROIDOLINA Collins, 2000
Order ANTHOATHECATA Cornelius, 1992
Suborder CAPITATA Kühn, 1913 (sensu stricto)
Family MOERISIIDAE Poche, 1914
Moerisia cf. inkermanica Paltschikowa-Ostroumowa, Reference Paltschikowa-Ostroumowa1925 (Figure 2)

Diagnosis

Moerisid with less than 32 but more than four moniliform tentacles, with rings of nematocysts arranged regularly on tentacles, with a terminal knob; manubrium short, cylindrical, lacking lips, with a quadrangular base and four long perradial lobes, with their distal parts swollen and pendant; gonads surrounding the manubrium and continuing over the perradial lobes.

Figure 2. Moerisia cf. inkermanica Paltschikowa-Ostroumowa, Reference Paltschikowa-Ostroumowa1925. (A) Complete view of mature specimens; (B) Lateral view of the manubrium; (C) Aboral view of the manubrium and perradial lobes; (D-E) Umbrella margin indicating tentacles at different development stages; (F) Oval clasping bulbs; (G) Moniliform tentacle indicating the terminal nematocysts knob; (H) Desmonemes; (I) Stenoteles.

Description

Medusa with an umbrella slightly wider than high, 3.25 mm width (2 ± 4.5 mm, SD = 0.70), 3.06 mm height (2 ± 4.5 mm, SD = 0.57); mesoglea thick; manubrium slender, not extending beyond the half of the subumbrellar cavity, with a narrow mouth beset with nematocysts, and with appearance of four folded lips; the base of the manubrium is small and quadrangular, with four long perradial lobes, extending nearly to the umbrella margin in the most mature specimens, with their distal parts swollen and pendant; the proximal part of the lobes is divided longitudinally by a median groove that narrows in its distal part; gonads located on the manubrium, continuing over the perradial lobes; four thin radial canals; margin of umbrella simple, lacking statocysts, and with a marginal ring narrow; in some specimens, the presence of short tentacles-like or vesicles-like structures, arising directly from the umbrella margin were observed; velum thin, covering 1/3 of the subumbrellar cavity; marginal bulbs oval, slightly enlarged, tapering, and clasping the umbrella margin; 15–24 (usually 16) hollow tentacles, moniliform, with numerous nematocyst rings regularly arranged, bearing a terminal knob. Cnidome composed of stenoteles of two size classes and desmonemes; stenoteles of class 1 in the tentacles: 7–8 × 8–10 μm, stenoteles of class 2 in the mouth: 6–9 × 7–11 μm; desmonemes of tentacles: 4–5 × 5–7 μm; scarce desmonemes in the mouth: 4–5 μm.

Habitat

M. inkermanica usually inhabits brackish waters of shallow depths (Schuchert, Reference Schuchert2010). Nevertheless, its wide distribution suggests good adaptability to physicochemical variations, reporting it in estuaries (Nascimento et al., Reference Nascimento, Nogueira, Viana and Bersano2019), lakes (Restaino et al., Reference Restaino, Bologna, Gaynor, Buchanan and Bilinski2018), and marine environments (Killi et al., Reference Killi, Tarkan, Kozic, Copp, Davison and Vilizzi2020) around the world. The polyps can tolerate 5–40 psu (%) salinity and temperatures from 0–30°C. They grow on reeds, pilings, and among polychaete tubes (Schuchert, Reference Schuchert, Crothers and Hayward2012).

Remarks

The presence of ocelli is a diagnostic character at the family level (Bouillon et al., Reference Bouillon, Medel, Pagés, Gili, Boero and Gravili2004; Schuchert, Reference Schuchert2010). However, ocelli were not observed in the analysed specimens. We attribute the absence of ocelli to the deterioration of the specimens due to the age of the samples and the preservation method. In addition, the shape of the bulbs varied among the specimens, which can also be attributed to the preservation method. The length of the perradial lobes varied among the analysed specimens, likely due to the different development stages. Kramp (Reference Kramp1938) mentioned the presence of statocysts in the umbrella margin of M. inkermanica, whereas Valkanov (Reference Valkanov1953) states that Kramp's interpretation corresponds to nematocyst capsules (Schuchert, Reference Schuchert2010). We observed similar structures to the previously described, concluding that they are marginal tentacles with different developmental stages (Figure 2d, e).

Discussion

The morphological characteristics of the specimens analysed in this work match those reported for M. inkermanica (Kramp, Reference Kramp1959, Reference Kramp1961; Bouillon et al., Reference Bouillon, Medel, Pagés, Gili, Boero and Gravili2004), except the cnidome reported by Schuchert (Reference Schuchert2010), which indicated four types of nematocysts. Due to the scarcity of morphological and molecular information for the members of Moerisia (Tables 2 and 3), we decided to tentatively recognize our specimens as M. cf. inkermanica. The variation in the cnidome could be considered a diagnostic character for discriminating among the species of Moerisia; yet, this information is poorly described for some species, so taxonomic studies describing this aspect are fundamental to improving the knowledge about the taxonomy of this group. The number of marginal tentacles and the length of the perradial lobes of the manubrium are the main characteristics differentiating among the medusae of Moerisia (Bouillon et al., Reference Bouillon, Medel, Pagés, Gili, Boero and Gravili2004; Schuchert, Reference Schuchert2010; Jankowski and Anokhin, Reference Jankowski, Anokhin, Damborenea, Rogers and Thorp2019). In this sense, M. lyonsi is distinguished from M. inkermanica by the number of tentacles and their prominent nematocyst clusters (Kramp, Reference Kramp1961; Bouillon et al., Reference Bouillon, Medel, Pagés, Gili, Boero and Gravili2004; Jankowski and Anokhin, Reference Jankowski, Anokhin, Damborenea, Rogers and Thorp2019). Likewise, the polyp of M. lyonsi lacks podocysts (pedal disc), whereas that of M. inkermanica presents these structures (Bouillon et al., Reference Bouillon, Medel, Pagés, Gili, Boero and Gravili2004; Jankowski and Anokhin, Reference Jankowski, Anokhin, Damborenea, Rogers and Thorp2019). M. lyonsi is reported from Egypt (type locality) and in rivers from Virginia, U.S.A. (Calder and Burrell, Reference Calder and Burrell1967).

Table 2. Comparison of the morphological diagnostic features of the valid species within Moerisia Boulenger, 1908

Table 3. GenBank accession numbers for the specimens of Moerisia Boulenger, 1908 with molecular data and their locality

M. carine Bouillon, Reference Bouillon1978 can be differentiated from M. inkermanica by its short perradial lobes, its marginal tentacles of different sizes (up to 16), and its mouth with well-defined lips and cnidome (Bouillon, Reference Bouillon1978). Despite the perradial lobes of the specimens analysed in this study varied in length, no specimens with short lobes as described in M. carine were observed (Bouillon et al., Reference Bouillon, Medel, Pagés, Gili, Boero and Gravili2004), except a juvenile with four tentacles. The polyp of M. carine is unknown, so a comprehensive morphological comparison with its congeners is not possible. This species is distributed in Papua New Guinea (type locality) and the Eastern Mediterranean (Schuchert, Reference Schuchert2010).

The medusa of M. horii (Uchida and Uchida, Reference Uchida and Uchida1929) resembles that of M. inkermanica (Uchida and Nagao, Reference Uchida and Nagao1959), making it hard to recognize reliable morphological characteristics to discriminate between these species. Their main morphological differences are in the polyp stage. The polyp of M. horii is smaller, usually with more than 12 tentacles and up to 10 podocysts (Uchida and Nagao, Reference Uchida and Nagao1959; Calder, Reference Calder2010). In addition, three types of nematocysts are reported in M. horii, i.e., stenoteles, basitrichous isorhizas, and desmonemes, whereas the specimens of this study only had stenoteles and desmonemes, and those analysed by Schuchert (Reference Schuchert2010) presented two additional types, i.e., mastigophores and haplonemes?.

Three species of Moerisia are hard to differentiate among their congeners due to their incipient morphological descriptions, the scarcity of records, and the lack of knowledge about their polyp or medusa stages, i.e., M. pallasi (Derzhavin, Reference Derzhavin1912), M. gemmata (Ritchie, Reference Ritchie1915), and M. gangetica Kramp, 1958. Morphological differences between M. pallasi and M. inkermanica are not evident in the medusa stage (Kramp, Reference Kramp1961; Schuchert, Reference Schuchert2010). Unfortunately, since its first description in the Caspian Sea (Derzhavin, Reference Derzhavin1912), the morphological descriptions of M. pallasi have been scarce (e.g., Kramp, Reference Kramp1961), making it difficult to recognize its taxonomic boundaries. The polyp of M. pallasi is smaller than that of M. inkermanica and lacks podocysts, resembling that of M. lyonsi. However, the polyp of M. pallasi presents a greater number of tentacles (Derzhavin, Reference Derzhavin1912; Bouillon et al., Reference Bouillon, Medel, Pagés, Gili, Boero and Gravili2004). M. gemmata was described based on the polyp stage, which is smaller than that of M. inkermanica and has up to two podocysts and two types of nematocysts, although both possess the same number of tentacles (Ritchie, Reference Ritchie1915). The medusa of M. gemmata is unknown, so comprehensive morphological discrimination is complicated. M. gangetica was described and differentiated from M. lyonsi based on geographical grounds (Kramp, Reference Kramp1955). This species, however, is reported in nearby locations where M. inkermanica occurs, presenting similar characteristics in the medusa stage (Kramp, Reference Kramp1955). Moreover, the polyp stage of M. gangetica is unknown, making reliable morphological differentiation impossible. These three species have been suggested as conspecific of some of their congeners (Rees and Thursfield, Reference Rees and Thursfield1965; Schuchert, Reference Schuchert2010); however, this must be addressed with integrative approaches, considering morphological and molecular data of the species from their different type localities. Molecular data regarding Moerisids is scarce, and the available information is related to only two nominal species (M. inkermanica and M. lyonsi) coming from the USA, Brazil, and China. M. inkermanica is the best molecularly known species, although there exist specimens with no specific assignation, which could suggest other undescribed species (Table 3).

Since its first description from the bay of Sevastopol in the Black Sea, M. inkermanica has been reported in the Netherlands (Saraber, Reference Saraber1962), the Mediterranean Sea (Schuchert, Reference Schuchert2010; Killi et al., Reference Killi, Tarkan, Kozic, Copp, Davison and Vilizzi2020), India (Kramp, Reference Kramp1955), France (Bouillon et al., Reference Bouillon, Bazin and Cleret1969), South Africa (Millard, Reference Millard1975) and in different localities from Brazil (e.g., Nogueira and Oliveira, Reference Nogueira and Oliveira2006; Nascimento et al., Reference Nascimento, Nogueira, Viana and Bersano2019; Teixeira-Amaral et al., Reference Teixeira-Amaral, de Lemos, Muxagata and Nagata2021). Some works hypothesized that its introduction was through maritime transport (e.g., Saraber, Reference Saraber1962; Nascimento et al., Reference Nascimento, Nogueira, Viana and Bersano2019). Here, we proved this hypothesis for the Gulf of Mexico since the analysed specimens came from the ballast water of oil tankers. Hence, we encourage attention to the application of protocols that regulate the management of this type of water since other non-native species could be introduced. The presence of juvenile specimens in our samples suggests a budding process, which might explain the prevalence of the species after water exchange since the polyps can fixed on the walls of the tanks. Only the tankers coming from the ports of Baytown, Houston, Sunoil Nederland, Port Arthur (TX), Lake St. Charles (LA), and Pascagoula (MS) transported specimens of M. cf. inkermanica on their ballast water (Figure 1). Nevertheless, the presence of this species in other ports is not ruled out since we only sampled three tanks per tanker.

Studies monitoring hydrozoan diversity in the Gulf of Mexico are fragmentary. In the southern Gulf, diverse studies have been conducted since the collection of the specimens of this work (2005) reporting different hydrozoan species in coastal ecosystems but not reporting to M. inkermanica (e.g., Cortés-Lacomba et al., Reference Cortés-Lacomba, Álvarez-Silva and Gutiérrez-Mendieta2013; Gutiérrez-Aguirre et al., Reference Gutiérrez-Aguirre, Delgado-Blas and Cervantes-Martínez2015; Ahuatzin-Hernández et al., Reference Ahuatzin-Hernández, Canul-Cabrera, Eúan-Canul and León-Deniz2020; López-Torres et al., Reference López-Torres, Mendoza-Becerril and de la Cruz-Francisco2023). In the northern Gulf, fewer studies have been carried out in this field, focusing on phylogenetic aspects (e.g., Pruski and Miglietta, Reference Pruski and Miglietta2019; Miglietta and Pruski, Reference Miglietta and Pruski2023). The monitoring hydrozoan diversity in nearby areas to the ports where tankers transporting M. cf. inkermanica set sail is scarce (e.g., Moore, Reference Moore1962; Burke, Reference Burke1975, Reference Burke1976; Harrel, Reference Harrel2002; Pruski and Miglietta, Reference Pruski and Miglietta2019). M. inkermanica is considered an invasive species in some regions of the world (Killi et al., Reference Killi, Tarkan, Kozic, Copp, Davison and Vilizzi2020), so its establishment in the Gulf of Mexico must be proved by monitoring the different coastal ecosystems of the region, analysing its abundance changes through the seasons of the year, and its impact on the native populations of the Gulf. Only then could it be recognized as an invasive species in this region. We encourage conducting more efforts in this way, aiming to have a better knowledge of the diversity of this group in the Gulf of Mexico, which is crucial to understanding the potential impacts on the native fauna and being able to apply correct management strategies to mitigate these impacts.

Data

All data are provided within the manuscript. Specimens are deposited at the collection of ‘Cnidarios del Golfo de México y Mar Caribe Mexicano’, based at the Universidad Nacional Autónoma de México, Facultad de Ciencias, Unidad Multidisciplinaria de Docencia e Investigación-Sisal, Yucatán.

Acknowledgements

We thank the administrative crew of the de Cayo Arcas platform. We also thank Francisco Puc-Itza, Jorge A. Dominguez-Maldonado, Gregory Arjona Torres, and José de la Cruz Cámara-Ramos for their support in the sampling and fieldwork. This work was written during the doctoral project of the first author (845170; CVU: 1079584).

Author contribution

UOL, MHR, and MAON conceptualized the sampling. JMAH conceptualized the idea and identified the specimens. All the authors approved the final version of the manuscript.

Financial support

This study was financed by PEMEX-GSIPAC-RMNE (Contract No. 412005814, Caracterización de Agua de Lastre, Cayo Arcas, 2005).

Competing interest

None.

Ethical standards

Not applicable.

References

Ahuatzin-Hernández, JM, Canul-Cabrera, JA, Eúan-Canul, CM and León-Deniz, LV (2020) Hydromedusae (Cnidaria: Hydrozoa) from the coastal lagoon of Bocas de Dzilam, Yucatán. Hidrobiológica 30, 221231. https://doi.org/10.24275/uam/izt/dcbs/hidro/2020v30n3/ahuatzinCrossRefGoogle Scholar
Álvarez-Silva, C, Gómez-Aguirre, S and Miranda-Arce, MG (2003) Variaciones morfológicas en Blackfordia virginica (Hydroidomedusae: Blackfordiidae) en lagunas costeras de Chiapas, México. Revista de Biología Tropical 51, 409412.Google ScholarPubMed
Bardi, J and Marques, AC (2009) The invasive hydromedusae Blackfordia virginica Mayer, 1910 (Cnidaria: Blackfordiidae) in southern Brazil, with comments on taxonomy and distribution of the genus Blackfordia. Zootaxa 2198, 4150. https://doi.org/10.11646/zootaxa.2198.1.4CrossRefGoogle Scholar
Botello, AV, Susana-Villanueva, F and Gilberto-Diaz, G (1997) Petroleum pollution in the Gulf of Mexico and Caribbean Sea. In Ware, GW (ed), Reviews of Environmental Contamination and Toxicology, Vol. 153. New York: Springer, pp. 91118. https://doi.org/10.1007/978-1-4612-2302-3_3CrossRefGoogle Scholar
Bouillon, J (1978) Hydroméduses de la mer de Bismarck (Papouasie, Nouvelle-Guinée). Partie 1: Anthomedusae Capitata (Hydrozoa-Cnidaria). Cahiers de Biologie Marine 19, 249297.Google Scholar
Bouillon, J, Bazin, J and Cleret, J (1969) Une Limnoméduse: Ostroumovia inkermanica dans le canal de Caen (Calvados, France). Bulletin de la Société linnéenne de Normandie 10, 7579.Google Scholar
Bouillon, J, Medel, MD, Pagés, F, Gili, JM, Boero, F and Gravili, C (2004) Fauna of the Mediterranean Hydrozoa. Scientia Marina 68, 5438. https://doi.org/10.3989/scimar.2004.68s25CrossRefGoogle Scholar
Boulenger, CE (1908) On Moerisia lyonsi, a new hydromedusan from Lake Qurun. Journal of Cell Science 2, 357378.CrossRefGoogle Scholar
Brockinton, EE, Peterson, MR, Wang, HH and Grant, WE (2022) Importance of anthropogenic determinants of Tubastraea coccinea invasion in the northern Gulf of Mexico. Water 14, 1365. https://doi.org/10.3390/w14091365CrossRefGoogle Scholar
Burke, WD (1975) Pelagic Cnidaria of Mississippi sound and adjacent waters. Gulf and Caribbean Research 5, 2338. https://doi.org/10.18785/grr.0501.04Google Scholar
Burke, WD (1976) Biology and distribution of the macrocoelenterates of Mississippi sound and adjacent waters. Gulf and Caribbean Research 5, 1728. https://doi.org/10.18785/grr.0502.03Google Scholar
Calder, DR (2010) Some anthoathecate hydroids and limnopolyps (Cnidaria, Hydrozoa) from the Hawaiian archipelago. Zootaxa 2590, 191. https://doi.org/10.11646/zootaxa.2590.1.1CrossRefGoogle Scholar
Calder, DR and Burrell, VG (1967) Occurrence of Moerisia lyonsi (Limnomedusae, Moerisiidae) in North America. American Midland Naturalist 78, 540541.CrossRefGoogle Scholar
Cartwright, P and Nawrocki, AM (2010) Character evolution in Hydrozoa (phylum Cnidaria). Integrative and Comparative Biology 50, 456472. https://doi.org/10.1093/icb/icq089CrossRefGoogle ScholarPubMed
Clark, K, Karsch-Mizrachi, I, Lipman, DJ, Ostell, J and Sayers, EW (2016) GenBank. Nucleic Acids Research 44, D67D72. https://doi.org/10.1093/nar/gkv1276CrossRefGoogle ScholarPubMed
Collins, AG (2002) Phylogeny of Medusozoa and the evolution of cnidarian life cycles. Journal of Evolutionary Biology 15, 418432. https://doi.org/10.1046/j.1420-9101.2002.00403.xCrossRefGoogle Scholar
Collins, AG, Winkelmann, S, Hadrys, H and Schierwater, B (2005) Phylogeny of Capitata and Corynidae (Cnidaria, Hydrozoa) in light of mitochondrial 16S rDNA data. Zoologica Scripta 34, 9199. https://doi.org/10.1111/j.1463-6409.2005.00172.xCrossRefGoogle Scholar
Collins, AG, Schuchert, P, Marques, AC, Jankowski, T, Medina, M and Schierwater, B (2006) Medusozoan phylogeny and character evolution clarified by new large and small subunit rDNA data and an assessment of the utility of phylogenetic mixture models. Systematic Biology 55, 97115. https://doi.org/10.1080/10635150500433615CrossRefGoogle Scholar
Cortés-Lacomba, R, Álvarez-Silva, C and Gutiérrez-Mendieta, F (2013) Listado actualizado de las medusas de la Laguna de Términos, Campeche, México. Hidrobiológica 23, 209217.Google Scholar
Derouen, ZC, Peterson, MR, Wang, HH and Grant, WE (2020) Determinants of Tubastraea coccinea invasion and likelihood of further expansion in the northern Gulf of Mexico. Marine Biodiversity 50, 111. https://doi.org/10.1007/s12526-020-01126-zCrossRefGoogle Scholar
Derzhavin, A (1912) Caspionema pallasi, eine Meduse des Kaspischen Meeres. Zoologischer Anzeiger 39, 390396.Google Scholar
Fautin, D, Dalton, P, Incze, LS, Leong, J-AC, Pautzke, C, Rosenberg, A, Sandifer, P, Sedberry, G, Tunnell, JW, Abbott, I, Brainard, RE, Brodeur, M, Eldredge, LG, Feldman, M, Moretzsohn, F, Vroom, PS, Wainstein, M and Wolff, N (2010) An overview of marine biodiversity in United States waters. PLoS ONE 5, e11914. https://doi.org/10.1371/journal.pone.0011914CrossRefGoogle ScholarPubMed
Fenner, D and Banks, K (2004) Orange cup coral Tubastraea coccinea invades Florida and the Flower Garden Banks, northwestern Gulf of Mexico. Coral Reefs 23, 505507. https://doi.org/10.1007/s00338-004-0422-xGoogle Scholar
Folino-Rorem, NC, Darling, JA and D'Ausilio, CA (2009) Genetic analysis reveals multiple cryptic invasive species of the hydrozoan genus Cordylophora. Biological Invasions 11, 18691882. https://doi.org/10.1007/s10530-008-9365-4CrossRefGoogle Scholar
GBIF (2024) Occurrence Download. https://www.gbif.org/occurrence/download/0030715-231002084531237. Accessed online 02 May 2024. https://doi.org/10.15468/dl.uwaqnqCrossRefGoogle Scholar
Graham, WM, Martin, DL, Felder, DL, Asper, VL and Perry, HM (2003) Ecological and economic implications of a tropical jellyfish invader in the Gulf of Mexico. In Pederson, J (ed), Marine Bioinvasions: Patterns, Processes and Perspectives. Dordrecht: Springer, pp. 5369. https://doi.org/10.1007/978-94-010-0169-4_6CrossRefGoogle Scholar
Gutiérrez-Aguirre, MA, Delgado-Blas, VH and Cervantes-Martínez, A (2015) Diversidad de las hidromedusas (Cnidaria) de la región nerítica del sureste de Tamaulipas, México. Teoría y Praxis 11, 153167. https://doi.org/10.22403/UQROOMX/TYP18/06CrossRefGoogle Scholar
Harrel, RC (2002) New distribution record and ecological notes of the freshwater Hydrozoan Craspedacusta sowerbii in Southeast Texas. The Texas Journal of Science 54, 357362.Google Scholar
Jankowski, T and Anokhin, B (2019) Phylum Cnidaria. In Damborenea, C, Rogers, DC and Thorp, JH (eds), Keys to Palearctic Fauna: Thorp and Covich's Freshwater Invertebrates, vol 4–4. Amsterdam: Elsevier, pp. 93111. https://doi.org/10.1016/B978-0-12-385024-9.00004-6CrossRefGoogle Scholar
Killi, N, Tarkan, AS, Kozic, S, Copp, GH, Davison, PI and Vilizzi, L (2020) Risk screening of the potential invasiveness of non-native jellyfishes in the Mediterranean Sea. Marine Pollution Bulletin 150, 110728. https://doi.org/10.1016/j.marpolbul.2019.110728CrossRefGoogle ScholarPubMed
Kramp, PL (1938) Die medusa von Ostrumovia inkermanica (Pal.–Ostr.) und die systematische Stellung der Moerisiiden und Olindiiden. Trud Chernomorsk Biol Sta Varna 7, 4568.Google Scholar
Kramp, PL (1955) Hydromedusae in the Indian museum. Records of the Zoological Survey of India 53, 339376.CrossRefGoogle Scholar
Kramp, PL (1959) The hydromedusae of the Atlantic Ocean and adjacent waters. Dana Report 46, 1283.Google Scholar
Kramp, PL (1961) Synopsis of the medusae of the world. Journal of the Marine Biological Association of the United Kingdom 40, 7382. https://doi.org/10.1017/S0025315400007347CrossRefGoogle Scholar
López-Ochoterena, E and Madrazo-Garibay, M (1989) Protozoarios ciliados de México XXXIII. Estudio biológico de algunas especies de las subclases Suctoria y Peritrichia, asociados al hidrozoario Cordylophora caspia (Pallas) en la Laguna de Mandinga, Veracruz. Revista de la Sociedad Mexicana de Historia Natural 40, 6570.Google Scholar
López-Torres, CK, Mendoza-Becerril, MA and de la Cruz-Francisco, V (2023) Medusozoans of Tuxpan, Veracruz, Gulf of Mexico. Regional Studies in Marine Science 63, 102987. https://doi.org/10.1016/j.rsma.2023.102987CrossRefGoogle Scholar
Ma, X and Purcell, JE (2005) Effects of temperature, salinity, and predators on mortality of and colonization by the invasive hydrozoan Moerisia lyonsi. Marine Biology 147, 215224. https://doi.org/10.1007/s00227-004-1538-9CrossRefGoogle Scholar
Marchessaux, G, Gadreaud, J, Martin-Garin, B, Thiéry, A, Ourgaud, M, Belloni, B and Thibault, D (2017) First report of the invasive jellyfish Gonionemus vertens A. Agassiz, 1862 in the Berre Lagoon, southeast France. BioInvasions Records 6, 339344. https://doi.org/10.3391/bir.2017.6.4.06CrossRefGoogle Scholar
Maronna, MM, Miranda, TP, Peña Cantero, ÁL, Barbeitos, MS and Marques, AC (2016) Towards a phylogenetic classification of Leptothecata (Cnidaria, Hydrozoa). Scientific Reports 6, 18075. https://doi.org/10.1038/srep18075CrossRefGoogle ScholarPubMed
McCann, LD, Hitchcock, NG, Winston, JE and Ruiz, GM (2007) Non-native bryozoans in coastal embayments of the southern United States: new records for the western Atlantic. Bulletin of Marine Science 80, 319342.Google Scholar
Meek, MH, Wintzer, AP, Shepherd, N and May, B (2013) Genetic diversity and reproductive mode in two non-native hydromedusae, Maeotias marginata and Moerisia sp., in the upper San Francisco Estuary, California. Biological Invasions 15, 199212. https://doi.org/10.1007/s10530-012-0279-9CrossRefGoogle Scholar
Miglietta, MP and Pruski, S (2023) Cryptic species in time and space: an assessment of cryptic diversity within eight nominal species of Hydrozoa (Cnidaria). Proceedings of the Royal Society B 290, 20230851. https://doi.org/10.1098/rspb.2023.0851CrossRefGoogle ScholarPubMed
Millard, NAH (1975) Monograph on the Hydroida of southern Africa. Annals of the South African Museum 68, 1513.Google Scholar
Moore, DR (1962) Occurrence and distribution of Nemopsis bachei Agassiz (Hydrozoa) in the northern Gulf of Mexico. Bulletin of Marine Science of the Gulf and Caribbean 12, 399402.Google Scholar
Nascimento, LS, Nogueira, M Jr, Viana, EM and Bersano, JGF (2019) Biodiversity of planktonic hydrozoans from a subtropical estuary: evidence of assemblage structure change. Journal of the Marine Biological Association of the United Kingdom 99, 551562. https://doi.org/10.1017/S0025315418000486CrossRefGoogle Scholar
Nawrocki, AM, Schuchert, P and Cartwright, P (2010) Phylogenetics and evolution of Capitata (Cnidaria: Hydrozoa), and the systematics of Corynidae. Zoologica Scripta 39, 290304. https://doi.org/10.1111/j.1463-6409.2009.00419.xCrossRefGoogle Scholar
Nogueira, M Jr (2012) Gelatinous zooplankton fauna (Cnidaria, Ctenophora and Thaliacea) from Baía da Babitonga (southern Brazil). Zootaxa 3398, 121. https://doi.org/10.11646/zootaxa.3398.1.1Google Scholar
Nogueira, M Jr and Oliveira, JS (2006) Moerisia inkermanica Paltschikowa-Ostroumova (Hydrozoa; Moerisiidae) e Blackfordia virginica Mayer (Hydrozoa; Blackfordiidae) na Baía de Antonina, Paraná, Brasil. Pan-American Journal of Aquatic Sciences 1, 3542.Google Scholar
Ocaña-Luna, A, Sánchez-Ramírez, M and Aguilar-Durán, R (2010) First record of Phyllorhiza punctata von Lendenfeld, 1884 (Cnidaria: Scyphozoa, Mastigiidae) in Mexico. Aquatic Invasions 5, S79S84. https://doi.org/10.3391/ai.2010.5.S1.017CrossRefGoogle Scholar
Ocaña-Luna, A, Sánchez-Ramírez, M and Islas-García, A (2021) Temporal abundance and population parameters of the invasive medusa Blackfordia virginica Mayer, 1910 (Hydroidomedusae: Blackfordiidae) in Pueblo Viejo lagoon, Mexico. BioInvasions Records 10, 826837. https://doi.org/10.3391/bir.2021.10.4.07CrossRefGoogle Scholar
Paltschikowa-Ostroumowa, MW (1925) Moerisia inkermanica n. sp. Zoologischer Anzeiger 62, 273284.Google Scholar
Pruski, S and Miglietta, MP (2019) Fluctuation and diversity of Hydromedusae (Hydrozoa, Cnidaria) in a highly productive region of the Gulf of Mexico inferred from high frequency plankton sampling. PeerJ 7, e7848. https://doi.org/10.7717/peerj.7848CrossRefGoogle Scholar
Purcell, JE, Båmstedt, U and Båmstedt, A (1999) Prey, feeding rates, and asexual reproduction rates of the introduced oligohaline hydrozoan Moerisia lyonsi. Marine Biology 134, 317325. https://doi.org/10.1007/s002270050549CrossRefGoogle Scholar
Rees, WJ (1958) The relationships of Moerisia lyonsi Boulenger, and the family Moerisiidae, with capitate hydroids. Proceedings of the Zoological Society of London 130, 537545. https://doi.org/10.1111/j.1096-3642.1958.tb00584.xCrossRefGoogle Scholar
Rees, JT and Gershwin, LA (2000) Non-indigenous hydromedusae in California's upper San Francisco Esturary: life cycles, distribution, and potential environmental impacts. Scientia Marina 64, 7386. https://doi.org/10.3989/scimar.2000.64s173CrossRefGoogle Scholar
Rees, WJ and Thursfield, S (1965) II. – The hydroid collections of James Ritchie. Proceedings of the Royal Society of Edinburgh. Section B: Biological Sciences 69, 34220. https://doi.org/10.1017/S0080455X00010122CrossRefGoogle Scholar
Restaino, DJ, Bologna, P, Gaynor, J, Buchanan, GA and Bilinski, JJ (2018) Who's lurking in your lagoon? First occurrence of the invasive hydrozoan Moerisia sp. (Cnidaria: Hydrozoa) in New Jersey, USA. BioInvasions Records 7, 223228. https://doi.org/10.3391/bir.2018.7.3.02CrossRefGoogle Scholar
Reusch, TBH, Bolte, S, Sparwel, M, Moss, AG and Javidpour, J (2010) Microsatellites reveal origin and genetic diversity of Eurasian invasions by one of the world's most notorious marine invader, Mnemiopsis leidyi (Ctenophora). Molecular Ecology 19, 26902699. https://doi.org/10.1111/j.1365-294X.2010.04701.xCrossRefGoogle ScholarPubMed
Rioja, E (1959) Estudios hidrobiológicos. XII: Hallazgo de la Cordylophora caspia (Pallas) (hidroideo gimnoblástido en la laguna de Mandinga, Veracruz). Anales del Instituto de Biología, Universidad Nacional Autónoma de México 30, 151157.Google Scholar
Ritchie, J (1915) The hydroids of the Indian Museum II. Annulella gemmata, a new and remarkable brackish-water hydroid. Records of the Zoological Survey of India 11, 541568.CrossRefGoogle Scholar
Saraber, JGAM (1962) Ostroumovia inkermanica in the Netherlands. Beaufortia 9, 117120.Google Scholar
Schuchert, P (2010) The European athecate hydroids and their medusae (Hydrozoa, Cnidaria): Capitata part 2. Revue Suisse de Zoologie 117, 337555.CrossRefGoogle Scholar
Schuchert, P (2012) North-West European athecate hydroids and their medusae. In Crothers, JH and Hayward, PJ (eds), Synopses of the British Fauna (New Series), no. 59. Dorchester: Linnean Society of London by Field Studies Council, pp. viii + 364.Google Scholar
Schuchert, P (2024) World Hydrozoa Database. Moerisia Boulenger, 1908. Accessed through: World Register of Marine Species. https://www.marinespecies.org/aphia.php?p=taxdetails&id=117166 Accessed online 02 May 2024.Google Scholar
Shepard, AN, Valentine, JF, D'Elia, CF, Yoskowitz, DW and Dismukes, DE (2013) Economic impact of Gulf of Mexico ecosystem goods and services and integration into restoration decision-making. Gulf of Mexico Science 31, 1027. https://doi.org/10.18785/goms.3101.02CrossRefGoogle Scholar
Teixeira-Amaral, P, de Lemos, VR, Muxagata, E and Nagata, RM (2021) Temporal dynamics of mesoplanktonic cnidarians in a subtropical estuary: environmental drivers and possible trophic effects. Estuarine, Coastal and Shelf Science 249, 107076. https://doi.org/10.1016/j.ecss.2020.107076CrossRefGoogle Scholar
Uchida, T and Nagao, Z (1959) The life-history of a Japanese brackish water hydroid, Ostroumovia horii. Journal of the Faculty of Science, Hokkaido University 14, 265281.Google Scholar
Uchida, T and Uchida, S (1929) Occurrence of a new lacustrine hydroid in Japan. Proceedings of the Imperial Academy 5, 157158.CrossRefGoogle Scholar
Valkanov, A (1953) Revision der Hydrozoen familie Moerisiidae. Trudove na Morskata biologicna stancija v” Stalin 18, 3347.Google Scholar
Wakida-Kusunoki, AT, Rojas-González, RI, González-Cruz, A, Amador-del Ángel, LE, Sánchez-Cruz, JL and López-Tellez, NA (2013) Presence of giant tiger shrimp Penaeus monodon Fabricius, 1798 on the Mexican coast of the Gulf of Mexico. BioInvasions Records 2, 325328. http://doi.org/10.3391/bir.2013.2.4.11CrossRefGoogle Scholar
Figure 0

Figure 1. Locations from where the tankers set sailed towards the Cayo Arcas oil terminal (star). Green dots indicate the locations from where the tankers transporting specimens of Moerisia cf. inkermanica Paltschikowa-Ostroumowa, 1925 set sailed.

Figure 1

Table 1. Physicochemical features of the ballast water and number of medusae recorded on each tanker. The ID corresponds to each tanker.

Figure 2

Figure 2. Moerisia cf. inkermanica Paltschikowa-Ostroumowa, 1925. (A) Complete view of mature specimens; (B) Lateral view of the manubrium; (C) Aboral view of the manubrium and perradial lobes; (D-E) Umbrella margin indicating tentacles at different development stages; (F) Oval clasping bulbs; (G) Moniliform tentacle indicating the terminal nematocysts knob; (H) Desmonemes; (I) Stenoteles.

Figure 3

Table 2. Comparison of the morphological diagnostic features of the valid species within Moerisia Boulenger, 1908

Figure 4

Table 3. GenBank accession numbers for the specimens of Moerisia Boulenger, 1908 with molecular data and their locality