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The thermophilic sea anemone Telmatactis cricoides (Cnidaria, Hexacorallia) in the western Mediterranean: filling gaps in the knowledge of the distribution

Published online by Cambridge University Press:  20 February 2024

Alejandro Martín-Arjona*
Affiliation:
Centro Oceanográfico de Málaga (IEO, CSIC), Puerto Pesquero s/n, Fuengirola 29640, Málaga, Spain
Anabel Muñoz-Caballero
Affiliation:
Centro Oceanográfico de Baleares (IEO, CSIC), Muelle de Poniente s/n 07015 Palma, Islas Baleares, Spain
Alberto Serrano
Affiliation:
Centro Oceanográfico de Santander (IEO, CSIC), Calle Severiano Ballesteros 16 39004, Santander, Spain
David Díaz-Viñolas
Affiliation:
Centro Oceanográfico de Baleares (IEO, CSIC), Muelle de Poniente s/n 07015 Palma, Islas Baleares, Spain
Javier Urra
Affiliation:
Centro Oceanográfico de Málaga (IEO, CSIC), Puerto Pesquero s/n, Fuengirola 29640, Málaga, Spain
*
Corresponding author: Alejandro Martín-Arjona; Email: [email protected]
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Abstract

Several individuals of the sea anemone Telmatactis cricoides (Duchassaing, 1850) (order Actiniaria) were observed in the Mediterranean continental Spanish coast (Almeria) and the Balearic Islands (Mallorca) showing an expansion of the species, possibly related to rising sea water temperatures. This finding contributes to increase the knowledge on the geographical distribution range of this actiniarian in the Mediterranean basin.

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

The genus Telmatactis Gravier, 1916 (Cnidaria, Anthozoa, Actiniaria) contains 29 tropical to subtropical species distributed worldwide (Rodríguez et al., Reference Rodríguez, Fautin and Daly2023). Individuals display hexameric body plan with an adherent pedal disc, a column divided into a large scapus and a narrow, naked scapulus, and an oral disc with 24 to 96 entacmaceous tentacles rather short to moderately long with acute to distinctly clavate tips, those of the primary cycle often considerably larger than the rest (Cairns et al., Reference Cairns, den Hartog, Arneson and Sterrer1986; den Hartog, Reference den Hartog1995).

In the Mediterranean Sea, a total of three Telmatactis species occur (Häussermann, Reference Häussermann2003): Telmatactis forskalii (Hemprich & Ehrenberg in Ehrenberg, 1834), widely distributed throughout the Mediterranean basin (den Hartog, Reference den Hartog1995); Telmatactis solidago (Duchassaing & Michelotti, 1864), which seems to have a restricted distributional range limited to the eastern Mediterranean (den Hartog, Reference den Hartog1995); and Telmatactis cricoides (Duchassaing, Reference Duchassaing de Fontbressin1850), described from the Caribbean area (Antilles) in Duchassaing de Fontbressin (Reference Duchassaing de Fontbressin1850) and occurring throughout the tropical Atlantic Ocean, where the species shows an amphiatlantic distribution in tropical and subtropical waters (Bermuda, Brazil, Gulf of Guinea, Cape Verde Islands, Senegal, Canary Islands, Azores Islands, and Madeira Island, among other locations) (see den Hartog, Reference den Hartog1995 and references therein; Wirtz, Reference Wirtz2009), together with the Mediterranean Sea where it has been reported along the central and eastern basin (den Hartog, Reference den Hartog1995), with some observations registered in citizen science platforms (e.g. iNaturalist).

In 2016, the sea anemone T. cricoides was observed at Chafarinas Islands (southern Alboran Sea, western Mediterranean), a small archipelago consisting of three islets: Congreso, Isabel II, and El Rey, located at 3.2 km from the coast of Morocco, during a sampling campaign (Sánchez-Tocino et al., Reference Sánchez-Tocino, Tierno de Figueroa and de la Linde Rubio2016). Nevertheless, the presence of this species in the Spanish continental coast and the northwestern Mediterranean has not been reported to date.

Materials and methods

In the aim to describe and asses the status of rocky infralittoral habitats within the mandatory European Directive 2008/56/EC (Marine Strategy Framework Directive; https://www.msfd.eu/index.html), the project 17-ESMARES2-INFRA (a sub-project within the ESMARES project; see details at https://www.miteco.gob.es/es/costas/temas/proteccion-medio-marino/estrategias-marinas.html) carries out annual surveys called INFRAROCK expeditions performing underwater visual censuses (UVC) using scuba diving along littoral Spanish waters between 5–15 m depth (average depth of 11.2 m).

Between 2020 and 2022, a total of 787 transects in 148 sampling stations have been carried out along the Spanish Mediterranean including the continental coast, the Columbretes and the Balearic Islands, and the Strait of Gibraltar area as far as Chipiona (expeditions INFRAROCK_1120, INFRAROCK3D_0521 and INFRAROCK3D_0721 on board R/V SOCIB, and INFRAROCK3D_0522 on board R/V Francisco de Paula Navarro) (Figure 1). In every sampling station, a total of 25 replicates using a 50 × 50 cm (0.25 m2) PVC quadrat were performed in each one of the 4 transects performed for macroinvertebrates presence and abundance evaluation through UVC.

Figure 1. Map of the study area with the stations sampled during the INFRAROCK diving expeditions (year 2020 in red, 2021 in green, and 2022 in blue). Locations where Telmatactis cricoides specimens have been observed are indicated.

The identification of the specimens observed in the expeditions was done visually in situ, and their size recorded with a plastic calliper; moreover, every specimen was photographed. No specimens were collected for laboratory identification.

Results

A total of four specimens of T. cricoides were observed and identified in situ by visual censuses in two stations visited during the INFRAROCK expeditions in 2021 and 2022 (Figure 1). No specimens were collected or examined, the general shape and size of the specimens, together with the characteristic clavate tentacle tips left no doubt about their identity.

The first observation, 7th August 2021, corresponds to three specimens (Figure 2A) found inside a small cave at 8.5 m depth on the rocky bottom of the San Andres Island (Almeria), a Special Area of Conservation (Natura 2000 network) and a regional Natural Monument (SE Spain; 36.9917°N; 1.8844°W) (Figure 1). This corresponds to the first record of T. cricoides in the Mediterranean continental Spanish coast. The specimens showed a size ranging between 6–8 cm diameter of the oral disc and tentacles. They were associated with a faunal assemblage characterized by sciaphilic species such as the bryozoans Myriapora truncata (Pallas, 1766) and Cellepora pumicosa (Pallas, 1766), the sponges Oscarella lobularis (Schmidt, 1862) and Crambe crambe (Schmidt, 1862), the scleractinian Polycyathus muellerae (Abel, 1959), and the tube worm Protula tubularia (Montagu, 1803).

Figure 2. Specimens of Telmatactis cricoides observed at (A) San Andrés Island (Almeria) in September 2021, and (B) Figuera Cape (Mallorca Island) in September 2022.

The second observation, 18th September 2022, corresponds to one specimen (Figure 2B) found inside a small crevice on a vertical rocky cliff at 10.5 m depth off Figuera Cape (SW Mallorca; 39.4580°N, 2.5234°E) (Figure 1). This specimen had a size of ca. 6 cm diameter of the oral disc and tentacles. In this case, the specimen was associated with a faunal assemblage characterized by the sponges C. crambe and Chondrosia reniformis (Nardo, 1847), the echinoderms Ophidiaster ophidianus (Lamarck, 1816) and Paracentrotus lividus (Lamarck, 1816), the annelids Bonelia viridis (Rolando, 1822) and Protula intestinum (Lamarck, 1818), and the scleractinian Cladocora caespitosa (Linnaeus, 1767).

Discussion

This is the first documented report of the presence of the subtropical sea anemone T. cricoides in the continental Spanish coast (Almeria) and the Balearic Islands (Mallorca). These findings enlarge the knowledge of the geographical distribution of this actiniarian in the western Mediterranean, where up to date it had only been reported at Chafarinas Islands (southern Alboran Sea) by Sánchez-Tocino et al. (Reference Sánchez-Tocino, Tierno de Figueroa and de la Linde Rubio2016). The presence of tropical and subtropical benthic species in the western Mediterranean has been documented mostly for molluscs (e.g. Ungulina rubra de Roissy, 1804, Sinum bifasciatum (Récluz, 1851), Tritia vaucheri (Pallary, 1906) and Gibberula epigrus (Reeve, 1865), among others; see Rueda et al., Reference Rueda, Gofas, Urra and Salas2009; Urra et al., Reference Urra, Gofas, Rueda, Marina, Mateo, Antit and Salas2017) but also for other phyla (Rueda et al., Reference Rueda, Urra, Marina, Mateo and Reina2010), including echinoderms (e.g. Luidia atlantidea Madsen, 1950; see Gallardo-Roldán et al., Reference Gallardo-Roldán, Urra, García, Lozano, Antit, Baro and Rueda2015), decapod crustaceans (e.g. Cryptosoma cristatum (Brullé, 1837), Pagurus mbizi (Forest, 1955), among others; see García Raso, Reference García Raso1993; García Raso et al., Reference García Raso, Salmerón, Baro, Marina and Abelló2014) and fishes (e.g. Acanthurus monroviae (Steindachner, 1876) and Parapristipoma octolineatum (Valenciennes, 1833), among others; Golani et al., Reference Golani, Azzurro, Jakov, Massutí, Orsi-Relini and Briand2021). The presence of the abovementioned species along the northern Alboran basin, with records spanning several decades, would indicate the existence of persistent local populations in the westernmost Mediterranean basin. This could be supported by the oceanographic dynamics of this region, with a constant eastwards flux of superficial Atlantic waters through the Strait of Gibraltar, which may promote larval transport from northwestern Africa to the Alboran basin, and facilitated by the global warming derived from the climate change, as sea surface temperature has increased globally in the last decades, including the Alboran basin (Nykjaer, Reference Nykjaer2009).

In the case of T. cricoides, Sánchez-Tocino et al. (Reference Sánchez-Tocino, Tierno de Figueroa and de la Linde Rubio2016) does not support the hypothesis that this sea anemone arrived via the Strait, as this species had not been reported from the well-studied Gulf of Cadiz and northern Alboran sea, especially considering the monitoring programme carried out by the regional authorities since 2006 (Junta de Andalucía, 2021), together with a specific programme aimed to evaluate actiniarian species caught by the artisanal fleet. This absence could be related with colder winter waters that are not favourable for this subtropical species; however, it could survive in the warmer coasts of Almeria and the Balearic Islands. On the other hand, its presence inside a horizontal crack close to Congreso Island (Chafarinas Islands) could be promoted by the arriving of larva with the secondary Alboran anticyclonic gyre that brings warmer surface Atlantic water than that of the northern Alboran Sea. Here, almost constant upwelling processes of deep waters take place along the coasts of Malaga and Granada (Sarhan et al., Reference Sarhan, García-Lafuente, Vargas-Yañez, Vargas and Plaza2000; Cebrián and Ballesteros, Reference Cebrián and Ballesteros2004; Garcia-Jove et al., Reference Garcia-Jove, Mourre, Zarokanellos, Lermusiaux, Rudnick and Tintoré2022), which is reflected in the presence of species commonly found at deeper bottoms (Marina et al., Reference Marina, Rueda, Urra, Salas, Gofas, García Raso, Moya, García, López-González, Laiz-Carrión and Baro2015).

The specimens documented here were found in a sciaphilous habitat and in a depth range (8–10 m) similar to those documented for the species (den Hartog, Reference den Hartog1995; Wirtz, Reference Wirtz1996); however, the size and the colour morph are more similar to those of T. cricoides populations from the central and eastern Mediterranean Sea (https://www.inaturalist.org/observations/67573632 for Italian observations; https://www.inaturalist.org/observations/60295772 for Greek observation) than to the highly variable colour morphs of the giant Madeiran and Canarian specimens, which can reach diameters of the oral disc and tentacles up to 20 cm (den Hartog, Reference den Hartog1995; Wirtz, Reference Wirtz1996). This is not necessarily linked to the origin of the specimens reported here and, therefore, genetic analyses would be of interest to determine if they come from larva transported by the incoming Atlantic water masses or from central/eastern Mediterranean populations. Regarding this and according to den Hartog (Reference den Hartog1995), T. cricoides is only found in waters where the mean temperature of the coldest month does not drop below ca. 15°C; hence, its distribution in the Mediterranean Sea was limited to its central and eastern regions. Nevertheless, the seawater temperature of the Balearic Sea has been increasing at a rate of 0.04 ± 0.004°C year−1 between 1993–2016 (von Schuckmann et al., Reference von Schuckmann, Le Traon, Smith, Pascual, Fennel, Djavidnia, Aaboe, Fanjul, Autret, Axell, Aznar, Benincasa, Bentamy, Boberg, Bourdallé-Badie, Nardeli, Brando, Bricaud, Breivik, Brewin, Capet, Ceschin, Ciliberti, Cossarini, de Alfonso, de Pascual-Collar, de Kloe, Deshayes, Desportes, Drévillon, Drillet, Droghei, Dubois, Embury, Etienne, Fratianni, García-Lafuente, Garcia-Sotillo, Garric, Gasparin, Gerin, Good, Gourrion, Grégoire, Greiner, Guinehut, Gutknecht, Hernandez, Hernandez, Høyer, Jackson, Jandt, Josey, Juza, Kennedy, Kokkini, Korres, Kõuts, Lagemaa, Lavergne, le Cann, Legeais, Lemieux-Dudon, Levier, Lien, Maljutenko, Manzano, Marcos, Marinova, Masina, Mauri, Mayer, Melet, Mélin, Meyssignac, Monier, Müller, Mulet, Naranjo, Notarstefano, Paulmier, Pérez-Gomez, Pérez-Gonzalez, Peneva, Perruche, Peterson, Pinardi, Pisano, Pardo, Poulain, Raj, Raudsepp, Ravdas, Reid, Rio, Salon, Samuelsen, Sammartino, Sammartino, Sandø, Santoleri, Sathyendranath, She, Simoncelli, Solidoro, Stoffelen, Storto, Szerkely, Tamm, Tietsche, Tinker, Tintore, Trindade, van Zanten, Vandenbulcke, Verhoef, Verbrugge, Viktorsson, von Schuckmann, Wakelin, Zacharioudaki and Zuo2018), reaching over 15°C in the coldest month of the past winters (Barrientos et al., Reference Barrientos, Vaquer-Sunyer, Gomis, Marcos, Jordà, Baceló-Llull, Pascual, Aguiar, Ruiz-Parrado, Vaquer-Sunyer and Barrientos2021) (Figure 3). This increase of seawater temperature, especially the minimum in winter, would favour a spreading and settlement of species unable to survive previously, as seems to be the case with T. cricoides.

Figure 3. Seawater temperature temporal trend registered from 2008 to 2020 in Cabrera Island at 5 m depth (A) and Sa Foradada islet at 10 m depth (B). The red dashed line indicates 15°C and the red solid line indicates the trend considering mean annual values. Dataset was provided by the regional temperature observation network T-MEDNet (www.t-mednet.org).

This would suggest that central and eastern populations of this species could be extending their range to the western Mediterranean basin following the increase of water temperature. These observations could be part of the tropicalization of temperate marine ecosystems (Vergés et al., Reference Vergés, Steinberg, Hay, Poore, Campbell, Ballesteros, Heck, Booth, Coleman, Feary, Figueira, Langlois, Marzinelli, Mizerek, Mumby, Nakamura, Moninya, van Sebille, Sen Gupta, Smale, Tomas, Wernberg and Wilson2014), phenomenon that refers to the increase in seawater temperature and the expansion of species into the Mediterranean basin due to Atlantic influence, Lessepsian migration (i.e. migration of marine species across the Suez Canal, usually from the Red Sea) and/or driven by human activities (e.g. shipping, aquaculture, release of ornamental species) (Bianchi and Morri, Reference Bianchi and Morri2003). Overall, the establishment of tropical and subtropical species along the Mediterranean coasts may cause native communities that support high levels of biodiversity and complexity to modify or even lose their particular character (Bellan-Santini and Bellan, Reference Bellan-Santini and Bellan2000). This puts at risk the identity of Mediterranean communities, becoming similar to their tropical analogues, as it has been observed in the southern Mediterranean basin in the last decades, especially in certain areas such as the Levant region (Fishelson, Reference Fishelson2000).

The Mediterranean Sea is home to a diverse array of marine life, including many native species. It has been identified as the recipient of the greatest number of exotic species in the world, with an average of one introduction every 4 weeks (Streftaris et al., Reference Streftaris, Zenetos and Papathanassiou2005). This can have significant impacts in Mediterranean ecosystems as tropical species may alter the balance of native communities, particularly if they develop an invasive character under certain conditions. For these reasons, long term monitoring programmes of infralittoral rocky habitats are essential, not only to assess the environmental status of marine benthic habitats, but also to monitor the existing species status and investigate the presence of new records and their effects on littoral ecosystems.

Acknowledgements

We would like to thank Dr Olga Reñones, Dr Emma Cebrian and the T-MEDNet monitoring programme (ICM-CSIC) for sharing the temperature datasets from the sensors located at Sa Foradada islet and Cabrera island. Thanks to all the colleagues of the ESMARES project during the sampling expeditions INFRAROCK_1120, 0521, 0721, 0522, INFRAESAL_0621 and LEBALICS_0822, and the crews of the R/Vs ‘Francisco de Paula Navarro’ and ‘SOCIB’.

Authors’ contributions

Conceptualization and design of the article AM-A, JU; writing-original draft preparation AM-A, JU; writing – review AM, AS, DD-V; data acquisitions JU, AS, AM, AM-A, DD-V; data visualization AM-A, AM. All authors have read and agreed to the published version of the manuscript.

Financial support

This study was supported by the 17-ESMARES2-INFRA project ‘Monitoring and assessment of infralittoral benthic habitats’ from the Instituto Español de Oceanografía (IEO, CSIC) under the framework of the tasks ordered to the IEO by the Ministerio de Transición Ecológica y Reto Demográfico (MITERD) of the Spanish government for the application of the Marine Strategy Framework Directive (MSFD) in Spanish waters.

Competing interest

None.

Data

All relevant data are within the manuscript.

References

Barrientos, N, Vaquer-Sunyer, R, Gomis, D, Marcos, M, Jordà, G, Baceló-Llull, B, Pascual, A, Aguiar, E and Ruiz-Parrado, I (2021) Temperatura. In Vaquer-Sunyer, R and Barrientos, N (ed), Informe Mar Balear 2021. Islas Baleares, Spain: Marilles Foundation, pp. 2028 https://informemarbalear.org/es/cambio-global/imb-temperatura-esp.pdf.Google Scholar
Bellan-Santini, D and Bellan, G (2000) Distribution and peculiarities of Mediterranean marine biocoenoses. Biologia Marina Mediterranea 7, 6780.Google Scholar
Bianchi, C and Morri, C (2003) Global sea warming and “tropicalization” of the Mediterranean Sea: biogeographic and ecological aspects. Biogeographia–The Journal of Integrative Biogeography 24, 319327.CrossRefGoogle Scholar
Cairns, S, den Hartog, JC and Arneson, C (1986) Class Anthozoa (Corals, Anemones). In Sterrer, W (ed.), Marine Fauna and Flora of Bermuda. NY: Wiley-lnterscience Publication, pp. 164194.Google Scholar
Cebrián, E and Ballesteros, E (2004) Zonation patterns of benthic communities in an upwelling area from the western Medierranean (La Herradura, Alboran Sea). Scientia Marina 68, 6984.CrossRefGoogle Scholar
den Hartog, JC (1995) Telmatactis in Greece and eastern Mediterranean. Zoologische Mededelingen 69, 153176.Google Scholar
Duchassaing de Fontbressin, P (1850) Animaux radiaires des Antilles. Paris: Plon Frères, 35.Google Scholar
ESMARES project. Marine environment planning instrument. Ministerio para la Transición Ecológica y el Reto Democrático. Government of Spain. https://www.miteco.gob.es/es/costas/tema/proteccion-medio-marino/estrategias-marinas.html (Accessed online 04 November 2023).Google Scholar
Fishelson, L (2000) Marine animal assemblages along the littoral of the Israeli Mediterranean seashore: the Red-Mediterranean Seas communities of species. Italian Journal of Zoology 67, 393415.CrossRefGoogle Scholar
Gallardo-Roldán, H, Urra, J, García, T, Lozano, M, Antit, M, Baro, J and Rueda, JL (2015) First record of the starfish Luidia atlantidea Madsen, 1950 in the Mediterranean Sea, with evidence of persistent populations. Cahiers de Biologie Marine 56, 263270.Google Scholar
García Raso, JE (1993) New record of other African species of Crustacea Decapoda, Cycloes cristata (Brulle), from European and Mediterranean waters. Bios 1, 215221.Google Scholar
García Raso, JE, Salmerón, F, Baro, J, Marina, P and Abelló, P (2014) The tropical African hermit crab Pagurus mbizi (Crustacea, Decapoda, Paguridae) in the Western Mediterranean Sea: a new alien species or filling gaps in the knowledge of the distribution? Mediterranean Marine Science 15, 172178.CrossRefGoogle Scholar
Garcia-Jove, M, Mourre, B, Zarokanellos, ND, Lermusiaux, PFJ, Rudnick, DL and Tintoré, J (2022) Frontal dynamics in the Alboran Sea: 2. Processes for vertical velocities development. Journal of Geophysical Research: Oceans 127, e2021JC017428.Google Scholar
Golani, D, Azzurro, E, Jakov, D, Massutí, E, Orsi-Relini, L and Briand, F (2021) Atlas of Exotic Fishes in the Mediterranean Sea, 2nd Edn. Paris, Monaco, CIESM.Google Scholar
Häussermann, V (2003) Ordnung Actiniaria (Seeanemonen, Aktonien). In: Hofrichter, R. (Hrsg.), Das Mittelmeer, Fauna, Flora, Ökologie, Band II/1, Bestimmungsführer, Spektrum Akademischer Verlag, 476499.Google Scholar
Junta de Andalucía (2021) Programa de gestión sostenible del medio marino andaluz Informe final de resultados. Tehcnical report, 186 pp.Google Scholar
Marina, P, Rueda, JL, Urra, J, Salas, C, Gofas, S, García Raso, JE, Moya, F, García, T, López-González, N, Laiz-Carrión, R and Baro, J (2015) Sublittoral soft bottom assemblages within a marine protected area of the northern Alboran Sea. Journal of the Marine Biological Association of the United Kingdom 95, 871884.CrossRefGoogle Scholar
Marine Strategy Framework Directive. Protection of the marine ecosystem and biodiversity through the sustainable management of European seas. https://www.msfd.eu/index.html (Accessed online 04 November 2023).Google Scholar
Nykjaer, L (2009) Mediterranean Sea surface warming 1985–2006. Climate Research 39, 1117.CrossRefGoogle Scholar
Rodríguez, E, Fautin, D and Daly, M (2023). World List of Actiniaria. Telmatactis Gravier, 1916. World Register of Marine Species. https://www.marinespecies.org/aphia.php?p=taxdetails&id=100766 (Accessed online 18 June 2023).Google Scholar
Rueda, JL, Gofas, S, Urra, J and Salas, C (2009) A highly diverse molluscan assemblage associated with eelgrass beds (Zostera marina L.) in the Alboran Sea: micro-habitat preference, feeding guilds and biogeographical distribution. Scientia Marina 73, 669700.CrossRefGoogle Scholar
Rueda, JL, Urra, J, Marina, P, Mateo, A and Reina, JA (2010) Especies africanas en las costas de Andalucía: un patrimonio natural único en el ámbito europeo. Quercus 293, 2430.Google Scholar
Sánchez-Tocino, L, Tierno de Figueroa, JM and de la Linde Rubio, A (2016) First record of Telmatactis cricoides (Duchassaing, 1850) (Actiniaria) in the Western Mediterranean. Zoologica Baetica 27, 35.Google Scholar
Sarhan, T, García-Lafuente, J, Vargas-Yañez, M, Vargas, J and Plaza, F (2000) Upwelling mechanisms in the northwestern Alboran Sea. Journal of Marine Systems 23, 317331.CrossRefGoogle Scholar
Streftaris, N, Zenetos, A and Papathanassiou, E (2005) Globalisation in marine ecosystems: the story of non-indigenous marine species across European seas. Oceanography and Marine Biology 43, 419453.Google Scholar
Urra, J, Gofas, S, Rueda, JL, Marina, P, Mateo, A, Antit, M and Salas, C (2017) Biodiversity and biogeographical patterns of molluscan assemblages in vegetated and unvegetated habitats in the northern Alboran Sea (W Mediterranean Sea). Marine Biodiversity 47, 187201.CrossRefGoogle Scholar
Vergés, A, Steinberg, PD, Hay, ME, Poore, AGB, Campbell, AH, Ballesteros, E, Heck, KL, Booth, DJ, Coleman, MA, Feary, DA, Figueira, W, Langlois, T, Marzinelli, EM, Mizerek, T, Mumby, PJ, Nakamura, Y, Moninya, R, van Sebille, E, Sen Gupta, A, Smale, DA, Tomas, F, Wernberg, T and Wilson, SK (2014) The tropicalization of temperate marine ecosystems: climate-mediated changes in herbivory and community phase shifts. Proceedings of the Royal Society B: Biological Sciences 281, 20140846.CrossRefGoogle ScholarPubMed
von Schuckmann, K, Le Traon, P, Smith, N, Pascual, A, Fennel, K, Djavidnia, S, Aaboe, S, Fanjul, EA, Autret, E, Axell, L, Aznar, R, Benincasa, M, Bentamy, A, Boberg, F, Bourdallé-Badie, R, Nardeli, BB, Brando, VE, Bricaud, C, Breivik, LA, Brewin, RJW, Capet, A, Ceschin, A, Ciliberti, S, Cossarini, G, de Alfonso, M, de Pascual-Collar, A, de Kloe, J, Deshayes, J, Desportes, C, Drévillon, M, Drillet, Y, Droghei, R, Dubois, C, Embury, O, Etienne, H, Fratianni, C, García-Lafuente, J, Garcia-Sotillo, M, Garric, G, Gasparin, F, Gerin, R, Good, S, Gourrion, J, Grégoire, M, Greiner, E, Guinehut, S, Gutknecht, E, Hernandez, F, Hernandez, O, Høyer, J, Jackson, L, Jandt, S, Josey, S, Juza, M, Kennedy, J, Kokkini, Z, Korres, G, Kõuts, M, Lagemaa, P, Lavergne, T, le Cann, B, Legeais, JF, Lemieux-Dudon, B, Levier, B, Lien, V, Maljutenko, I, Manzano, F, Marcos, M, Marinova, V, Masina, S, Mauri, E, Mayer, M, Melet, A, Mélin, F, Meyssignac, B, Monier, M, Müller, M, Mulet, S, Naranjo, C, Notarstefano, G, Paulmier, A, Pérez-Gomez, B, Pérez-Gonzalez, I, Peneva, E, Perruche, C, Peterson, KA, Pinardi, N, Pisano, A, Pardo, S, Poulain, PM, Raj, RP, Raudsepp, U, Ravdas, M, Reid, R, Rio, MH, Salon, S, Samuelsen, A, Sammartino, M, Sammartino, S, Sandø, AB, Santoleri, R, Sathyendranath, S, She, J, Simoncelli, S, Solidoro, C, Stoffelen, A, Storto, A, Szerkely, T, Tamm, S, Tietsche, S, Tinker, J, Tintore, J, Trindade, A, van Zanten, D, Vandenbulcke, L, Verhoef, A, Verbrugge, N, Viktorsson, L, von Schuckmann, K, Wakelin, SL, Zacharioudaki, A and Zuo, H (2018) Copernicus marine service ocean state report. Journal of Operational Oceanography 11, S1S142.CrossRefGoogle Scholar
Wirtz, P (1996) The sea anemone Telmatactis cricoides from Madeira and the Canary Islands: size frequency, depth distribution and colour polymorphism. Life and Marine Sciences 14, 15.Google Scholar
Wirtz, P (2009) Ten new records of marine invertebrates from the Azores. Life and Marine Sciences 26, 4549.Google Scholar
Figure 0

Figure 1. Map of the study area with the stations sampled during the INFRAROCK diving expeditions (year 2020 in red, 2021 in green, and 2022 in blue). Locations where Telmatactis cricoides specimens have been observed are indicated.

Figure 1

Figure 2. Specimens of Telmatactis cricoides observed at (A) San Andrés Island (Almeria) in September 2021, and (B) Figuera Cape (Mallorca Island) in September 2022.

Figure 2

Figure 3. Seawater temperature temporal trend registered from 2008 to 2020 in Cabrera Island at 5 m depth (A) and Sa Foradada islet at 10 m depth (B). The red dashed line indicates 15°C and the red solid line indicates the trend considering mean annual values. Dataset was provided by the regional temperature observation network T-MEDNet (www.t-mednet.org).