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RESEARCH ARTICLE
Contents Vol 74(1)

Amphipod assemblages associated with native habitat-forming seaweeds of the Alboran Sea: influence by environmental protection and biogeographical patterns

Carlos Navarro-Barranco https://orcid.org/0000-0001-5894-0212 A * , Pablo Lanza-Arroyo B , Jorge Gutiérrez-Serrano B and Juan Moreira https://orcid.org/0000-0002-1374-2033 B
+ Author Affiliations
- Author Affiliations

A Laboratorio de Biología Marina, Departamento de Zoología, Universidad de Sevilla, E-41012 Seville, Spain.

B Departamento de Biología (Zoología) and Centro de Investigación en Biodiversidad y Cambio Global (CIBC-UAM), Universidad Autónoma de Madrid, E-28049 Madrid, Spain.

* Correspondence to: carlosnavarro@us.es

Handling Editor: Kylie Pitt

Marine and Freshwater Research 74(1) 50-64 https://doi.org/10.1071/MF22080
Submitted: 6 April 2022  Accepted: 26 September 2022   Published: 26 October 2022

© 2023 The Author(s) (or their employer(s)). Published by CSIRO Publishing

Abstract

Context: Despite the key ecological role played by epifaunal communities associated with macroalgae in temperate coastal rocky shores worldwide, biodiversity and ecological patterns of their associated invertebrate communities are still poorly known.

Aims: The present study aims to compare the amphipod assemblages associated with the dominant canopy-forming macroalgae in shallow subtidal habitats of the Alboran Sea, as well as to explore its biogeographical patterns and the influence of protection measures.

Methods: Replicate samples of both Ericaria selaginoides (=Cystoseira tamariscifolia) and Halopteris scoparia were collected at two different bioregions within the Alboran Sea and both inside and outside marine protected areas.

Key results: Amphipoda was the dominant taxon within the mobile epifaunal community, both in terms of number of species (47 different species were recorded) and individuals (>70% of the total abundance). Assemblages associated with E. selaginoides and H. scoparia differed and showed a marked response to the Mediterranean–Atlantic gradient in this region; species related to warmer waters become increasingly dominant towards the east. However, there were no significant differences in amphipod assemblage composition, abundance or species richness between protected and non-protected areas.

Conclusions: Obtained results highlighted the relevance of these native macroalgae as habitat for epifauna, as well as the influence of macroalgal identity and regional biogeographical patterns on amphipod distribution.

Implications: This study provides valuable baseline information to monitor human-induced changes such as coastal pollution, invasive species, and climate change. It also draws attention about the uncertain response of epifaunal communities to management strategies (such as marine protected areas) and ecological processes (e.g. increasing predation pressure).

Keywords: amphipod, biogeographical patterns, Crustacea, Cystoseira, epifauna, Halopteris, macroalgal forest, marine protected areas, Mediterranean Sea.


References

Alberto, F, Massa, S, Manent, P, Diaz-Almela, E, Arnaud-Haond, S, Duarte, CM, and Serrão, EA (2008). Genetic differentiation and secondary contact zone in the seagrass Cymodocea nodosa across the Mediterranean–Atlantic transition region. Journal of Biogeography 35, 1279–1294.
Genetic differentiation and secondary contact zone in the seagrass Cymodocea nodosa across the Mediterranean–Atlantic transition region.Crossref | GoogleScholarGoogle Scholar |

Alexander TJ (2011) Responses of temperate mobile macroinvertebrates to reef habitat structure and protection from fishing. PhD thesis, University of Tasmania, Hobart, Tas., Australia.

Anderson MJ, Gorley RN, Clarke KR (2008) ‘PERMANOVA for PRIMER: guide to software and statistical methods.’ (PRIMER-E: Plymouth, UK)

Arfianti T, Costello MJ (2020) The biological, ecological and ecosystem roles of marine Amphipoda. In ‘Encyclopedia of the World’s biomes’. (Eds MI Goldstein, DA DellaSala) pp. 518–526. (Elsevier)

Badalamenti, F, Cantone, G, Domina, R, Di Pietro, N, Catalano, D, Mollica, E, and D’Anna, G (1999). Primi dati sulla fauna a policheti di substrato duro dell’infralitorale fotofilo superiore dell’Isola di Ustica. Biologia Marina Mediterranea 6, 230–236.

Baldoa, F, and Drake, P (2002). A multivariate approach to the feeding habits of small fishes in the Guadalquivir Estuary. Journal of Fish Biology 61, 21–32.
A multivariate approach to the feeding habits of small fishes in the Guadalquivir Estuary.Crossref | GoogleScholarGoogle Scholar |

Barrett, NS, Buxton, CD, and Edgar, GJ (2009). Changes in invertebrate and macroalgal populations in Tasmanian marine reserves in the decade following protection. Journal of Experimental Marine Biology and Ecology 370, 104–119.
Changes in invertebrate and macroalgal populations in Tasmanian marine reserves in the decade following protection.Crossref | GoogleScholarGoogle Scholar |

Bedini, R, Bonechi, L, and Piazzi, L (2014). Mobile epifaunal assemblages associated with Cystoseira beds: comparison between areas invaded and not invaded by Lophocladia lallemandii. Scientia Marina 78, 425–432.
Mobile epifaunal assemblages associated with Cystoseira beds: comparison between areas invaded and not invaded by Lophocladia lallemandii.Crossref | GoogleScholarGoogle Scholar |

Bellan-Santini D, Karaman G, Krapp-Schickel G, Ledoyer M, Myers A, Ruffo S, Schiecke U (1982) ‘The Amphipoda of the Mediterranean. Part 1, Gammaridea (Acanthonotozomatidae to Gammaridae).’ (Mémories de l’Institut Oceanographique de Monaco: Monaco)

Bellan-Santini D, Diviacco G, Krapp-Schickel G (1989) ‘The Amphipoda of the Mediterranean. Part 2, Gammaridea (Haustoriidae to Lysianassidae).’ (Ed. S Ruffo) (Mémories de l’Institut Oceanographique de Monaco: Monaco)

Bellan-Santini D, Karaman G, Krapp-Schickel G, Ledoyer M, Ruffo S (1993) ‘The Amphipoda of the Mediterranean. Part 3, Gammaridea (Melphidippidae to Talitridae), Ingolfiellidea, Caprellidea.’ (Mémories de l’Institut Oceanographique de Monaco: Monaco)

Bellan-Santini D, Karaman G, Ledoyer M, Myers A, Ruffo S, Vader W (1998) ‘The Amphipoda of the Mediterranean. Part 4: Localities and Map, Addenda to Parts 1-3, Key to Families, Ecology, Faunistics and Zoogeography, Bibliography, Index.’ (Mémories de l’Institut Oceanographique de Monaco: Monaco)

Benedetti-Cecchi, L, Pannacciulli, F, Bulleri, F, Moschella, PS, Airoldi, L, Relini, G, and Cinelli, F (2001). Predicting the consequences of anthropogenic disturbance: large-scale effects of loss of canopy algae on rocky shores. Marine Ecology Progress Series 214, 137–150.
Predicting the consequences of anthropogenic disturbance: large-scale effects of loss of canopy algae on rocky shores.Crossref | GoogleScholarGoogle Scholar |

Bermejo, R, de la Fuente, G, Vergara, JJ, and Hernández, I (2013). Application of the CARLIT index along a biogeographical gradient in the Alboran Sea (European Coast). Marine Pollution Bulletin 72, 107–118.
Application of the CARLIT index along a biogeographical gradient in the Alboran Sea (European Coast).Crossref | GoogleScholarGoogle Scholar |

Bermejo, R, Ramirez-Romero, E, Vergara, JJ, and Hernández, I (2015). Spatial patterns of macrophyte composition and landscape along the rocky shores of the Mediterranean–Atlatic transition region (northern Alboran Sea). Estuarine, Coastal and Shelf Science 155, 17–28.
Spatial patterns of macrophyte composition and landscape along the rocky shores of the Mediterranean–Atlatic transition region (northern Alboran Sea).Crossref | GoogleScholarGoogle Scholar |

Bermejo, R, de la Fuente, G, Ramírez-Romero, E, Vergara, JJ, and Hernández, I (2016). Spatial variability and response to anthropogenic pressures of assemblages dominated by a habitat forming seaweed sensitive to pollution (northern coast of Alboran Sea). Marine Pollution Bulletin 105, 255–264.
Spatial variability and response to anthropogenic pressures of assemblages dominated by a habitat forming seaweed sensitive to pollution (northern coast of Alboran Sea).Crossref | GoogleScholarGoogle Scholar |

Bermejo, R, Chefaoui, RM, Engelen, AH, Buonomo, R, Neiva, J, Ferreira-Costa, J, et al. (2018). Marine forests of the Mediterranean-Atlantic Cystoseira tamariscifolia complex show a southern Iberian genetic hotspot and no reproductive isolation in parapatry. Scientific Reports 8, 10427.
Marine forests of the Mediterranean-Atlantic Cystoseira tamariscifolia complex show a southern Iberian genetic hotspot and no reproductive isolation in parapatry.Crossref | GoogleScholarGoogle Scholar |

Bernal-Ibáñez, A, Gestoso, I, Wirtz, P, Kaufmann, M, Serrão, EA, Canning-Clode, J, and Cacabelos, E (2021). The collapse of marine forests: drastic reduction in populations of the family Sargassaceae in Madeira Island (NE Atlantic). Regional Environmental Change 21, 71.
The collapse of marine forests: drastic reduction in populations of the family Sargassaceae in Madeira Island (NE Atlantic).Crossref | GoogleScholarGoogle Scholar |

Bianchi, CN, and Morri, C (2003). Global sea warming and ‘tropicalization’ of the Mediterranean Sea: biogeographic and ecological aspects. Biogeographia – The Journal of Integrative Biogeography 24, 319–327.
Global sea warming and ‘tropicalization’ of the Mediterranean Sea: biogeographic and ecological aspects.Crossref | GoogleScholarGoogle Scholar |

Blanco, A, Neto, JM, Troncoso, J, Lemos, MFL, and Olabarria, C (2020). Effectiveness of two western Iberian Peninsula marine protected areas in reducing the risk of macroalgae invasion. Ecological Indicators 108, 105 705.
Effectiveness of two western Iberian Peninsula marine protected areas in reducing the risk of macroalgae invasion.Crossref | GoogleScholarGoogle Scholar |

Blanfuné, A, Boudouresque, CF, Verlaque, M, and Thibaut, T (2019). The ups and downs of a canopy-forming seaweed over a span of more than one century. Scientific Reports 9, 5250.
The ups and downs of a canopy-forming seaweed over a span of more than one century.Crossref | GoogleScholarGoogle Scholar |

Boada, J, Pagès, JF, Gera, A, Macpherson, E, Santana, Y, Romero, J, and Alcoverro, T (2018). The richness of small pockets: decapod species peak in small seagrass patches where fish predators are absent. Marine Environmental Research 142, 1–6.
The richness of small pockets: decapod species peak in small seagrass patches where fish predators are absent.Crossref | GoogleScholarGoogle Scholar |

Borja, A, Franco, J, and Pérez, V (2000). A marine biotic index to establish the ecological quality of soft-bottom benthos within European estuarine and coastal environments. Marine Pollution Bulletin 40, 1100–1114.
A marine biotic index to establish the ecological quality of soft-bottom benthos within European estuarine and coastal environments.Crossref | GoogleScholarGoogle Scholar |

Bueno, M, Dias, GM, and Leite, FPP (2017). The importance of shore height and host identity for amphipod assemblages. Marine Biology Research 13, 870–877.
The importance of shore height and host identity for amphipod assemblages.Crossref | GoogleScholarGoogle Scholar |

Buonomo, R, Chefaoui, RM, Lacida, RB, Engelen, AH, Serrão, EA, and Airoldi, L (2018). Predicted extinction of unique genetic diversity in marine forests of Cystoseira spp. Marine Environmental Research 138, 119–128.
Predicted extinction of unique genetic diversity in marine forests of Cystoseira spp.Crossref | GoogleScholarGoogle Scholar |

Bustamante, M, Tajadura, J, Díez, I, and Saiz-Salinas, JI (2017). The potential role of habitat-forming seaweeds in modeling benthic ecosystem properties. Journal of Sea Research 130, 123–133.
The potential role of habitat-forming seaweeds in modeling benthic ecosystem properties.Crossref | GoogleScholarGoogle Scholar |

Carvalho, NF, Grande, H, Rosa Filho, JS, and Jacobucci, GB (2018). The structure of gammarid amphipod (Crustacea, Peracarida) assemblages associated with Sargassum (Phaeophyta, Fucales) and their link with the structural complexity of algae. Hydrobiologia 820, 245–254.
The structure of gammarid amphipod (Crustacea, Peracarida) assemblages associated with Sargassum (Phaeophyta, Fucales) and their link with the structural complexity of algae.Crossref | GoogleScholarGoogle Scholar |

Cebrián, E, and Ballesteros, E (2004). Zonation patterns of benthic communities in an upwelling area from the western Mediterranean (La Herradura, Alboran Sea). Scientia Marina 68, 69–84.
Zonation patterns of benthic communities in an upwelling area from the western Mediterranean (La Herradura, Alboran Sea).Crossref | GoogleScholarGoogle Scholar |

Cebrián, E, Ballesteros, E, and Canals, M (2000). Shallow rocky bottom benthic assemblages as calcium carbonate producers in the Alboran Sea (southwestern Mediterranean). Oceanologica Acta 23, 311–322.
Shallow rocky bottom benthic assemblages as calcium carbonate producers in the Alboran Sea (southwestern Mediterranean).Crossref | GoogleScholarGoogle Scholar |

Chen YY, Edgar GJ, Fox RJ (2021) The nature and ecological significance of epifaunal communities within marine ecosystems. In ‘Oceanography and marine biology: an annual review. Vol. 59’. pp. 585–720. (CRC Press)

Clarke KR, Gorley RN (2001) ‘PRIMER: plymouth routines in multivariate ecological research) v5: user manual/tutorial.’ (PRIMER-E Ltd: Plymouth, UK)

Compaire, JC, Casademont, P, Cabrera, R, Gómez-Cama, C, and Soriguer, MC (2018). Feeding of Scorpaena porcus (Scorpaenidae) in intertidal rock pools in the Gulf of Cadiz (NE Atlantic). Journal of the Marine Biological Association of the United Kingdom 98, 845–853.
Feeding of Scorpaena porcus (Scorpaenidae) in intertidal rock pools in the Gulf of Cadiz (NE Atlantic).Crossref | GoogleScholarGoogle Scholar |

Conradi, M, and López-González, PJ (1999). The benthic Gammaridea (Crustacea, Amphipoda) fauna of Algeciras Bay (Strait of Gibraltar): distributional ecology and some biogeographical considerations. Helgoland Marine Research 53, 2–8.
The benthic Gammaridea (Crustacea, Amphipoda) fauna of Algeciras Bay (Strait of Gibraltar): distributional ecology and some biogeographical considerations.Crossref | GoogleScholarGoogle Scholar |

Dayton, PK (1985). Ecology of kelp communities. Annual Review of Ecology and Systematics 16, 215–245.
Ecology of kelp communities.Crossref | GoogleScholarGoogle Scholar |

Di Franco, E, Di Franco, A, Calò, A, Di Lorenzo, M, Mangialajo, L, Bussotti, S, et al. (2021). Inconsistent relationships among protection, benthic assemblage, habitat complexity and fish biomass in Mediterranean temperate rocky reefs. Ecological Indicators 128, 107850.
Inconsistent relationships among protection, benthic assemblage, habitat complexity and fish biomass in Mediterranean temperate rocky reefs.Crossref | GoogleScholarGoogle Scholar |

Fabbrizzi, E, Scardi, M, Ballesteros, E, Benedetti-Cecchi, L, Cebrian, E, Ceccherelli, G, et al. (2020). Modeling macroalgal forest distribution at Mediterranean scale: present status, drivers of changes and insights for conservation and management. Frontiers in Marine Science 7, 20.
Modeling macroalgal forest distribution at Mediterranean scale: present status, drivers of changes and insights for conservation and management.Crossref | GoogleScholarGoogle Scholar |

Félix-Hackradt, FC, Hackradt, CW, Treviño-Otón, J, Pérez-Ruzafa, Á, and García-Charton, JA (2018). Effect of marine protected areas on distinct fish life-history stages. Marine Environmental Research 140, 200–209.
Effect of marine protected areas on distinct fish life-history stages.Crossref | GoogleScholarGoogle Scholar |

Filbee-Dexter, K, and Scheibling, RE (2014). Sea urchin barrens as alternative stable states of collapsed kelp ecosystems. Marine Ecology Progress Series 495, 1–25.
Sea urchin barrens as alternative stable states of collapsed kelp ecosystems.Crossref | GoogleScholarGoogle Scholar |

Flores-Moya A, Moreno D, De la Rosa J, Altamirano M, Bañares-España E (2021) Seaweeds and seagrasses: the marine forests from the Alboran Sea. In ‘Alboran Sea-ecosystems and marine resources’. (Eds JC Baez, J-T Vázquez, JA Camiñas, M Malouli Idrisi) pp. 247–284. (Springer: Cham, Switzerland)

Foster, ZSL, Sharpton, TJ, and Grünwald, NJ (2017). Metacoder: an R package for visualization and manipulation of community taxonomic diversity data. PLoS Computational Biology 13, e1005404.
Metacoder: an R package for visualization and manipulation of community taxonomic diversity data.Crossref | GoogleScholarGoogle Scholar |

Gan, SX, Tay, YC, and Huang, D (2019). Effects of macroalgal morphology on marine epifaunal diversity. Journal of the Marine Biological Association of the United Kingdom 99, 1697–1707.
Effects of macroalgal morphology on marine epifaunal diversity.Crossref | GoogleScholarGoogle Scholar |

García-Charton, JA, Pérez-Ruzafa, A, Sánchez-Jerez, P, Bayle-Sempere, JT, Reñones, O, and Moreno, D (2004). Multi-scale spatial heterogeneity, habitat structure, and the effect of marine reserves on western Mediterranean rocky reef fish assemblages. Marine Biology 144, 161–182.
Multi-scale spatial heterogeneity, habitat structure, and the effect of marine reserves on western Mediterranean rocky reef fish assemblages.Crossref | GoogleScholarGoogle Scholar |

Gil FJE, Adiego EMG, Moyano JES, García-Gómez JC (1999) Vigilancia ecológica de los fondos del litoral andaluz. In ‘Investigación y Desarrollo Medioambiental en Andalucía: resultados del Acuerdo Marco suscrito entre la Consejería de Medio Ambiente y la Universidad de Sevilla (1995–1998)’. pp. 105–108. (Universidad de Sevilla: Sevilla, Spain)

González-Duarte, MM, Megina, C, and Piraino, S (2014). Looking for long-term changes in hydroid assemblages (Cnidaria, Hydrozoa) in Alboran Sea (south-western Mediterranean): a proposal of a monitoring point for the global warming. Helgoland Marine Research 68, 511–521.
Looking for long-term changes in hydroid assemblages (Cnidaria, Hydrozoa) in Alboran Sea (south-western Mediterranean): a proposal of a monitoring point for the global warming.Crossref | GoogleScholarGoogle Scholar |

Guerra-García, JM, Cabezas, P, Baeza-Rojano, E, Espinosa, F, and García-Gómez, JC (2009). Is the north side of the Strait of Gibraltar more diverse than the south side? A case study using the intertidal peracarids (Crustacea: Malacostraca) associated to the seaweed Corallina elongata. Journal of the Marine Biological Association of the United Kingdom 89, 387–397.
Is the north side of the Strait of Gibraltar more diverse than the south side? A case study using the intertidal peracarids (Crustacea: Malacostraca) associated to the seaweed Corallina elongata.Crossref | GoogleScholarGoogle Scholar |

Guerra-García, JM, Baeza-Rojano, E, Cabezas, MP, and García-Gómez, JC (2011a). Vertical distribution and seasonality of peracarid crustaceans associated with intertidal macroalgae. Journal of Sea Research 65, 256–264.
Vertical distribution and seasonality of peracarid crustaceans associated with intertidal macroalgae.Crossref | GoogleScholarGoogle Scholar |

Guerra-García, JM, Ros, M, Dugo-Cota, A, Burgos, V, Flores-León, AM, Baeza-Rojano, E, et al. (2011b). Geographical expansion of the invader Caprella scaura (Crustacea: Amphipoda: Caprellidae) to the East Atlantic coast. Marine Biology 158, 2617–2622.
Geographical expansion of the invader Caprella scaura (Crustacea: Amphipoda: Caprellidae) to the East Atlantic coast.Crossref | GoogleScholarGoogle Scholar |

Izquierdo, D, and Guerra-García, JM (2011). Distribution patterns of the peracarid crustaceans associated with the alga Corallina elongata along the intertidal rocky shores of the Iberian Peninsula. Helgoland Marine Research 65, 233–243.
Distribution patterns of the peracarid crustaceans associated with the alga Corallina elongata along the intertidal rocky shores of the Iberian Peninsula.Crossref | GoogleScholarGoogle Scholar |

Jacobucci, GB, Vieira, EA, and Leite, FPP (2019). Influence of a narrow depth gradient on the spatial structure of Sargassum peracarid assemblages in Southeastern Brazil. Marine Biodiversity 49, 1001–1011.
Influence of a narrow depth gradient on the spatial structure of Sargassum peracarid assemblages in Southeastern Brazil.Crossref | GoogleScholarGoogle Scholar |

Jiménez Prada, P, Hachero Cruzado, I, and Guerra García, JM (2015). Importancia de los anfípodos en la dieta de especies de interés acuícola del litoral andaluz. Zoologica baetica 26, 3–29.

Jones, CG, Lawton, JH, and Shachak, M (1994). Organisms as ecosystem engineers. Oikos 69, 373–386.
Organisms as ecosystem engineers.Crossref | GoogleScholarGoogle Scholar |

Machado, GBO, Ferreira, AP, Bueno, M, Siqueira, SGL, and Leite, FPP (2019). Effects of macroalgal host identity and predation on an amphipod assemblage from a subtropical rocky shore. Hydrobiologia 836, 65–81.
Effects of macroalgal host identity and predation on an amphipod assemblage from a subtropical rocky shore.Crossref | GoogleScholarGoogle Scholar |

Mancuso, FP, D’Agostaro, R, Milazzo, M, and Chemello, R (2021). The invasive Asparagopsis taxiformis hosts a low diverse and less trophic structured molluscan assemblage compared with the native Ericaria brachycarpa. Marine Environmental Research 166, 105279.
The invasive Asparagopsis taxiformis hosts a low diverse and less trophic structured molluscan assemblage compared with the native Ericaria brachycarpa.Crossref | GoogleScholarGoogle Scholar |

Martin, LM, Taylor, M, Huston, G, Goodwin, DS, Schell, JM, and Siuda, ANS (2021). Pelagic Sargassum morphotypes support different rafting motile epifauna communities. Marine Biology 168, 115.
Pelagic Sargassum morphotypes support different rafting motile epifauna communities.Crossref | GoogleScholarGoogle Scholar |

Mateo-Ramírez, Á, Urra, J, Rueda, JL, Marina, P, and García Raso, J (2018). Decapod assemblages associated with shallow macroalgal communities in the northwestern Alboran Sea: microhabitat use and temporal variability. Journal of Sea Research 135, 84–94.
Decapod assemblages associated with shallow macroalgal communities in the northwestern Alboran Sea: microhabitat use and temporal variability.Crossref | GoogleScholarGoogle Scholar |

Matias, MG, Arenas, F, Rubal, M, and Pinto, IS (2015). Macroalgal composition determines the structure of benthic assemblages colonizing fragmented habitats. PLoS ONE 10, e0142289.
Macroalgal composition determines the structure of benthic assemblages colonizing fragmented habitats.Crossref | GoogleScholarGoogle Scholar |

Melis, R, Ceccherelli, G, Piazzi, L, and Rustici, M (2019). Macroalgal forests and sea urchin barrens: structural complexity loss, fisheries exploitation and catastrophic regime shifts. Ecological Complexity 37, 32–37.
Macroalgal forests and sea urchin barrens: structural complexity loss, fisheries exploitation and catastrophic regime shifts.Crossref | GoogleScholarGoogle Scholar |

Micheli, F, Benedetti-Cecchi, L, Gambaccini, S, Bertocci, I, Borsini, C, Osio, GC, and Romano, F (2005). Cascading human impacts, marine protected areas, and the structure of Mediterranean reef assemblages. Ecological Monographs 75, 81–102.
Cascading human impacts, marine protected areas, and the structure of Mediterranean reef assemblages.Crossref | GoogleScholarGoogle Scholar |

Milazzo, M, Chemello, R, Badalamenti, F, and Riggio, S (2000). Molluscan assemblages associated with photophilic algae in the marine reserve of Ustica Island (Lower Tyrrhenian Sea, Italy). Italian Journal of Zoology 67, 287–295.
Molluscan assemblages associated with photophilic algae in the marine reserve of Ustica Island (Lower Tyrrhenian Sea, Italy).Crossref | GoogleScholarGoogle Scholar |

Ministerio de Sanidad (2021) ‘Informe Nacional de Calidad de Aguas de Baño 2020. Colección de estudios, informes e Investigación.’ (Gobierno de España: Madrid, Spain)

Moksnes, P-O, Gullström, M, Tryman, K, and Baden, S (2008). Trophic cascades in a temperate seagrass community. Oikos 117, 763–777.
Trophic cascades in a temperate seagrass community.Crossref | GoogleScholarGoogle Scholar |

Mooser, A, Anfuso, G, Mestanza, C, and Williams, AT (2018). Management implications for the most attractive scenic sites along the Andalusia Coast (SW Spain). Sustainability 10, 1328.
Management implications for the most attractive scenic sites along the Andalusia Coast (SW Spain).Crossref | GoogleScholarGoogle Scholar |

Navarro-Barranco, C, Florido, M, Ros, M, González-Romero, P, and Guerra-García, JM (2018). Impoverished mobile epifaunal assemblages associated with the invasive macroalga Asparagopsis taxiformis in the Mediterranean Sea. Marine Environmental Research 141, 44–52.
Impoverished mobile epifaunal assemblages associated with the invasive macroalga Asparagopsis taxiformis in the Mediterranean Sea.Crossref | GoogleScholarGoogle Scholar |

Navarro-Barranco, C, Muñoz-Gómez, B, Saiz, D, et al. (2019a). Can invasive habitat-forming species play the same role as native ones? The case of the exotic marine macroalga Rugulopteryx okamurae in the Strait of Gibraltar. Biological Invasions 21, 3319–3334.
Can invasive habitat-forming species play the same role as native ones? The case of the exotic marine macroalga Rugulopteryx okamurae in the Strait of Gibraltar.Crossref | GoogleScholarGoogle Scholar |

Navarro-Barranco, C, Tierno de Figueroa, JM, Ros, M, and Guerra García, JM (2019b). Influence of Marine Protected Areas on parasitic prevalence: the case of the isopod Anilocra physodes as a parasite of the fish Lithognathus mormyrus. Journal of Zoology 308, 280–292.
Influence of Marine Protected Areas on parasitic prevalence: the case of the isopod Anilocra physodes as a parasite of the fish Lithognathus mormyrus.Crossref | GoogleScholarGoogle Scholar |

Navarro-Barranco C, Ros M, de Figueroa JMT, Guerra-García JM (2020) Marine crustaceans as bioindicators: amphipods as case study. In ‘Fisheries and aquaculture. Vol. 9’. (Eds G Lovrich, M Thiel) pp. 435–463 (Oxford University Press: Oxford, UK)

Navarro-Barranco, C, Moreira, J, Espinosa, F, Ros, M, Rallis, I, Sempere-Valverde, J, et al. (2021). Evaluating the vulnerability of coralligenous epifauna to macroalgal invasions. Aquatic Conservation: Marine and Freshwater Ecosystems 31, 2305–2319.
Evaluating the vulnerability of coralligenous epifauna to macroalgal invasions.Crossref | GoogleScholarGoogle Scholar |

Newcombe, EM, and Taylor, RB (2010). Trophic cascade in a seaweed–epifauna–fish food chain. Marine Ecology Progress Series 408, 161–167.
Trophic cascade in a seaweed–epifauna–fish food chain.Crossref | GoogleScholarGoogle Scholar |

Novoa, EAM, and Guiry, MD (2019). Reinstatement of the genera Gongolaria Boehmer and Ericaria Stackhouse (Sargassaceae, Phaeophyceae). European Journal of Phycology 54, 456.

Pacios, I, Guerra-García, JM, Baeza-Rojano, E, and Cabezas, MP (2011). The non-native seaweed Asparagopsis armata supports a diverse crustacean assemblage. Marine Environmental Research 71, 275–282.
The non-native seaweed Asparagopsis armata supports a diverse crustacean assemblage.Crossref | GoogleScholarGoogle Scholar |

Parravicini, V, Micheli, F, Montefalcone, M, Morri, C, Villa, E, Castellano, M, Povero, P, and Bianchi, CN (2013). Conserving biodiversity in a human-dominated world: degradation of marine sessile communities within a protected area with conflicting human uses. PLoS ONE 8, e75767.
Conserving biodiversity in a human-dominated world: degradation of marine sessile communities within a protected area with conflicting human uses.Crossref | GoogleScholarGoogle Scholar |

Patarra, RF, Carreiro, AS, Lloveras, AA, Abreu, MH, Buschmann, AH, and Neto, AI (2017). Effects of light, temperature and stocking density on Halopteris scoparia growth. Journal of Applied Phycology 29, 405–411.
Effects of light, temperature and stocking density on Halopteris scoparia growth.Crossref | GoogleScholarGoogle Scholar |

Pereira, SG, Lima, FP, Queiroz, NC, Ribeiro, PA, and Santos, AM (2006). Biogeographic patterns of intertidal macroinvertebrates and their association with macroalgae distribution along the Portuguese coast. Hydrobiologia 555, 185–192.
Biogeographic patterns of intertidal macroinvertebrates and their association with macroalgae distribution along the Portuguese coast.Crossref | GoogleScholarGoogle Scholar |

Piazzi, L, Bonaviri, C, Castelli, A, Ceccherelli, G, Costa, G, Curini-Galletti, M, et al. (2018). Biodiversity in canopy-forming algae: structure and spatial variability of the Mediterranean Cystoseira assemblages. Estuarine, Coastal and Shelf Science 207, 132–141.
Biodiversity in canopy-forming algae: structure and spatial variability of the Mediterranean Cystoseira assemblages.Crossref | GoogleScholarGoogle Scholar |

Pinnegar, JK, Polunin, NVC, Francour, P, Badalamenti, F, Chemello, R, Harmelin-Vivien, ML, et al. (2000). Trophic cascades in benthic marine ecosystems: lessons for fisheries and protected-area management. Environmental Conservation 27, 179–200.
Trophic cascades in benthic marine ecosystems: lessons for fisheries and protected-area management.Crossref | GoogleScholarGoogle Scholar |

Real R, Gofas S, Altamirano M, Salas C, Báez JC, Camiñas JA, García-Raso JE, Gil de Sola L, Olivero J, Reina-Hervás JA, Flores-Moya A (2021) Biogeographical and macroecological context of the Alboran Sea. In ‘Alboran sea-ecosystems and marine resources’. (Eds JC Baez, JT Vázquez, JA Camiñas, M Malouli Idrisi) pp. 431–457. (Springer: Cham, Switzerland)

Renault, L, Oguz, T, Pascual, A, Vizoso, G, and Tintore, J (2012). Surface circulation in the Alborán Sea (western Mediterranean) inferred from remotely sensed data. Journal of Geophysical Research: Oceans 117, C08009.
Surface circulation in the Alborán Sea (western Mediterranean) inferred from remotely sensed data.Crossref | GoogleScholarGoogle Scholar |

Rodríguez-Prieto, C, and Polo, L (1996). Effects of the sewage pollution in the structure and dynamics of the community of Cystoseira mediterranea (Fucales, Phaeophyceae). Scientia Marina 60, 253–263.

Ros, M, Guerra-García, JM, Lignot, J-H, and Rivera-Ingraham, GA (2021). Environmental stress responses in sympatric congeneric crustaceans: explaining and predicting the context-dependencies of invader impacts. Marine Pollution Bulletin 170, 112621.
Environmental stress responses in sympatric congeneric crustaceans: explaining and predicting the context-dependencies of invader impacts.Crossref | GoogleScholarGoogle Scholar |

Sala, E (1997). The role of fishes in the organization of a Mediterranean sublittoral community: II: epifaunal communities. Journal of Experimental Marine Biology and Ecology 212, 45–60.
The role of fishes in the organization of a Mediterranean sublittoral community: II: epifaunal communities.Crossref | GoogleScholarGoogle Scholar |

Sales, M, and Ballesteros, E (2009). Shallow Cystoseira (Fucales: Ochrophyta) assemblages thriving in sheltered areas from Menorca (NW Mediterranean): relationships with environmental factors and anthropogenic pressures. Estuarine, Coastal and Shelf Science 84, 476–482.
Shallow Cystoseira (Fucales: Ochrophyta) assemblages thriving in sheltered areas from Menorca (NW Mediterranean): relationships with environmental factors and anthropogenic pressures.Crossref | GoogleScholarGoogle Scholar |

Sanabria-Fernandez, JA, Alday, JG, Lazzari, N, Riera, R, and Becerro, MA (2019). Marine protected areas are more effective but less reliable in protecting fish biomass than fish diversity. Marine Pollution Bulletin 143, 24–32.
Marine protected areas are more effective but less reliable in protecting fish biomass than fish diversity.Crossref | GoogleScholarGoogle Scholar |

Sánchez-Moyano, JE, García-Adiego, EM, Estacio, FJ, and García-Gómez, JC (2000). Effect of environmental factors on the spatial distribution of the epifauna of the alga Halopteris scoparia in Algeciras Bay, southern Spain. Aquatic Ecology 34, 355–367.
Effect of environmental factors on the spatial distribution of the epifauna of the alga Halopteris scoparia in Algeciras Bay, southern Spain.Crossref | GoogleScholarGoogle Scholar |

Sedano, F, Tierno de Figueroa, JM, Navarro-Barranco, C, Ortega, E, Guerra-García, JM, and Espinosa, F (2020a). Do artificial structures cause shifts in epifaunal communities and trophic guilds across different spatial scales? Marine Environmental Research 158, 104998.
Do artificial structures cause shifts in epifaunal communities and trophic guilds across different spatial scales?Crossref | GoogleScholarGoogle Scholar |

Sedano, F, Navarro-Barranco, C, Guerra-García, JM, and Espinosa, F (2020b). From sessile to vagile: understanding the importance of epifauna to assess the environmental impacts of coastal defence structures. Estuarine, Coastal and Shelf Science 235, 106616.
From sessile to vagile: understanding the importance of epifauna to assess the environmental impacts of coastal defence structures.Crossref | GoogleScholarGoogle Scholar |

Smale, DA, Burrows, MT, Moore, P, O’Connor, N, and Hawkins, SJ (2013). Threats and knowledge gaps for ecosystem services provided by kelp forests: a Northeast Atlantic perspective. Ecology and Evolution 3, 4016–4038.
Threats and knowledge gaps for ecosystem services provided by kelp forests: a Northeast Atlantic perspective.Crossref | GoogleScholarGoogle Scholar |

Spalding, MD, Fox, HE, Allen, GR, Davidson, N, Ferdaña, ZA, Finlayson, M, et al. (2007). Marine ecoregions of the world: a bioregionalization of coastal and shelf areas. BioScience 57, 573–583.
Marine ecoregions of the world: a bioregionalization of coastal and shelf areas.Crossref | GoogleScholarGoogle Scholar |

Stelling-Wood, TP, Gribben, PE, and Poore, AGB (2020). Habitat variability in an underwater forest: using a trait-based approach to predict associated communities. Functional Ecology 34, 888–898.
Habitat variability in an underwater forest: using a trait-based approach to predict associated communities.Crossref | GoogleScholarGoogle Scholar |

Steneck, RS, Graham, MH, Bourque, BJ, Corbett, D, Erlandson, JM, Estes, JA, and Tegner, MJ (2002). Kelp forest ecosystems: biodiversity, stability, resilience and future. Environmental Conservation 29, 436–459.
Kelp forest ecosystems: biodiversity, stability, resilience and future.Crossref | GoogleScholarGoogle Scholar |

Sturaro, N, Lepoint, G, Pérez-Perera, A, Vermeulen, S, Panzalis, P, Navone, A, and Gobert, S (2014). Seagrass amphipod assemblages in a Mediterranean marine protected area: a multiscale approach. Marine Ecology Progress Series 506, 175–192.
Seagrass amphipod assemblages in a Mediterranean marine protected area: a multiscale approach.Crossref | GoogleScholarGoogle Scholar |

Sturaro, N, Gobert, S, Pérez-Perera, A, Caut, S, Panzalis, P, Navone, A, and Lepoint, G (2016). Effects of fish predation on Posidonia oceanica amphipod assemblages. Marine Biology 163, 58.
Effects of fish predation on Posidonia oceanica amphipod assemblages.Crossref | GoogleScholarGoogle Scholar |

Suárez-Jiménez, R, Hepburn, CD, Hyndes, GA, McLeod, RJ, Taylor, RB, and Hurd, CL (2017). The invasive kelp Undaria pinnatifida hosts an epifaunal assemblage similar to native seaweeds with comparable morphologies. Marine Ecology Progress Series 582, 45–55.
The invasive kelp Undaria pinnatifida hosts an epifaunal assemblage similar to native seaweeds with comparable morphologies.Crossref | GoogleScholarGoogle Scholar |

Thornber CS, Jones E, Thomsen MS (2017) Epibiont–marine macrophytes assemblages. In ‘Marine macrophytes as foundation species’. (Ed. E Olafsson) pp. 43–75. (CRC Press: Boca Raton, FL, USA)

Underwood AJ (1997) ‘Experiments in ecology: their logical design and interpretation using analysis of variance.’ (Cambridge University Press: Cambridge, UK)

Underwood AJ, Chapman MG, Richards SA (2002) ‘GMAV-5 for Windows: an analysis of variance programme.’ (University of Sydney: Sydney, NSW, Australia)