Sea urchin harvest inside marine protected areas: an opportunity to investigate the effects of exploitation where trophic upgrading is achieved-Reference-Cited by-同舟云学术

Sea urchin harvest inside marine protected areas: an opportunity to investigate the effects of exploitation where trophic upgrading is achieved

Published:2022-03-07 Issue: Volume:10 Page:e12971
ISSN:2167-8359
Container-title:PeerJ
language:en
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Author:

Ceccherelli Giulia¹,Addis Piero²,Atzori Fabrizio³,Cadoni Nicoletta³,Casu Marco⁴,Coppa Stefania⁵,De Luca Mario¹,de Lucia Giuseppe Andrea⁵,Farina Simone⁶⁷,Fois Nicola⁸,Frau Francesca³,Gazale Vittorio⁹,Grech Daniele⁶,Guala Ivan⁶,Mariani Mariano¹⁰,Marras Massimo SG¹¹,Navone Augusto¹²,Pansini Arianna¹,Panzalis Pieraugusto¹²,Pinna Federico¹,Ruiu Alberto¹⁰,Scarpa Fabio⁴,Piazzi Luigi¹

Affiliation:

1. Dipartimento di Chimica e Farmacia, Universitá di Sassari, Via Piandanna, Sassari, Italy

2. Dipartimento di Scienze della Vita e dell’Ambiente, Universitá di Cagliari, Via Fiorelli, Cagliari, Italy

3. Capo Carbonara –Villasimius Marine Protected Area, Via Roma, Villasimius (CA), Italy

4. Dipartimento di Medicina Veterinaria –Sez. Fisiologia della Nutrizione e Zoologia, Universitá di Sassari, Sassari, Italy

5. Istituto per lo studio degli Impatti Antropici e Sostenibilità in ambiente marino (IAS) –Consiglio Nazionale delle Ricerche (CNR), Loc. Sa Mardini, Torre Grande (OR), Italy

6. IMC –International Marine Centre, Loc. Sa Mardini, Torre Grande, OR, Italy

7. SZN –Stazione Zoologica Anton Dohrn, Villa Comunale Napoli, Italy

8. Agris –Agricultural Research Agency of Sardinia –Bonassai SS, Sassari, Italy

9. Isola dell’Asinara Marine Protected Area, via Ponte Romano, Porto Torres (SS), Italy

10. Capo Caccia –Isola Piana Marine Protected Area, Loc. Tramariglio SP, Alghero, SS, Italy

11. Penisola del Sinis –Isola di Mal di Ventre Marine Protected Area, Corso Italia, Cabras, OR, Italy

12. Tavolara Punta Coda Cavallo Marine Protected Area, Via S. Giovanni, Olbia (SS), Italy

Abstract

Background Marine protected areas (MPAs) usually have both positive effects of protection for the fisheries’ target species and indirect negative effects for sea urchins. Moreover, often in MPAs sea urchin human harvest is restricted, but allowed. This study is aimed at estimating the effect of human harvest of the sea urchin Paracentrotus lividus within MPAs, where fish exploitation is restricted and its density is already controlled by a higher natural predation risk. The prediction we formulated was that the lowest densities of commercial sea urchins would be found where human harvest is allowed and where the harvest is restricted, compared to where the harvest is forbidden. Methods At this aim, a collaborative database gained across five MPAs in Sardinia (Western Mediterranean, Italy) and areas outside was gathered collecting sea urchin abundance and size data in a total of 106 sites at different degrees of sea urchin exploitation: no, restricted and unrestricted harvest sites (NH, RH and UH, respectively). Furthermore, as estimates made in past monitoring efforts (since 2005) were available for 75 of the sampled sites, for each of the different levels of exploitation, the rate of variation in the total sea urchin density was also estimated. Results Results have highlighted that the lowest sea urchin total and commercial density was found in RH sites, likely for the cumulative effects of human harvest and natural predation. The overall rate of change in sea urchin density over time indicates that only NH conditions promoted the increase of sea urchin abundance and that current local management of the MPAs has driven towards an important regression of populations, by allowing the harvest. Overall, results suggest that complex mechanisms, including synergistic effects between natural biotic interactions and human pressures, may occur on sea urchin populations and the assessment of MPA effects on P. lividus populations would be crucial to guide management decisions on regulating harvest permits. Overall, the need to ban sea urchin harvest in the MPAs to avoid extreme reductions is encouraged, as inside the MPAs sea urchin populations are likely under natural predation pressures for the trophic upgrading.

Publisher

PeerJ

Subject

General Agricultural and Biological Sciences,General Biochemistry, Genetics and Molecular Biology,General Medicine,General Neuroscience

Link

https://peerj.com/articles/12971.pdf

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