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‘Simple’ can be good, too: testing three hard bottom sampling methods on macrobenthic and meiobenthic assemblages

Published online by Cambridge University Press:  24 October 2018

Kleoniki Keklikoglou*
Affiliation:
Institute of Marine Biology, Biotechnology and Aquaculture, Hellenic Centre for Marine Research, Thalassocosmos, 71003 Heraklion, Crete, Greece
Georgios Chatzigeorgiou
Affiliation:
Institute of Marine Biology, Biotechnology and Aquaculture, Hellenic Centre for Marine Research, Thalassocosmos, 71003 Heraklion, Crete, Greece
Sarah Faulwetter
Affiliation:
Department of Zoology, Section of Marine Biology, University of Patras, 26504 Patras, Greece
Vassiliki Kalogeropoulou
Affiliation:
Animal and Plant Health Agency, KT153NB Addlestone, Surrey, UK
Wanda Plaiti
Affiliation:
Institute of Marine Biology, Biotechnology and Aquaculture, Hellenic Centre for Marine Research, Thalassocosmos, 71003 Heraklion, Crete, Greece
Maria Maidanou
Affiliation:
Institute of Marine Biology, Biotechnology and Aquaculture, Hellenic Centre for Marine Research, Thalassocosmos, 71003 Heraklion, Crete, Greece
Costas Dounas
Affiliation:
Institute of Marine Biology, Biotechnology and Aquaculture, Hellenic Centre for Marine Research, Thalassocosmos, 71003 Heraklion, Crete, Greece
Nikolaos Lampadariou
Affiliation:
Institute of Oceanography, Hellenic Centre for Marine Research, Thalassocosmos, 71003 Heraklion, Crete, Greece
Christos Arvanitidis
Affiliation:
Institute of Marine Biology, Biotechnology and Aquaculture, Hellenic Centre for Marine Research, Thalassocosmos, 71003 Heraklion, Crete, Greece
*
Author for correspondence: Kleoniki Keklikoglou, E-mail: [email protected]

Abstract

Subtidal hard bottoms are of particular scientific and economic value as they are highly productive systems. They are less well studied compared with soft bottoms, as they often require manual sample collection via scuba diving. Although a multitude of sampling devices is available for soft bottoms, only a few are suitable for hard substrates, and their performance is largely unstudied. In the present study, three hard bottom sampling methods were compared, regarding their sampling efficiency and the damage they may cause to macrobenthic and meiobenthic organisms. Two of the sampling methods examined are typically employed for the study of hard bottom substrates (manual collection, airlift device), while the third involves a newly constructed sampler (MANOSS – Manual Operated Suction Sampler). All three sampling methods were tested at 12 m depth on a hard bottom substrate with algal coverage dominated by Cystoseira spp. No overall significant differences were observed between the sampling efficiency and the damage caused by the three sampling methods regarding the macrofaunal assemblages, with the exception of the MANOSS method which collected more species than the manual method. In addition, significant differences were observed in the collecting performance for the meiobenthic assemblages, presenting significantly higher densities of meiofauna sampled by the MANOSS compared with the manual collection method, while the airlift device presented an intermediate efficiency. However, taking into account other factors such as cost, ease of use and the scope of each study, none of the methods clearly outperforms the others.

Type
Research Article
Copyright
Copyright © Marine Biological Association of the United Kingdom 2018 

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References

Abbiati, M (ed.) (1991) Metodi di campionamento biologico subacqueo. In Lezioni del Corso Formativo per Ricercatore Scientifico Subacqueo. Pisa: International School of Scientific Diving, pp. 312.Google Scholar
Airoldi, L, Connell, SD and Beck, MW (2009) The loss of natural habitats and the addition of artificial substrata. In Wahl, M (ed.), Marine Hard Bottom Communities. Berlin: Springer, pp. 269280.10.1007/b76710_19Google Scholar
Alldredge, AL and King, JM (1985) The distance demersal zooplankton migrate above the benthos: implications for predation. Marine Biology 84, 253260.10.1007/BF00392494Google Scholar
Antoniadou, C and Chintiroglou, C (2005) Biodiversity of zoobenthic hard-substrate sublittoral communities in the Eastern Mediterranean (North Aegean Sea). Estuarine, Coastal and Shelf Science 62, 637653.10.1016/j.ecss.2004.09.032Google Scholar
Antoniadou, C, Koutsoubas, D and Chintiroglou, CC (2005) Mollusca fauna from infralittoral hard substrate assemblages in the North Aegean Sea. Belgian Journal of Zoology 135, 119126.Google Scholar
Armonies, W (1988) Active emergence of meiofauna from intertidal sediment. Marine Ecology Progress Series 43, 151159.10.3354/meps043151Google Scholar
Austen, MC and Warwick, RM (1989) Comparison of univariate and multivariate aspects of estuarine meiobenthic community structure. Estuarine, Coastal and Shelf Science 29, 2342.10.1016/0272-7714(89)90071-1Google Scholar
Bergmann, M, Beare, DJ and Moore, PG (2001) Damage sustained by epibenthic invertebrates discarded in the Nephrops fishery of the Clyde Sea area, Scotland. Journal of Sea Research 45, 105118.10.1016/S1385-1101(01)00053-3Google Scholar
Bianchi, CN and Morri, C (2000) Marine biodiversity of the Mediterranean Sea: situation, problems and prospects for future research. Marine Pollution Bulletin 40, 367376.10.1016/S0025-326X(00)00027-8Google Scholar
Bianchi, CN, Pronzato, R, Cattaneo-Vietti, R, Benedetti-Cecchi, L, Morri, C, Pansini, M, Chemello, R, Milazzo, M, Fraschetti, S, Terlizzi, A, Peirano, A, Salvati, E, Benzoni, F, Calcinai, B, Cerrano, C and Bavestrello, G (2004) Hard bottoms. In Gambi, M and Dappiano, M (eds), Mediterranean marine benthos: a manual of methods for its sampling and study. Biologia Marina Meditteranea 11 (Suppl. 1), 185215.Google Scholar
Bray, RJ and Curtis, JT (1957) An ordination of the upland forest communities of southern Wisconsin. Ecological Monographs 27, 325349.10.2307/1942268Google Scholar
Brett, C (1964) A portable hydraulic diver-operated dredge-sieve for sampling subtidal macrofauna. Journal of Marine Research 22, 205209.Google Scholar
Brooks, S (1994) An efficient and quantitative aquatic benthos sampler for use in diverse habitats with variable flow regimes. Hydrobiologia 281, 123128.10.1007/BF00006441Google Scholar
Carleton, JH and Hamner, WM (1987) A diver-operated device for the capture of mobile epibenthic organisms. Limnology and Oceanography 32, 503510.10.4319/lo.1987.32.2.0503Google Scholar
Chatzigeorgiou, G, Dailianis, T, Faulwetter, S and Pettas, M (2012) MANOSS – a manually operated suction sampler for hard bottom benthos. Transitional Waters Bulletin 6, 4249.Google Scholar
Chintiroglou, C, Antoniadou, C, Vafidis, D and Koutsoubas, D (2005) A review on the biodiversity of hard substrate invertebrate communities in the Aegean Sea. Mediterranean Marine Science 6, 5162.10.12681/mms.185Google Scholar
Clarke, K (1993) Non-parametric multivariate analyses of changes in community structure. Australian Journal of Ecology 18, 117143.10.1111/j.1442-9993.1993.tb00438.xGoogle Scholar
Clarke, K and Gorley, R (2006) PRIMER v6.1.5: User Manual/Tutorial. Plymouth: PRIMER-E.Google Scholar
Clarke, K and Warwick, R (1994) Similarity-based testing for community pattern: the two-way layout with no replication. Marine Biology 118, 167176.10.1007/BF00699231Google Scholar
Danovaro, R and Fraschetti, S (2002) Meiofaunal vertical zonation on hard-bottoms: comparison with soft-bottom meiofauna. Marine Ecology Progress Series 230, 159169.10.3354/meps230159Google Scholar
Decho, AW (1986) Water-cover influences on diatom ingestion rates by meiobenthic copepods. Marine Ecology Progress Series 33, 139146.10.3354/meps033139Google Scholar
de Jonge, VN and Bouwman, LA (1977) A simple density separation technique for quantitative isolation of meiobenthos using the Colloidal silica Ludox-TM. Marine Biology 42, 143148.10.1007/BF00391564Google Scholar
Drake, CM and Elliott, JM (1982) A comparative study of three air-lift samplers used for sampling benthic macro-invertebrates in rivers. Freshwater Biology 12, 511533.10.1111/j.1365-2427.1982.tb00644.xGoogle Scholar
Eleftheriou, A and McIntyre, A (2005) Methods for the Study of Marine Benthos, 3rd Edn. Oxford: Blackwell Science.10.1002/9780470995129Google Scholar
Elliott, JM and Tullett, PA (1983) A supplement to a bibliography of samplers for benthic invertebrates. Freshwater Biological Association, Occasional Publication 20, 27 pp.Google Scholar
Emery, AR (1968) Preliminary observations on coral reef plankton. Limnology and Oceanography 13, 293303.10.4319/lo.1968.13.2.0293Google Scholar
Fraschetti, S, Gambi, C, Giangrande, A, Musco, L, Terlizzi, A and Danovaro, R (2006) Structural and functional response of meiofauna rocky assemblages to sewage pollution. Marine Pollution Bulletin 52, 540548.10.1016/j.marpolbul.2005.10.001Google Scholar
Gale, WF and Thompson, JD (1975) A suction sampler for quantitatively sampling benthos on rocky substrates in rivers. Transactions of the American Fisheries Society 104, 398405.10.1577/1548-8659(1975)104<398:ASSFQS>2.0.CO;22.0.CO;2>Google Scholar
Gibbons, MJ and Griffiths, CL (1988) An improved quantitative method for estimating intertidal meiofaunal standing stock on an exposed rocky shore. South African Journal of Marine Science 6, 5558.10.2989/025776188784480537Google Scholar
Giere, O (2009) Meiobenthology: The Microscopic Motile Fauna of Aquatic Sediments, 2nd Edn. Berlin: Springer.Google Scholar
Guidetti, P, Bianchi, CN, Chiantore, M, Schiaparelli, S, Morri, C and Cattaneo-Vietti, R (2004) Living on the rocks: substrate mineralogy and the structure of subtidal rocky substrate communities in the Mediterranean Sea. Marine Ecology Progress Series 274, 5768.10.3354/meps274057Google Scholar
Guyonnet, B, Grall, J and Vincent, B (2008) Modified otter trawl legs to reduce damage and mortality of benthic organisms in North East Atlantic fisheries (Bay of Biscay). Journal of Marine Systems 72, 216.10.1016/j.jmarsys.2007.05.017Google Scholar
Hall-Spencer, JM, Froglia, C, Atkinson, RJA and Moore, PG (1999) The impact of Rapido trawling for scallops, Pecten jacobaeus (L.), on the benthos of the Gulf of Venice. ICES Journal of Marine Science 56, 111124.10.1006/jmsc.1998.0424Google Scholar
Hiscock, K (1987) Subtidal rock and shallow sediments using diving. In Baker, JM and Wolff, W (eds), Biological Surveys of Estuaries and Coasts. New York, NY: Cambridge University Press, pp. 198237.Google Scholar
Hiscock, K and Hoare, R (1973) A portable suction sampler for rock epibiota. Helgolander Wiss. Meeresunters 25, 3538.10.1007/BF01609959Google Scholar
Jenkins, SR, Beukers-Stewart, BD and Brand, AR (2001) Impact of scallop dredging on benthic megafauna: a comparison of damage levels in captured and non-captured organisms. Marine Ecology Progress Series 215, 297301.10.3354/meps215297Google Scholar
Jennings, S, Pinnegar, J, Polunin, N and Warr, K (2001) Impacts of trawling disturbance on the trophic structure of benthic invertebrate communities. Marine Ecology Progress Series 213, 127142.10.3354/meps213127Google Scholar
Karalis, P, Antoniadou, C and Chintiroglou, C (2003) Structure of the artificial hard substrate assemblages in ports in Thermaikos Gulf (North Aegean Sea). Oceanologica Acta 26, 215224.10.1016/S0399-1784(03)00040-9Google Scholar
Kikuchi, RM, Fonseca-Gessner, AA and Shimizu, GY (2006) Suction sampler for collection of benthic macroinvertebrates in several continental aquatic environments: a comparative study with the Hess and Surber samplers. Acta Limnologica Brasiliensia 18, 2937.Google Scholar
Kruskal, WH and Wallis, WA (1952) Use of ranks in one-criterion variance analysis. Journal of the American Statistical Association 47, 583621.Google Scholar
Lotze, HK, Lenihan, HS, Bourque, BJ, Bradbury, RH, Cooke, RG, Kay, MC, Kidwell, SM, Kirby, MX, Peterson, CH and Jackson, JBC (2006) Depletion degradation, and recovery potential of estuaries and coastal seas. Science 312, 18061809.10.1126/science.1128035Google Scholar
Margalef, R (1958) Information theory in ecology. General Systems 3, 3671.Google Scholar
Mees, J and Jones, MB (1997) The hyperbenthos. Oceanography and Marine Biology: An Annual Review 35, 221255.Google Scholar
Mensink, BP, Fischer, CV, Cadee, GC, Ten Hallers-Tjabbes, CC and Boon, JP (2000) Shell damage and mortality in the common whelk Buccinum undatum caused by beam trawl fishery. Journal of Sea Research 43, 5364.10.1016/S1385-1101(00)00003-4Google Scholar
Metaxas, A and Scheibling, RE (1994) Spatial and temporal variability of tidepool hyperbenthos on a rocky shore in Nova Scotia, Canada. Marine Ecology Progress Series 108, 175184.10.3354/meps108175Google Scholar
Moschino, V, Deppieri, M and Marin, MG (2003) Evaluation of shell damage to the clam Chamelea gallina captured by hydraulic dredging in the Northern Adriatic Sea. Journal of Marine Science 60, 393401.Google Scholar
Pranovi, F, Raicevich, S, Franceschini, G, Torricelli, P and Giovanardi, O (2001) Discard analysis and damage to non-target species in the ‘rapido’ trawl fishery. Marine Biology 139, 863875.Google Scholar
Rostron, DM (2001) Procedural guideline No. 3-10. sampling marine benthos using suction samplers. In Davies, J, Baxter, J, Bradley, M, Connor, D, Khan, J, Murray, E, Sanderson, W, Turnbull, C and Vincent, M (eds), Marine Monitoring Handbook. Peterborough: Joint Nature Conservation Committee, pp. 293305.Google Scholar
Shannon, C and Weaver, W (1963) The Mathematical Theory of Communication. Urbana, IL: University of Illinois Press.Google Scholar
Sutherland, WJ (2006) Ecological Census Techniques: A Handbook, 2nd edn. Cambridge: Cambridge University Press.Google Scholar
Tanner, C, Hawkes, MW and Lebednic, PA (1977) A hand-operated suction sampler for the collection of subtidal organisms. Journal of the Fisheries Board of Canada 34, 10311034.Google Scholar
Veale, LO, Hill, AS, Hawkins, SJ and Brand, AR (2001) Distribution and damage to the by-catch assemblages of the northern Irish sea scallop dredge fisheries. Journal of the Marine Biological Association of the United Kingdom 81, 8596.Google Scholar
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