Biogeosciences Plankton in the open Mediterranean Sea: a review
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1570 I. Siokou-Frangou et al.: Mediterranean plankton spring blooms, i.e., in the Gulf of Lion, Ligurian Sea, and North Aegean Sea (Andersen et al., 2001a; Siokou-Frangou et al., 2004; Calbet et al., 2007). This distribution indicates a rather modest adaptability of C. typicus to fluctuations in food availability (Calbet et al., 2007), despite its capacity of feeding on a wide spectrum of prey types. Given the oligotrophic status of the MS, prey availability can affect mesozooplankton. Food limitation is suggested to occur in the Catalan Sea, since mesozoooplankton ingestion rates correlate with food availability but are lower than in ex- perimental studies (Saiz et al., 2007). Food limitation may lead to competition among mesozooplankters in the open MS. However, the ability to exploit different food sources may overcome this problem and allow the co-occurrence of various and numerous taxa. This is suggested by grazing experiments conducted in the coastal Catalan Sea, where doliolids, small copepods and cladocerans show clear food niche separation (Katechakis et al., 2004). 5.7 Grazing impact The prey preference of copepods could significantly affect ciliate abundance, exerting a strong top down control on their populations. This control has been hypothesized as the ma- jor factor for the low standing stock of ciliates across the en- tire MS (Dolan et al., 1999; Pitta et al., 2001). Additionally, in situ measurements indicate that mesozooplankton graz- ing impact on phytoplankton can be significant. Namely, in the Gulf of Lion, the percentage of primary production re- moved by zooplankton grazing was estimated to be impor- tant in both winter (47%) and spring (50%) (Gaudy et al., 2003). Previous estimations in the area suggested that half of the phytoplankton loss from March to April should be due to zooplankton grazing (Nival et al., 1975). In the very oligotrophic South Aegean Sea, copepods grazed 14% (in March) to 35% (in September) of the primary production from cells >3 µm (Siokou-Frangou et al., 2002). The graz- ing impact would be even higher had these estimates in- cluded copepod nauplii and small copepodites as well as groups with high growth rates such as appendicularians (Saiz et al., 2007). In the North-East Aegean Sea, small copepods (Oncaea spp., small Clausocalanus species, Paracalanus parvus) showed a considerably higher grazing impact on phytoplankton production (almost 100% during September) as compared to larger copepods (C. helgolandicus, C. typ-
agreement with the statement by Calbet et al. (2001) that zoo- plankton should exert a tighter control on autotrophs in olig- otrophic environments than in productive systems. However, data available for the open MS are still too few to provide conclusive evidence. Experiments providing information on the grazing im- pact of other mesozooplankton groups (e.g., appendicular- ians, doliolids, salps, ostracods) on autotrophs and micro- heterotrophs are lacking for the open MS. As for the rare studies on the feeding impact of carnivorous zooplankton, the predation pressure exerted by chaetognaths on copepod standing stocks appeared overall negligible in the Catalan Sea (Dur´o and Saiz, 2000, <1%), whereas it varied between 0.3 and 7.8% in several areas of the EMS (Kehayias, 2003). A good coupling between mesozooplankters and their prey is suggested by the horizontal patterns of mesozooplankton in the open MS, which match those of autotrophic biomass and production (e.g., the west-to-east decrease) and, to a lesser extent, those of microheterotrophs. This coupling also occurs at a smaller scale, in the frontal areas of the Lig- urian, Catalan and North Aegean Seas (Saiz et al., 1992; Alcaraz et al., 1994; Pinca and Dallot, 1995; Alcaraz et al., 2007; Zervoudaki et al., 2007). However, occasionally the areas of the maximum zooplankton abundance do not coin- cide with those of the highest phytoplankton concentration (Calbet et al., 1996, e.g., in the Catalan Sea,), and this con- trast might be attributed to factors other than nutrition, such as zooplankton mortality due to predation.
Mesozooplankton is the major prey of small pelagic fish (both larvae and adults) in the MS. Diet and diel feeding of anchovy larvae in the WMS suggest that their distribution is trophically-driven and closely connected to the occurrence of DZM in summer (Sabat´es et al, 2007). Indeed, in the Al- gerian basin, the Catalan Sea and the Gulf of Lion, larvae of Engraulis encrasicolus feed mostly on copepods (C. typ- icus, T. stylifera, M. rosea, Clausocalanidae-Paracalanidae) and, to a lesser extent, on molluscs, cladocerans, other crus- taceans and appendicularians (Tudela and Palomera, 1995, 1997; Plounevez and Champalbert , 2000; Bacha and Amara, 2009). In particular, copepod nauplii and copepodites are the major prey items of anchovy and sardine larvae in the Adriatic Sea and in the WMS (Tudela and Palomera, 1995; Stergiou et al., 1997; Tudela and Palomera, 1997; Plounevez and Champalbert , 2000; Coombs et al., 2003; Bacha and Amara, 2009; Morote et al., 2010). In the Adriatic Sea, sar- dine adults and larvae seem to feed on phytoplankton too (Rasoanarivo et al., 1991), while sprats feed on copepods, decapod larvae, cladocerans and chaetognaths (Ticina et al, 2000). Borme et al. (2009) report that the principal prey of all size classes of E. encrasicolus in the NW Adriatic Sea are small-sized copepods (0.2–0.6 mm in prosome length), such as Euterpina acutifrons and Oncaea spp. These au- thors comment that the observed preference of anchovy for these few copepod species might be related to their abun- dance, but also to species-specific behavioural (e.g., swim- ming patterns, patchy distribution) and/or physical charac- teristics (e.g., colour, bioluminescence) of the prey. The constant and important presence of copepods in the diet of anchovies and clupeids reported above, and the rel- evant portion (20%) of total zooplankton production esti- mated to be consumed by adult anchovies in the Catalan Sea Biogeosciences, 7, 1543–1586, 2010 www.biogeosciences.net/7/1543/2010/ Yüklə 0,96 Mb. Dostları ilə paylaş:
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