Biogeosciences Plankton in the open Mediterranean Sea: a review
Yüklə 0,96 Mb. Pdf görüntüsü
|
- Bu səhifədəki naviqasiya:
- 3.2.3 The colonial and large diatoms
I. Siokou-Frangou et al.: Mediterranean plankton 1555
Fig. 10. Longitudinal differences in the distribution of selected autotrophic picoeukaryotes during the cruise PROSOPE from Gibraltar to the Southern Cretan Sea in September 1999. The distribution of the different taxa is represented as their percentage to the total eukaryotes estimated with quantitative PCR. Chlorophytes were abundant in deep and intermediate layers in the WMS, whereas Ostreococcus, Bathycoccus and other Mamiellales were only abundant at intermediate depths in the Sicily Channel. Reproduced with permission from Marie et al. (2006). 83
totrophic picoeukaryotes during the cruise PROSOPE from Gibral- tar to the Southern Cretan Sea in September 1999. The distribution of the different taxa is represented as their percentage to the to- tal eukaryotes estimated with quantitative PCR. Chlorophytes were abundant in deep and intermediate layers in the WMS, whereas Os- treococcus, Bathycoccus and other Mamiellales were only abundant at intermediate depths in the Sicily Channel. Reproduced with per- mission from Marie et al. (2006). Aegean Sea (Ignatiades et al., 1995), South Adriatic and Ionian Seas (Rabitti et al., 1994). A consistent proportion of coccolithophores was also reported in winter offshore of the Catalan Front (Estrada et al., 1999) and in spring in the Aegean Sea (Ignatiades et al., 2002), while maximum fluxes were recorded in winter-spring in the central EMS (Ziveri et al., 2000). In a trans-Mediterranean study conducted in June 1999, coccolithophores were more abundant and di- versified at eastern stations than at western ones (Ignatiades et al., 2009). Much less known is the diversity and distri- bution of non-calcifying prymnesiophytes (e.g., Imantonia and Chrysochromulina species), which can only be identi- fied with special techniques (electron microscopy or molec- ular tools). Among the few species mentioned in this group are those of the genus Phaeocystis, which may form large, recognisable colonies (see the section on microplankton be- low), but are not easily detected when they are in the flagel- late stage. Cryptophytes, often only detected by their marker pigment alloxanthin, are generally more abundant when diatoms are also abundant, e.g., in winter and spring at the DYFAMED station (Vidussi et al., 2001; Marty et al., 2002) or in the Cretan Sea (Gotsis-Skretas et al., 1999). Plagioselmis pro- longa is one of the most frequently mentioned species in this group. However, reports of cryptophyte species from light microscopy investigations should all be reconsidered, since most species can only be recognised in live samples or using electron microscopy (Cerino and Zingone, 2007). As for small dinoflagellates, they mainly include naked au- totrophic and heterotrophic species which are poorly known and are not identifiable in light microscopy. In addition, their pigment signature may overlap with that of other flagellate groups. All information about these nano-dinoflagellates de- rives from microscopic counts, based on which they are less abundant than flagellates but much larger and hence more important in terms of biomass, especially in late spring and summer. In the eastern basin, dinoflagellates were reported to be dominant in different seasons and especially in strat- ified conditions (Berland et al., 1987; Gotsis-Skretas et al., 1999; Totti et al., 2000; Psarra et al., 2000; Ignatiades et al., 2002), although the flagellates <5 µm were not counted in these studies. Some small thecate species such as Proro-
but they are generally not abundant in MS offshore waters. 3.2.3 The colonial and large diatoms The general rule that the contribution of picoplankton and nanoplankton decreases along with the increase of chl a concentration (Li, 2002) is also valid for the MS. Where this occurs, colonial and microplanktonic diatoms (larger than 20 µm) belonging to several genera (Asterionellop- sis, Chaetoceros, Pseudo-nitzschia, Thalassionema, Thalas- siosira) become more important. In the following section, specific examples are provided of the distribution of mi- croplanktonic diatoms in association with relatively dense biomass accumulation, namely in i) the winter bloom, ii) the deep convection, gyre and front areas, and iii) the summer- autumn DCM. A diatom increase is evident at many sites of the WMS (Claustre et al., 1994; Marty et al., 2002) and EMS (Wass- mann et al., 2000; Gacic et al., 2002) in February-March, confirming the consistent anticipation of the vernal bloom as “the unifying signature” of the basin (Margalef and Castellv´ı, 1967; Duarte et al., 1999). However these events are very ephemeral and hence not always detected in offshore wa- ters. For example, a diatom increase is regularly recorded at DYFAMED in February–March (Fig. 10), but an actual bloom is missed by the monthly measurements of primary production (Marty and Chiaverini, 2002). No diatom bloom was detected either during a February cruise in the Adriatic Sea (Totti et al., 1999), whereas in January and in March di- atoms reached 58 and 37%, of the >5 µm fraction of the phy- toplankton, respectively, in the Cretan Sea (Gotsis-Skretas et al., 1999), and 88% at shelf stations (Psarra et al., 2000). Notably, massive sedimentation events are often recorded in the MS in winter (Miquel et al., 1994; Stemmann et al., 2002), suggesting that diatom blooms in this season are scarcely exploited by zooplankton populations (Duarte et al., 1999; Ribera d’Alcal´a et al., 2004). In fact, they consti- tute a resource for the zoobenthos of the underlying bottom (L´opez et al., 1998; Zupo and Mazzocchi, 1998), for which winter is not a resting period (Coma et al., 2000), probably as an adaptation to the recurrent food rain from above (Duarte et al., 1999; Calbet, 2001). In addition to during the winter bloom, diatoms also dom- inate, and for longer periods, in deep convection areas. Here, www.biogeosciences.net/7/1543/2010/ Biogeosciences, 7, 1543–1586, 2010 Yüklə 0,96 Mb. Dostları ilə paylaş:
|