The marine diatom Pseudo-nitzschia galaxiae Lundholm et Moestrup has been recently described from Mexican and Australian plankton. In this paper, we illustrate the considerable morphological variability of the species in the Mediterranean Sea and present first evidence of its toxicity. In addition to lanceolate cells 25-41 m long, which fit the original description of the species, markedly larger (<82 m) and smaller (>10 m) specimens are commonly recorded. Cells of the largest size have almost parallel valve margins, while smaller specimens have extremely short rostrate ends and do not form colonies. Despite remarkable differences in shape and size, the typical ultrastructure of the species was observed for the different size classes in culture and in natural samples. In culture, cell length decreased at a rate of 1.1-2.1 m per month. Liquid chromatography-mass spectrometry (LC-MS) analyses revealed the presence of domoic acid (DA) at very low levels in two of seven strains analyzed. LSU rDNA analysis confirmed the identity of the species and showed a very low genetic variability for the strains from the Gulf of Naples, with no relationships with size and overall shape of the cells. A relatively high number (53) of Pseudo-nitzschia sequences were considered in the phylogenetic analysis, yet the relationships among species remain unclear, probably in relation with a recent speciation process in the genus. In natural samples, P. galaxiae populations of different cell sizes occurred at different times over the year, with smaller cells found in winter and early spring, and medium and larger cells peaking in late spring-summer. The maximum concentration value in the Gulf of Naples was recorded in May 1985 (9.4 × 10 6 cells l −1 ). From the analysis of a high number of both natural and culture samples, it is concluded that size and shape variations are indicative of different stages of the life cycle of P. galaxiae, which exhibit a synchronized and seasonal occurrence at the interannual scale.
The composition and seasonal cycle of the cryptomonad community were investigated at a coastal station in the Gulf of Naples (Mediterranean Sea) from March 2002 to March 2004. Serial dilution cultures were established from samples collected fortnightly in surface waters and single species abundances were estimated as most probable number. For species identification, unialgal cultures obtained by further dilution were analysed with light and scanning electron microscopy and spectrophotometry. Additional data collected at the same station and from other Mediterranean areas are also presented. Sixteen different morphs were recognized from 103 cultures. These included Plagioselmis prolonga, Proteomonas sulcata (haplomorph and diplomorph), Rhinomonas pauca, R. reticulata, Rhodomonas salina, R. cf. marina, Storeatula major, Teleaulax cf. acuta. Seven other morphs belonging to the genera Cryptochloris, Hemiselmis, Rhodomonas and Storeatula did not fit the descriptions of any described species, demonstrating a high rate of unknown diversity in the group. Total cryptomonad abundance showed peaks in spring-summer and autumn of both years. Some species were recorded occasionally, others (P. prolonga) throughout the year, still others (Hemiselmis sp., P. sulcata, R. pauca and R. reticulata) only at certain times of the year, the occurrence pattern recurring in both years. The species-specific occurrence patterns and the seasonal succession suggest that these species differ in their ecological requirements.
Phytoplankton community structure was analysed from 2010 to 2017 at C1-LTER, the coastal Long-Term Ecological Research station located in the Gulf of Trieste, which is the northernmost part of the Mediterranean Sea. Phytoplankton abundance and relevant oceanographic parameters were measured monthly in order to describe the seasonal cycle and interannual variability of the main phytoplankton taxa (diatoms, dinoflagellates, coccolithophores and flagellates) and to analyse their relationship with environmental conditions. Overall, phytoplankton abundances showed a marked seasonal cycle characterised by a bloom in spring, with the peak in May. During the summer, phytoplankton abundances gradually decreased until September, then slightly increased again in October and reached their minima in winter. In general, the phytoplankton community was dominated by flagellates (generally <10 µm) and diatoms co-occurring in the spring bloom. In this period, diatoms were also represented by nano-sized species, gradually replaced by larger species in summer and autumn. Phytoplankton assemblages differed significantly between seasons (Pseudo-F = 9.59; p < 0.01) and temperature and salinity were the best predictor variables explaining the distribution of the multivariate data cloud. At the interannual scale, a strong decrease of the late-winter bloom was observed in recent years with the spring bloom being the main phytoplankton increase of the year.
The section of the Liguro-Provencal basin north of the Balearic Islands is one of the most productive sites in the whole Mediterranean Sea, with intense phytoplankton bloom lasting about 2 months in late winter-early spring. The phytoplankton species composition of the area was investigated using light and electron microscopy to analyze bottle and net samples collected at several stations in spring 2000 and 2003. Serial dilution cultures established from bottle samples were also examined. A total of 168 phytoplankton taxa was identified, consisting of 73 Coscinodiscophyceae, 47 Dinophyceae, 25 Coccolithophyceae and 4 Prymnesiophyceae, 5 Prasinophyceae, 3 Chrysophyceae, 2 Cryptophyceae, 2 Dictyochophyceae, 1 Euglenophyceae, 1 Pelagophyceae, 1 Choanoflagellidea, 1 Filosea and 3 incertae sedis. We also provided a brief taxonomic description and original micrographs for 25 of the smallest and/or less known species identified in the study area, which may go undetected during routine microscopical analysis of fixed samples. Among these, 10 species were recorded for the first time in the Mediterranean Sea, confirming the need of detailed studies to reveal the biodiversity and biogeography of Mediterranean phytoplankton.
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