Salinity tolerance as a factor controlling spatial patterns in composition and structure of zooplankton in the Guadalquivir estuary

Trabajo presentado en ECSA 56 (Coastal systems in transition: From a 'natural' to an 'anthropogenically-modified' state), celebrado en Bremen del 4 al 7 de septiembre de 2016.N

Population dynamic and trophic position of mysid community demonstrates its key role for nursery function in a temperate estuary

Guadalquivir Estuary is a main nursery ground of marine goal species for Gulf of Cadiz fisheries. It is a well-mixed temperate estuary with horizontal salinity gradient and clear seasonal water temperature trend. Mysid community with Mesopodopsis slabberi, Neomysis integer and Rhopalophthalmus tartessicus make up to over 80% of total macrofauna biomass in the estuary. Life history, population structure, secondary production, trophic level and community spatio-temporal dynamic were unravelled combining analysis of long term 16y monitoring data with 2y of in depth population analysis and trophic biomarker studies. Results show a key trophic role in food web, a seasonal trend showing density peaks ( 23, 3 and 6 mg/m3, respectively) in spring-summer and winter marine coastward migration. Despite being euryhaline, the three species of showed unevenly spatial distribution, being salinity the variable best explaining structure changes of mysid assemblage. Inter- and intra-specific euryhalinity differences both for prey and predators seem to determine the entire spatial estuarine community distribution. High secondary production (P/B rates 38.2, 10.3 and 10.7) and food web studies confirm key role of mysids transferring energy up to juveniles (fish and crustaceans) arriving yearly in spring to their nursery area

Aspects of phosphorus physiology associated with phosphate-induced polar lipid remodelling in marine microalgae

Marine microalgae exhibit a diversified phosphorus physiology and have also been recently found to show high inter-taxa variability in their phosphate induced-polar lipids' remodelling. Identification of phosphorus physiology aspects that are more related to lipid remodelling can contribute to better understanding of such intricate phytoplankton lipid metabolism. Therefore, some aspects of phosphorus physiology related to its uptake, storage and use were evaluated in a taxonomically diversified group of nine marine microalgae that was arranged into three subgroups, each of them including species showing similar polar lipid responses to phosphate. Luxury phosphate uptake (PU) was the physiological aspect best associated to microalgal polar lipid metabolism as it was maximal in species (Picochlorum atomus, Tetraselmis suecica and Nannochloropsis gaditana) that were able to counterbalance between phospholipids (PL) and betaine lipids (BL). Cryptophytes (Rhodomonas baltica, Chroomonas placoidea), characterized by their constitutive BL and flexible PL contents in response to phosphate, had almost no luxury PU and showed higher phosphorus cell quota (QP) under phosphate deprivation. Haptophyes (Isochrysis galbana, Diacronema vlkianum), with constitutive BL contents and permanently minimal PL contents, showed the lowest QP when deprived of phosphate while their luxury PU was below that for green microalgae. Induction of alkaline phosphatase activity following phosphate depletion was maximal in diatoms (Phaeodactylum tricornutum, Chaetoceros gracilis) and I. galbana but it was unrelated to lipid remodelling. Despite strong influence of taxonomy, polar lipid remodelling accounted for 38.8% of total variation when microalgae were ordinated using their physiological responses to phosphorus as descriptive variable

Common and species-specific effects of phosphate on marine microalgae fatty acids shape their function in phytoplankton trophic ecology

The use of fatty acids (FA) to infer structure of phytoplankton assemblages and as indicators of microalgae nutritional value is acquiring relevance in modern phytoplankton ecology and new advances concerning factors influencing FA variability among microalgae are demanded. In this regard, the relationship between phosphorus and FA remains particularly little studied in marine phytoplankton. In the present study, we focus on phosphate effects on FA from a diversified set of marine microalgae and provide new insights into the applicability of FA in phytoplankton trophic ecology. Phosphate deprivation mainly induced monounsaturated FA production in eight out of nine microalgae and their changes were species-specific, with palmitoleic acid exhibiting extreme variation and discriminating between haptophyte classes. The important phosphate-induced and interspecific variability found for oleic acid was perceived as a concern for the current application of this FA as a trophic position indicator in grazers. Chloroplast C-16 and C-18 polyunsaturated FA were more affected by phosphate than C-20 and C-22 highly unsaturated FA (HUFA). The relative stability of stearidonic acid to phosphate in cryptophytes and haptophytes pinpointed this FA as a suited marker for both microalgae groups. Taken all species together, phosphate deprivation and taxonomy accounted for 20.8 and 50.7% of total FA variation, respectively. HUFA were minimally affected by phosphate indicating their suitability as indicators of phytoplankton trophic value. The asymptotic relationship between HUFA and phosphorus cell content suggested mineral composition (phosphorus) could be more important than HUFA content as attribute of marine microalgae nutritional value at the species level

Exploring occurrence and molecular diversity of betaine lipids across taxonomy of marine microalgae

Betaine lipids (BL) from ten microalgae species of the kingdoms Plantae and Chromista were identified and quantified by HPLC/ESI-TOF-MS. Diacylgyceryl-N-trimethylhomoserine (DGTS) was detected in Trebouxiophyceae and Eustigmatophyceae species, whereas Tetraselmis suecica was described as the first green algae containing diacylglyceryl-hydroxymethyl-N,N,N-trimethyl-beta-alanine (DGTA). DGTA molecular species where also characterized in Cryptophyceae species as well as in the Bacillariophyceae diatom Phaeodactylum tricornutum. The Mediophyceae diatom Chaetoceros gracilis had no DGTA, but contained diacylglyceryl-carboxyhydroxymethylcholine (DGCC). A principal coordinate (PCO) analysis of microalgae species revealed the existence of three main clusters around each BL type. The first PCO axis (43.9% of total variation) grouped Chlorophyceae, Trebouxiophyceae and Eustigmatophyceae species and positively correlated with DGTS. The second PCO axis (27.8% of total variation) segregated DGTA from DGCC containing species. Cryptophyceae, Bacillariophyceae and Chlorodendrophyceae were the more closely associated species to DGTA. Mediophyceae and Dinophyceae species contained DGCC as the only BL. Molecular diversity varied from the simplest DGCC composition in Gyrodinium dorsum to the highest spectrum of ten different molecular species detected for DGTA (Rhodomonas baltica) and DGCC (C. gracilis). The fatty acid profile of DGTS was very dissimilar to that of the whole lipid cell content. DGTS from Nannochloropsis gaditana was highly unsaturated respecting to total lipids, whereas in Picochlorum atomus DGTS unsaturation was nearly one half to that of total lipids. Dissimilarity between DGTA and total lipid fatty acid profile was minimum among all BL and DGTA fatty acid unsaturation was the maximum observed in the study. New DGCC molecular species enriched in 20:5 were described in Mediophyceae diatoms. Multivariate microalgae ordination using BL as descriptors revealed a higher chemotaxonomic potential than that based on their respective BL fatty acid profile. Nevertheless, taxonomic resolution was improved when fatty acids from the whole cell lipid pool were used

Short term primary production in western Mediterranean Sea phytoplankton

Thermal stratification of the water column promotes contrasting conditions with respect to irradiance level and nutrient concentration for phytoplankton growth, demanding more research on which environmental factor has more importance in determining the photosynthetic performance of the communities. For this purpose, two research surveys were performed in several coastal stations located in the Alboran Sea (Western Mediterranean Sea) at the end of 2008 and 2009 summers. Primary productivity was estimated by determining photosynthetic electron transport rates (ETRB ) and inorganic carbon assimilation rates (PPC B ) at two different depths within the water column, surface and chlorophyll a vertical maximum depth (CM). At the surface, communities presented similar photo-acclimation features during the two surveys, which were different from those obtained for the CM samples that grew at more favorable nutrient and light conditions. The acclimation response to surface conditions consisted in the reduction in the chlorophyll a (Chl a) cell content, and the increase in the Chl a specific light absorption coefficient [a*(λ)], initial slope of ETRB vs. Irradiance curves (αB ) and light saturation parameter (Ek), indicating that the communities were acclimated to stress conditions (i.e. high PAR and UVR dose and low nutrient availability). However, the in situ primary productivity was unaffected; on the contrary, both PPC B and ETRB in situ increased with respect to the values obtained for communities growing at CM depth. Furthermore, ΦETR,C (i.e. the molar ratio of transported e− to assimilated carbon) in surface samples was similar to CM samples (8.0 ± 3.5 compared with 7.5 ± 5.3 mol e− [mol−1 C], respectively). The analysed phytoplankton communities were mainly dominated by diatom. This corroborates that diatoms possess a greater capacity to cope with high irradiance levels, even at low nutrient concentrations registered during this study at surface waters