A polyphasic approach to assess the cyanobacterial diversity of summer samples from Czech reservoirs

We used a polyphasic approach combining data from microscopic assessment of fresh biomass and from clone libraries and DGGE fingerprints based on 16S rRNA gene sequences to investigate the cyanobacterial diversity of Czech reservoirs during the summer in 2001 and 2002. In total, 15 genera were identified using the microscopic analysis in 38 samples analysed. They were Aphanizomenon, Anabaena, Anabaenopsis, Aphanocapsa, Aphanothece, Pseudanabaena, Planktothrix, Planktolyngbya, Limnothrix, Woronichinia, Snowella, Romeria, Microcystis, Merismopedia, and Coelomoron. We recovered 113 DGGE band sequences from the same samples. In addition, 128 partial 16S rRNA sequences were obtained from two clone libraries of reservoirs Pilská and Orlík. The phylogenetic comparison with the currently available rRNA sequences in databases showed that our sequences belonged to 8 clusters: Woronichinia, Microcystis, Synechococcus, Snowella, Planktothrix, Anabaena/Aphanizomenon, Limnothrix and a plastid related to Chrysochromulina polylepis. The microscopic enumeration and the molecular results were generally congruent concerning the major populations determined in these samples (for 32 samples among 38). Anabaena/Aphanizomenon, Microcystis and Woronichinia were the major genera in the Czech reservoirs during summer, and were present in most of the samples. This study showed some discrepancies between the genera retrieved by the traditional method and the molecular analyses. Differences concerned the presence of minor populations belonging to Aphanothece, Romeria, Merismopedia, Synechococcus, Snowella and Pseudanabena. These differences could be explained by biases specific to each method (competitive amplification, difficulty to obtain sequences from DGGE bands, not precise microscopic observation of the small-sized genera).MIDI-CHI

Extracellular phosphatases produced by phytoplankton and other sources in shallow eutrophic lakes (Wuhan, China): taxon-specific versus bulk activity

Extracellular phosphatases are an important part of the phosphorus cycle in aquatic environments. Phosphatase activity (PA) in plankton was studied in seven subtropical shallow lakes of different exploitation management and trophic status in the urban area of Wuhan City. Bulk PA was rather high (range 1.1-11 mu mol l(-1) h(-1)), although concentrations of soluble reactive phosphorus (SRP) were also high (range 27 mu g P l(-1) to similar to 1.5 mg P l(-1)) in all lakes. Cell-associated extracellular PA in phytoplankton was detected using the fluorescence-labelled enzyme activity technique. Phytoplankton species partly contributed to the bulk PA. We found explicit differences in the presence of cell-associated phosphatase within the main phytoplankton groups; species belonging to Chlorophyta and Dinophyta were regularly phosphatase-positive, while Cyanophyta and Bacillariophyceae were phosphatase-negative in all but one case. Furthermore, there is a certain potential of extracellular phosphatases produced by heterotrophic nanoflagellates in most of the lakes. This new finding compromises the 'traditional' interpretation of bulk phosphatase data as being due to overall phytoplankton or bacterial P regeneration.Extracellular phosphatases are an important part of the phosphorus cycle in aquatic environments. Phosphatase activity (PA) in plankton was studied in seven subtropical shallow lakes of different exploitation management and trophic status in the urban area of Wuhan City. Bulk PA was rather high (range 1.1-11 mu mol l(-1) h(-1)), although concentrations of soluble reactive phosphorus (SRP) were also high (range 27 mu g P l(-1) to similar to 1.5 mg P l(-1)) in all lakes. Cell-associated extracellular PA in phytoplankton was detected using the fluorescence-labelled enzyme activity technique. Phytoplankton species partly contributed to the bulk PA. We found explicit differences in the presence of cell-associated phosphatase within the main phytoplankton groups; species belonging to Chlorophyta and Dinophyta were regularly phosphatase-positive, while Cyanophyta and Bacillariophyceae were phosphatase-negative in all but one case. Furthermore, there is a certain potential of extracellular phosphatases produced by heterotrophic nanoflagellates in most of the lakes. This new finding compromises the 'traditional' interpretation of bulk phosphatase data as being due to overall phytoplankton or bacterial P regeneration