Project description:Prochlorococcus is an abundant, cosmopolitan, marine cyanobacterium with ecotypes that vary temporally and spatially across oligotrophic regions of the global ocean. This group of organisms can serve as a model system to understand the accumulation of organic compounds synthesized by primary producers in marine ecosystems. We applied targeted metabolomics to three axenic cultures of strains that span the Prochlorococcus phylogeny: a high-light adapted HLII-clade strain, a low-light adapted LLI-clade strain, and a low-light adapted LLIV-clade strain. Intracellular metabolites were extracted from cells captured in exponential growth and extracellular metabolites were adsorbed, from the same samples, to solid-phase extraction resin. Both pools were quantified using a triple quadrupole mass spectrometer. The resulting data reveal intraspecific differences in metabolites that provide clues about the selective pressures shaping the meta-metabolism of the Prochlorococcus collective, and its interactions with the surrounding microbes that depend on them.

Project description:High light-adapted strain

Project description:Low light-adapted strain

Project description:We investigated light dependent gene expression changes in the marine ochrophyte Nannochloropsis oceanica CCMP1779. These algae have several putative blue light photoreceptors but appear to lack red light photoreceptors. To study early light signaling in N. oceanica and avoid as much as possible secondary downstream events, we quantified gene expression changes in dark-adapted cells after a short blue or red light pulse. More genes were differentially expressed under blue than under red light. In addition, fold change in expression was smaller for the red light-treated samples. For example, the median fold change of induced genes was 3 for blue light and 2.5 for red light. Moreover, hierarchical cluster analysis showed that gene expression after red light treatment was more similar to the dark control than after blue light treatment.

Project description:Marine Synechococcus, together with Prochlorococcus, contribute to a significant proportion of the primary production on Earth. The spatial distribution of these two groups of marine picocyanobacteria depends on different factors such as nutrients availability or temperature. Some Synechococcus ecotypes thrive in mesotrophic and moderately oligotrophic waters, where they exploit both oxidized and reduced forms of nitrogen. Here, we present a comprehensive study, which includes transcriptomic and proteomic analyses of the response of Synechococcus sp. strain WH7803 to nanomolar concentrations of nitrate, compared to ammonium or nitrogen starvation. We found that Synechococcus has a specific response to nanomolar nitrate concentration that differs to the response showed under nitrogen starvation or the presence of standard concentrations of either ammonium or nitrate. This fact suggests that the particular response to the uptake of nanomolar concentration of nitrate could be an evolutionary advantage for marine Synechococcus against Prochlorococcus in the natural field.

Project description:Oligotrophic marine bacterium

Project description:Oligotrophic marine bacterim

Project description:Low light-adapted cyanobacterium

Project description:High light-adapted cyanobacterium

Project description:Samples collect to investigate the gene activity from microbial populations in marine steel corrosion, and to compare with gene activity in water and bed sediment samples from the surrounding area. The study was undertaken to (1) investigate mechanisms of microbially influenced corrosion (MIC) of marine steel, and (2) compare microbial population gene activity between corrosion and the surrounding environment. Purified DNA (1µg) was labelled with Cy3, purified and hybridised at 42°C for 16h with the GeoChipTM 5.0 on a MAUI hybridisation station (BioMicro, USA).