Project description:The general acclimation of cyanobacteria to low carbon (LC) conditions includes coordinated alterations of gene expression and metabolism. To analyze possible signals for LC sensing and compensating reactions, we compared wild-type (WT) cells with two mutants of Synechocystis, the carboxysome-less mutant ccmM and the photorespiratory mutant ΔglcD1/D2. Metabolic phenotyping revealed that the mutant ΔccmM accumulated high 2-phosphoglycolate (2PG) levels while the ΔglcD1/D2 mutant accumulated glycolate, indicating oxygenase activity of RubisCO at high carbon (HC). The changes in the metabolite spectrum were compared to alterations in the global gene expression pattern. Cells of HC-grown mutants ΔccmM and ΔglcD1/D2 showed altered mRNA levels for many genes involved in photosynthesis, high light stress, and N-assimilation, while LC-specific genes such as those for inorganic carbon (Ci) transporters were not increased. After a shift to LC, mutant ΔglcD1/D2 revealed gene expression changes similar to WT cells, while mutant ΔccmM showed no differential expression of most LC-induced genes under identical conditions. In fact, none of the genes for Ci transporters or other components of the carbon concentrating mechanism (CCM) displayed higher transcript levels in the ΔccmM mutant. This finding renders a direct role for 2PG as a metabolic signal component for the induction of CCM during LC acclimation less likely. Because, the transcription pattern of ΔglcD1/D2 under LC showed specific differences compared to WT, a potential role for glycolate as a signal molecule that may trigger expression of parts of the CCM is proposed. Transcriptional profiling of carboxysomal and photorespiratory mutants of Synechocystis sp. PCC 6803 under high carbon (HC) and low carbon (LC) conditions relative to the wildtype response.

Project description:Like many other organisms, cyanobacteria exhibit rhythmic gene expression with a period length of 24 hours to adapt to daily environmental changes. In the model organism Synechococcus elongatus PCC 7942 the central oscillator consists of three proteins: KaiA, KaiB and KaiC and utilizes the histidine kinase SasA and its response regulator RpaA as output-signaling pathway. Synechocystis sp. PCC 6803 contains two additional homologs of the kaiB and kaiC genes. Here we demonstrate that RpaA interacts with the core oscillator KaiAB1C1 of Synechocystis sp. PCC 6803 via SasA, similar to Synechococcus elongatus PCC 7942. However, interaction with the additional Kai homologs was not detected, suggesting different signal transduction components for the clock homologs. Inactivation of rpaA in Synechocystis sp. PCC 6803, lead to reduced viability of the mutant in light-dark cycles that aggravated under mixotrophic growth conditions. Chemoheterotrophic growth in the dark was abolished completely. In accordance, transcriptomic data revealed that RpaA is involved in the regulation of genes related to CO2‑acclimation and carbon metabolism under diurnal light conditions. Further, our results indicate that RpaA functions in the posttranslational regulation of glycogen metabolism as well, and a potential link between the circadian clock and motility was identified.

Project description:The NDH1 complex fulfils numerous tasks in the cyanobacterial cell such as respiration, cyclic electron flow, and inorganic carbon concentration. Despite the immense progress in our understanding of structure/function relation of the cyanobacterial NDH1 complex, the subunits catalysing the NAD(P)H docking and oxidation are still missing. The gene sml0013 of Synechocystis 6803 encodes for a small protein of unknown function for that homologs exist in all completely known cyanobacterial genomes. The protein exhibits weak similarities to the NDF6 protein, which was reported from Arabidopsis chloroplasts as a NDH subunit (Ishikawa et al. 2008). A sml0013 inactivation mutant of Synechocystis 6803 was generated and characterized. It showed only weak differences regarding growth and pigmentation at various culture conditions; most remarkably it exhibited a glucose-sensitive phenotype in the light. The genome-wide expression pattern of the M-NM-^Tsml0013::Km mutant was almost identical to wild type when grown under high CO2 conditions as well as after shifts to low CO2 conditions. However, measurements of the photosystem I redox kinetic in cells of the M-NM-^Tsml0013::Km mutant revealed differences to wild type such as a decreased capability of cyclic electron flow as well as of utilization of electrons from catabolic processes. These results suggest that the Sml0013 protein (named NdhP) represent a novel subunit of the cyanobacterial NDH1 complex mediating its coupling to the respiratory or photosynthetic electron flow. Gene expression of Synechocystis sp. PCC 6803 WT and a M-NM-^Tsml0013::Km mutant was monitored at HC conditions (5% CO2) and at 24h after a shift to LC conditions (ambient air containing 0.035% CO2). Each condition was sampled in biological duplicates.

Project description:To investigate acclimation mechanisms employed under extreme high light conditions, gene expression analysis was performed using the model microalgae Synechocystis sp. PCC 6803 (PCC 6803) cultured under various light intensities. From the low to the mid light conditions, the expression of genes related to light harvesting systems was repressed, whereas that of CO2 fixation and of D1 protein turnover-related genes was induced. Gene expression data also revealed that the down-regulation of genes related to flagellum synthesis (pilA2), pyridine nucleotide transhydrogenase (pntA and pntB), and sigma factor (sigA and sigF) represents acclimation mechanisms of PCC 6803 under excessive high light conditions.

Project description:Quantification of circadian gene expression in WT Synechocystis sp. PCC 6803 cells

Project description:Gene expression changes were followed in cultures of the cyanobacterium Synechocystis sp. PCC 6803 three and 24 hours after shift from high carbon (HC) to low carbon (LC) concentrations. The acclimation to fluctuating inorganic carbon (Ci) concentrations is crucial for photoautotrophic organisms living in aquatic environments such as cyanobacteria. The PII-like regulator protein SbtB binds the second messengers cAMP or c-diAMP and is involved in the acclimation to LC. Here, we investigated the impact of SbtB and of second messengers on gene expression changes during this acclimation response. We analyzed cultures of the wild type (WT), the ΔsbtB mutant lacking the PII-like regulator protein SbtB, the ΔcyaI mutant, lacking the main soluble adenylate cyclase for cAMP production and ΔdacA, lacking the diadenylate cyclase for c-diAMP production. The majority of LC-induced genes behaved in these mutants like in wild type. However, a defined subset of LC-regulated genes in WT was found to be changed in mutant ΔsbtB already under high CO2. Collectively, the results indicate that SbtB regulates a particular subset of genes during the LC acclimation response.

Project description:Gene expression changes were followed in cultures of the cyanobacterium Synechocystis sp. PCC 6803 three and 24 hours after shift from high carbon (HC) to low carbon (LC) concentrations. The acclimation to fluctuating inorganic carbon (Ci) concentrations is crucial for photoautotrophic organisms living in aquatic environments such as cyanobacteria. The PII-like regulator protein SbtB binds the second messengers cAMP or c-diAMP and is involved in the acclimation to LC. Here, we investigated the impact of SbtB and of second messengers on gene expression changes during this acclimation response. We analyzed cultures of the wild type (WT), the ΔsbtB mutant lacking the PII-like regulator protein SbtB, the ΔcyaI mutant, lacking the main soluble adenylate cyclase for cAMP production and ΔdacA, lacking the diadenylate cyclase for c-diAMP production. The majority of LC-induced genes behaved in these mutants like in wild type. However, a defined subset of LC-regulated genes in WT was found to be changed in mutant ΔsbtB already under high CO2. Collectively, the results indicate that SbtB regulates a particular subset of genes during the LC acclimation response.

Project description:Gene expression changes were followed in cultures of the cyanobacterium Synechocystis sp. PCC 6803 three and 24 hours after shift from high carbon (HC) to low carbon (LC) concentrations. The acclimation to fluctuating inorganic carbon (Ci) concentrations is crucial for photoautotrophic organisms living in aquatic environments such as cyanobacteria. The PII-like regulator protein SbtB binds the second messengers cAMP or c-diAMP and is involved in the acclimation to LC. Here, we investigated the impact of SbtB and of second messengers on gene expression changes during this acclimation response. We analyzed cultures of the wild type (WT), the ΔsbtB mutant lacking the PII-like regulator protein SbtB, the ΔcyaI mutant, lacking the main soluble adenylate cyclase for cAMP production and ΔdacA, lacking the diadenylate cyclase for c-diAMP production. The majority of LC-induced genes behaved in these mutants like in wild type. However, a defined subset of LC-regulated genes in WT was found to be changed in mutant ΔsbtB already under high CO2. Collectively, the results indicate that SbtB regulates a particular subset of genes during the LC acclimation response.

Project description:Targeted proteome analysis of Synechocystis sp. PCC 6803 under photoautotrophic and mixotrophic conditions

Project description:To identify novel phototransduction pathways in cyanobacteria, mutants defective for phytochrome-related proteins in Synechocystis sp. PCC 6803 that exhibit increased or decreased gene expression levels. were screened. Keywords: array-based