Oxidative Stress Responses in the Unicellular Cyanobacterium Synechococcus Pcc 7942

Oxidative stress responses were tested in the unicellular cyanobacterium synechococcus PCC 7942 (R-2). Cells were exposed to hydrogen peroxide, cumene hydroperoxide and high light intensities. The extent and time course of oxidative stress were related to the activities of ascorbate peroxidase and catalase. Ascorbate peroxidase was found to be the major enzyme involved in the removal of hydrogen peroxide under the tested oxidative stresse. Catalase activity was inhibited in cells, treated with high H₂O₂ concentrations, and was not induced under photooxidative stress. Catalase was specifically induced in cells treated with cumene hydroperoxide.

Superoxide dismutase activity increased under conditions generating superoxide, such as high light intensities. The induction of the antioxidative enzymes was light dependent and was inhibited by chloramphenicol.     

Phosphate Uptake in the Cyanobacterium Synechococcus R-2 PCC 7942

Phosphate uptake rates in Synechococcus R-2 in BG-11 media (anitrate-based medium, not phosphate limited) were measured usingcells grown semi-continuously and in continuous culture. Netuptake of phosphate is proportional to external concentration.Growing cells at pH_o 10 have a net uptake rate of about 600pmol m^–2 s^–1 phosphate, but the isotopic flux for³²P phosphate was about 4 nmol m^–2 s^–1. There appearsto be a constitutive over-capacity for phosphate uptake. TheK_m and V_max, of the saturable component were not significantlydifferent at pH_o 7.5 and 10, hence the transport system probablyrecognizes both H₂PO^–₄and HPO^2–₄. The intracellularinorganic phosphate concentration is about 3 to 10 mol m^–3,but there is an intracellular polyphosphate store of about 400mol m^–3. Intracellular inorganic phosphate is 25 to 50kJ mol^–1 from electrochemical equilibrium in both thelight and dark and at pH_o 7.5 and 10. Phosphate uptake is veryslow in the dark ( 100 pmol m^–2 s^–1) and is light-activated(pH_o 7.51.3 nmol m^–2 s^–1, pH_o 10600 pmol m^–2s^–1). Uptake has an irreversible requirement for Mg²⁺in the medium. Uptake in the light is strongly Na⁺-dependent.Phosphate uptake was negatively electrogenic (net negative chargetaken up when transporting phosphate) at pH_o 7.5, but positivelyelectrogenic at pH_o 10. This seems to exclude a sodium motiveforce driven mechanism. An ATP-driven phosphate uptake mechanismneeds to have a stoichiometry of one phosphate taken up perATP (1 PO_{4 in}/ATP) to be thermodynamically possible under allthe conditions tested in the present study. (Received June 16, 1997; Accepted September 4, 1997)     

Na-Independent HCO(3) Transport and Accumulation in the Cyanobacterium Synechococcus UTEX 625

The active transport and intracellular accumulation of HCO₃⁻ by air-grown cells of the cyanobacterium Synechococcus UTEX 625 (PCC 6301) was strongly promoted by 25 millimolar Na⁺.Na⁺-dependent HCO₃⁻ accumulation also resulted in a characteristic enhancement in the rate of photosynthetic O₂ evolution and CO₂ fixation. However, when Synechococcus was grown in standing culture, high rates of HCO₃⁻ transport and photosynthesis were observed in the absence of added Na⁺. The internal HCO₃⁻ pool reached levels up to 50 millimolar, and an accumulation ratio as high as 970 was observed. Sodium enhanced HCO₃⁻ transport and accumulation in standing culture cells by about 25 to 30% compared with the five- to eightfold enhancement observed with air-grown cells. The ability of standing culture cells to utilize HCO₃⁻ from the medium in the absence of Na⁺ was lost within 16 hours after transfer to air-grown culture and was reacquired during subsequent growth in standing culture. Studies using a mass spectrometer indicated that standing culture cells were also capable of active CO₂ transport involving a high-affinity transport system which was reversibly inhibited by H₂S, as in the case for air-grown cells. The data are interpreted to indicate that Synechococcus possesses a constitutive CO₂ transport system, whereas Na⁺-dependent and Na⁺-independent HCO₃⁻ transport are inducible, depending upon the conditions of growth. Intracellular accumulation of HCO₃⁻ was always accompanied by a quenching of chlorophyll a fluorescence which was independent of CO₂ fixation. The extent of fluorescence quenching was highly dependent upon the size of the internal pool of HCO₃⁻ + CO₂. The pattern of fluorescence quenching observed in response to added HCO₃⁻ and Na⁺ in air-grown and standing culture cells was highly characteristic for Na⁺-dependent and Na⁺-independent HCO₃⁻ accumulation. It was concluded that measurements of fluorescence quenching provide an indirect means for following HCO₃⁻ transport and the dynamics of intracellular HCO₃⁻ accumulation and dissipation.     

Growth Rate Regulation of rRNA Content of a Marine Synechococcus (Cyanobacterium) Strain

The relationship between growth rate and rRNA content in a marine Synechococcus strain was examined. A combination of flow cytometry and whole-cell hybridization with fluorescently labeled 16S rRNA-targeted oligonucleotide probes was used to measure the rRNA content of Synechococcus strain WH8101 cells grown at a range of light-limited growth rates. The sensitivity of this approach was sufficient for the analysis of rRNA even in very slowly growing Synechococcus cells (μ = 0.15 day⁻¹). The relationship between growth rate and cellular rRNA content comprised three phases: (i) at low growth rates (<~0.7 day⁻¹), rRNA cell⁻¹ remained approximately constant; (ii) at intermediate rates (~0.7 − 1.6 day⁻¹), rRNA cell⁻¹ increased proportionally with growth rate; and (iii) at the highest, light-saturated rates (>~1.6 day⁻¹), rRNA cell⁻¹ dropped abruptly. Total cellular RNA (as measured with the nucleic acid stain SYBR Green II) was well correlated with the probe-based measure of rRNA and varied in a similar manner with growth rate. Mean cell volume and rRNA concentration (amount of rRNA per cubic micrometer) were related to growth rate in a manner similar to rRNA cell⁻¹, although the overall magnitude of change in both cases was reduced. These patterns are hypothesized to reflect an approximately linear increase in ribosome efficiency with increasing growth rate, which is consistent with the prevailing prokaryotic model at low growth rates. Taken together, these results support the notion that measurements of cellular rRNA content might be useful for estimating in situ growth rates in natural Synechococcus populations.     

Regulation of Nitrite Reductase Activity under CO2 Limitation in the Cyanobacterium Synechococcus sp. PCC7942

During photoautotrophic growth under CO2-limited conditions, cells of Synechococcus sp. PCC7942 excreted into the medium about 30% of the nitrite produced by reduction of nitrate. No nitrite was excreted under CO2-sufficient conditions. After transfer of high-CO2-grown cells to CO2-limited conditions, nitrite reductase activity started to decline within 0.5 h and decreased to 50% of the initial level in 3 h, whereas nitrate reductase activity was virtually unchanged. Nitrite started to accumulate in the medium about 3 h after the transfer of the cells to CO2-limited conditions and reached a concentration of >0.4 mM at 17 h. These findings suggested that the nitrite excretion was due to an imbalance of the activities of nitrite reductase and nitrate reductase. Since ammonium, the product of nitrite reduction, was not detected in the medium, it was concluded that the step of nitrite reduction limits the rate of nitrate assimilation under CO2-limited conditions. The extent of decrease in nitrite reductase activity under CO2-limited conditions was much larger than that caused by rifampicin (an inhibitor of RNA synthesis) treatment under high-CO2 conditions. Addition of CO2, in the form of sodium bicarbonate, to the CO2-limited culture increased the nitrite reductase activity, but rifampicin inhibited this increase. These findings suggested the presence of a mechanism that irreversibly inactivates nitrite reductase under CO2-limited conditions.     

Response of the Unicellular Diazotrophic Cyanobacterium Crocosphaera watsonii to Iron Limitation

Iron (Fe) is widely suspected as a key controlling factor of N₂ fixation due to the high Fe content of nitrogenase and photosynthetic enzymes complex, and to its low concentrations in oceanic surface seawaters. The influence of Fe limitation on the recently discovered unicellular diazotrophic cyanobacteria (UCYN) is poorly understood despite their biogeochemical importance in the carbon and nitrogen cycles. To address this knowledge gap, we conducted culture experiments on Crocosphaera watsonii WH8501 growing under a range of dissolved Fe concentrations (from 3.3 to 403 nM). Overall, severe Fe limitation led to significant decreases in growth rate (2.6-fold), C, N and chlorophyll a contents per cell (up to 4.1-fold), N₂ and CO₂ fixation rates per cell (17- and 7-fold) as well as biovolume (2.2-fold). We highlighted a two phased response depending on the degree of limitation: (i) under a moderate Fe limitation, the biovolume of C. watsonii was strongly reduced, allowing the cells to keep sufficient energy to maintain an optimal growth, volume-normalized contents and N₂ and CO₂ fixation rates; (ii) with increasing Fe deprivation, biovolume remained unchanged but the entire cell metabolism was affected, as shown by a strong decrease in the growth rate, volume-normalized contents and N₂ and CO₂ fixation rates. The half-saturation constant for growth of C. watsonii with respect to Fe is twice as low as that of the filamentous Trichodesmium indicating a better adaptation of C. watsonii to poor Fe environments than filamentous diazotrophs. The physiological response of C. watsonii to Fe limitation was different from that previously shown on the UCYN Cyanothece sp, suggesting potential differences in Fe requirements and/or Fe acquisition within the UCYN community. These results contribute to a better understanding of how Fe bioavailability can control the activity of UCYN and explain the biogeography of diverse N₂ fixers in ocean.     

Structure, Function and Regulation of the Nitrate Transport System of the Cyanobacterium Synechococcus sp. PCC7942

The active nitrate transport system of the cyanobacterium Synechococcussp. PCC7942 is encoded by the four genes nrtA, nrtB, nrtC andnrtD. It is essential for the growth of the cyanobacterium atphysiological concentrations of nitrate and has been shown tobe involved in the active transport of nitrite as well. Thededuced amino acid sequences of the NrtB, NrtC and NrtD proteinsindicate that the transporter is a member of the ABC (ATP-bindingcassette) superfamily of active transporters. Among the prokaryoticABC transporters, the cyanobacterial nitrate/nitrite transporteris unique in having a membrane-bound protein NrtA and an NrtA-likeextra domain linked to one of the ATP-binding subunits (C-terminaldomain of NrtC). Molecular biological, biochemical and physiologicalstudies suggest that NrtA is the substrate-binding protein requiredfor the transport of nitrate/nitrite and that the C-terminaldomain of NrtC has a regulatory role. Comparison of the structuresof nitrate transporters from eukaryotic and prokaryotic, photosyntheticand non-photosynthetic organisms indicate that the nrt nitrate/nitritetransporter represents a prokaryotic nitrate transporter distinctfrom the nitrate transporters of eukaryotes. ¹Recipient of the JSPP Young Investigator Award, 1994.     

Polarized Photoacoustic Spectra of the Cyanobacterium Synechococcus Oriented in Polymer Film

Photoacoustic spectra (PAS) were obtained for the cyanobacterium Synechococcus (Anacystis nidulans) cells embedded in isotropic and stretched polyvinyl alcohol films. The polarized radiation with the electric vector changing in 30° intervals with respect to given direction in a sample plane was used. Two cyanobacterium strains, one with very low biliprotein content, second with normal amount of biliproteins were investigated. The polarized absorption and fluorescence spectra were also measured. Conclusions were drawn about the thermal deactivation occurring in differently oriented pools of chromophores and about mutual orientation of their transition moments. Thermal deactivation in carotenoids (Cars) of both strains was different. The ratio of Car thermal deactivation to the thermal deactivation of chlorophyll (Chl) was higher in cyanobacteria with lower content of biliproteins than in the strain with normal amount of these complexes. Hence biliproteins can play the role in excitation energy transfer from Cars to Chls. For complex biological samples, polarized PAS can be a more sensitive method to investigate the directions of the absorption transition moments than the widely used polarized absorption spectra.     

Ionic Osmoregulation during Salt Adaptation of the Cyanobacterium Synechococcus 6311

The mechanisms of salt adaptation were studied in the cyanobacterium Synechococcus 6311. Intracellular volumes and ion concentrations were measured before and after abrupt increases of external NaCl concentrations up to 0.6 molar NaCl. Equilibrium volumes, measured with a rapid and accurate electron spin resonance spin probe method, showed that at low NaCl concentrations the cells did not shrink as expected for an impermeable solute. However, when the NaCl concentration exceeded a critical value, volume losses occurred. These losses were not fully reversed by hypoosmotic treatment, suggesting membrane damage. The critical value of irreversible volume loss paralleled the increase in salinity during cell growth. Rapid mixing experiments showed that exposure of Synechococcus 6311 to non-damaging NaCl concentrations caused water extrusion from the cells; the volume decreases were time resolved to about 200 milliseconds. Subsequently, volumes increased rapidly as NaCl moved into the cells. Controls recovered their volumes within 15 seconds, while salt-adapted cells grown at 0.6 molar NaCl required 1 minute for volume equilibration. This decrease in the rate of cell volume recovery indicates that salt adaptation is accompanied by changes in cell membrane properties. Subsequent to these initial rapid volume changes, a more gradual sequence of ion movement and sugar accumulation was observed. Under conditions for photoautotrophic growth, significant Na⁺ extrusion was observed 30 min after salt shock. Sucrose accumulation reached a maximum value after 16 hours and K⁺ accumulation reached equilibrium after 40 hours. The final concentrations of K⁺ and Na⁺ and sucrose and glucose inside the 0.6 molar NaCl-grown cells indicate that the inorganic ions and organic `compatible' solutes are the major osmotic species which account for the adaptation of Synechococcus 6311 to salt.     

Complete Genome Structure of the Unicellular Cyanobacterium Synechocystis sp. PCC6803

Cyanobacteria are photoautotrophic organisms capable of oxygen-producingphotosynthesis similar to that in eukaryotic algae and plants,and because of this, they have been used as model organismsfor the study of the mechanism and regulation of oxygen-producingphotosynthesis. To understand the entire genetic system in cyanobacteria,the nucleotide sequence of the entire genome of the unicellularcyanobacterium Synechocystis sp. PCC6803 has been determined.The total length of the circular genome is 3,573,470 bp, witha GC content of 47.7%. A total of 3,168 potential protein codinggenes were assigned. Of these, 145 (4.6%) were identical toreported genes, and 1,259 (39.6%) and 342 (10.8%) showed similarityto reported and hypothetical genes, respectively. The remaining1,422 (45.0%) showed no apparent similarity to any genes registeredin the databases. Classification of the genes by their biologicalfunction and comparison of the gene complement with those ofother organisms have revealed a variety of features of the geneticinformation characteristic of a photoautotrophic organism. Thesequence data, as well as other information on the Synechocystisgenome, is presented in CyanoBase on WWW [http://www.kazusa.or.jp/cyano/]. (Received July 24, 1997; Accepted September 17, 1997)     

Calcium and Phosphate Regulation of Nitrogen Metabolism in the Cyanobacterium Spirulina platensis Under the High Light Stress

High light stress (40 W/m²)-induced alterations in the nitrogen assimilatory enzymes in Spirulina platensis were studied under the Ca²⁺ and phosphate (Pi)-supplemented as well as starved conditions. Results revealed that activities of nitrate reductase (NR), amino acid transferases (AST/GOT and ALT/GPT), and protease enzymes in the high-light-incubated cells were relatively higher under the Ca²⁺- and Pi-starved conditions. On the contrary, relative rates of glutamine synthetase (GS) and ATPase activities were lower in the Ca²⁺- and Pi-starved cells. But the Spirulina cells under the Ca²⁺- and Pi-added conditions showed enhanced activity of both GS and ATPase enzymes. During the high-light stress, a decline in the GS activity, particularly under the Ca²⁺- and Pi-starved conditions, was indicative of a nitrogen starvation-like condition. This could be one of the reasons for induction of the NR and protease enzymes. A higher rate of GS activity was recorded under both the Ca²⁺- and Pi-supplemented conditions, perhaps owing to the enhanced rate of ATPase activity in such conditions. But a declining pattern of both NR and protease activities in the presence of Ca²⁺ and Pi, despite the higher rate of ATPase activity, might involve some other mechanism like the protein-kinase system. Received: 11 May 2000 / Accepted: 13 June 2000     

Carbonic Anhydrase Activity Associated with the Cyanobacterium Synechococcus PCC7942

Intact cells and crude homogenates of high (1% CO₂) and low dissolved inorganic carbon (C_i) (30-50 microliters per liter of CO₂) grown Synechococcus PCC7942 have carbonic anhydrase (CA)-like activity, which enables them to catalyze the exchange of ¹⁸O from CO₂ to H₂O. This activity was studied using a mass spectrometer coupled to a cuvette with a membrane inlet system. Intact high and low C_i cells were found to contain CA activity, separated from the medium by a membrane which is preferentially permeable to CO₂. This activity is most apparent in the light, where ¹⁸O-labeled CO₂ species are being taken up by the cells but the effluxing CO₂ has lost most of its label to water. In the dark, low C_i cells catalyze the depletion of the ¹⁸O enrichment of CO₂ and this activity is inhibited by both ethoxyzolamide and 2-(trifluoromethoxy)carbonyl cyanide. This may occur via a common inhibition of the C_i pump and the C_i pump is proposed as a potential site for the exchange of ¹⁸O. CA activity was measurable in homogenates of both cell types but was 5- to 10-fold higher in low C_i cells. This was inhibited by ethoxyzolamide with an I₅₀ of 50 to 100 micromolar in both low and high C_i cells. A large proportion of the internal CA activity appears to be pelletable in nature. This pelletability is increased by the presence of Mg²⁺ in a manner similar to that of ribulose bisphosphate carboxylase-oxygenase activity and chlorophyll (thylakoids) and may be the result of nonspecific aggregation. Separation of crude homogenates on sucrose gradients is consistent with the notion that CA and ribulose bisphosphate carboxylase-oxygenase activity may be associated with the same pelletable fraction. However, we cannot unequivocally establish that CA is located within the carboxysome. The sucrose gradients show the presence of separate soluble and pelletable CA activity. This may be due to the presence of separate forms of the enzyme or may arise from the same pelletable association which is unstable during extraction.     

A Model for HCO(3) Accumulation and Photosynthesis in the Cyanobacterium Synechococcus sp: Theoretical Predictions and Experimental Observations

A simple model based on HCO₃⁻ transport has been developed to relate photosynthesis and inorganic carbon fluxes for the marine cyanobacterium, Synechococcus sp. Nägeli (strain RRIMP N1). Predicted relationships between inorganic carbon transport, CO₂ fixation, internal carbonic anhydrase activity, and leakage of CO₂ out of the cell, allow comparisons to be made with experimentally obtained data. Measurements of inorganic carbon fluxes and internal inorganic carbon pool sizes in these cells were made by monitoring time-courses of CO₂ changes (using a mass spectrometer) during light/dark transients. At just saturating CO₂ conditions, total inorganic carbon transport did not exceed net CO₂ fixation by more than 30%. This indicates CO₂ leakage similar to that estimated for C₄ plants.

For this leakage rate, the model predicts the cell would need a conductance to CO₂ of around 10⁻⁵ centimeters per second. This is similar to estimates made for the same cells using inorganic carbon pool sizes and CO₂ efflux measurements. The model predicts that carbonic anhydrase is necessary internally to allow a sufficiently fast rate of CO₂ production to prevent a large accumulation of HCO₃⁻. Intact cells show light stimulated carbonic anhydrase activity when assayed using ¹⁸O-labeled CO₂ techniques. This is also supported by low but detectable levels of carbonic anhydrase activity in cell extracts, sufficient to meet the requirements of the model.

     

Purification and Characterization of Phosphoribulokinase from the Cyanobacterium Synechococcus PCC7942

Phosphoribulokinase (PRK) was purified to electrophoretic homogeneityfrom Synechococcus PCC7942 with high specific activity. Molecularmasses of the native enzyme and its subunit were 178 and 42kDa, respectively. Cys-17 and Cys-38 were conserved in the cyanobacterialPRK, but 18 amino acid residues between them were missing amongthe 40 residues found in higher plant PRKs. (Received February 1, 1995; Accepted July 27, 1995)     

Generic characters of the simplest cyanoprokaryotes Cyanobium,Cyanobacterium and Synechococcus

The cytomorphological features (cell morphology, type of cell division, cell structure, structure of photosynthetic apparatus) were studied in the type strains of the cyanoprokaryotic genera Cyanobium and Cyanobacterium, and in the reference strain of the traditional genus Synechococcus (Synechococcus PCC 6301; = “Anacystis nidulans” sensu auct.). They were originally described by Rippka & Cohen-Bazire, based on the mean DNA-base composition (moles % G + C) and on the resistance to various cyanophages. The phenotypic diacritical characters were found to coincide well with the molecular markers, and thus, the genera Cyanobium and Cyanobacterium are acceptable also according to the traditional (botanical) taxonomic criteria. The integrated molecular, cytomorphological and ecophysiological approaches to the solution of taxonomic problems in cyanobacteria are therefore inevitable for taxonomic evaluation, from the methodological point of view. The lists of species within the revised genera Cyanobium and Cyanobacterium are reviewed.     

Novel Form of ClpB/HSP100 Protein in the Cyanobacterium Synechococcus

Synechococcus sp. strain PCC 7942 has a second clpB gene that encodes a 97-kDa protein with novel features. ClpBII is the first ClpB not induced by heat shock or other stresses; it is instead an essential, constitutive protein. ClpBII is unable to complement ClpBI function for acquired thermotolerance. No truncated ClpBII version is normally produced, unlike other bacterial forms, while ectopic synthesis of a putative truncated ClpBII dramatically decreased cell viability.