Primary Role of the Cytoplasmic Membrane in Thermal Acclimation Evidenced in Nitrate-Starved Cells of the Blue-Green Alga, Anacystis nidulans

The lipid phase transition of the cytoplasmic membrane and the chilling susceptibility were studied in nitrate-starved Anacystis nidulans cells. Nitrate starvation resulted in the disappearance of the thylakoid membrane system, without any effect on chilling susceptibility. The chilling susceptibility of the algal cells depended on the growth temperature. Temperatures of lipid phase transitions of the cytoplasmic membranes were detected by chilling-induced spectral changes in the carotenoid region, in vivo. These values were identical to those of cultures containing intact thylakoid systems. Our results suggest that cytoplasmic membrane plays a determinative role in the thermal acclimation of the alga cells.     

Chilling Susceptibility of the Blue-green Alga Anacystis nidulans: I. EFFECT OF GROWTH TEMPERATURE

Effects of chilling treatment on the photosynthetic activities and the light-absorption and fluorescence spectra were investigated in intact cells of the blue-green alga Anacystis nidulans that were grown at different temperatures. When the algal cells grown at 38 C were treated at 0 C for 10 minutes, the photosynthesis and the Hill reaction with 1,4-benzoquinone were significantly inactivated and the light-absorption spectrum of carotenoids was modified. These parameters showed very similar temperature dependencies in the chilling susceptibility and the temperature regions critical for the susceptibility depended on the growth temperature. The midpoint values for the critical temperature regions were 4, 6, and 12 C in cells grown at 28, 33, and 38 C, respectively. It is proposed that a common mechanism would underlie the chilling susceptibility of the photosynthesis, the Hill reaction, and the carotenoid absorption spectrum. The decoupling of excitation transfer from allophycocyanin to chlorophyll a at the chilling temperatures occurred very slowly and is attributed to a somewhat different mechanism of the chilling susceptibility.     

pH Changes in the Cytoplasm of the Blue-Green Alga Anacystis nidulans Caused by Light-dependent Proton Flux into the Thylakoid Space

The pH in the cytoplasmic and thylakoid spaces of the blue-green alga, Anacystis nidulans, has been determined in the light and in the dark by uptake of 5,5-dimethyloxazolidine-2,4-dione and methylamine into the sucrose-impermeable ³H-H₂O space, as measured by silicon layer filtering centrifugation.     

The estimation of turnover of spermidine in Anacystis nidulans.

The turnover of spermidine in Anacystis nidulans was studied using [2-¹⁴C]methionine to prelabel intracellular spermidine. It was found that there is essentially neither excretion nor degradation of spermidine in exponentially growing Anacystis nidulans. Spermidine was degraded rapidly in stationary phase cells. The half-life of specific activity of spermidine in exponential phase was 8.3 h, a period similar to that of the doubling time (7.5 h) of the bacterium. The rate of synthesis of spermidine was calculated to be 0.04 nmol/10⁸ cells/h.     

Reversible inhibition of photochemistry of photosystem II by Ca2+ removal from intact cells of Anacystis nidulans

Depletion of Ca²⁺ from Anacystis nidulans produces an inhibition of O₂ evolution that is accompanied both at 39°C and 77 K by a loss of chlorophyll fluorescence of variable yield. This indicates that Ca²⁺-depletion causes disruption of normal photosystem II function, manifested by the disappearance of photoreduction of Q. Delayed light emission in the ms time range is also eliminated in Ca²⁺-depleted cells, which confirms that Ca²⁺ removal prevents charge separation and recombination in reaction centers of photosystem II. Readdition of Ca²⁺ to depleted cells restores fully the fluorescence of variable yield and delayed light emission, as well as O₂ evolution. Thus, Ca²⁺ may be a required component for photosystem II in A. nidulans.     

Photosynthetic activity of diimidoester-modified cells,permeaplasts, and cell-free membrane fragments of the blue-green alga Anacystis nidulans

On treating the blue-green alga Anacystis nidulans with dimethylsuberimidate up to 70% of the free NH₂ of the photosynthetic membrane is amidinated, and presumably inter- and intramolecular cross-links are established in the membrane proteins. Amidination destroys the ability of A. nidulans to photoreduce HCO₃^? but leaves the photochemical activities of Photosystems II and I nearly intact. With added electron acceptors, photosynthetic O₂ evolution can be demonstrated both with permeable cells (permeaplasts) prepared by digestion of the cell wall of dimethylsuberimidate-reacted A. nidulans with lysozyme, as well as with heavy membrane particles (36 000 × g) prepared from dimethylsuberimidate-reacted cells.Permeaplasts prepared from dimethylsuberimidate-reacted cells resist damage in hypoosmotic medium, whereas those prepared from unreacted cells are induced to release C-phycocyanin. On the other hand, the former are inactivated more easily by heat stress than the latter. On this basis, it is concluded that cross-linking with dimethylsuberimidate confers functional instability to photosynthetic membranes.     

Chilling-Susceptibility of the Blue-Green Alga Anacystis nidulans: III. LIPID PHASE OF CYTOPLASMIC MEMBRANE

The lipid phase of cytoplasmic membrane was studied by freeze-fracture electron microscopy in the chilling-susceptible blue-green alga, Anacystis nidulans. At growth temperatures, intramembrane particles were distributed at random in the fracture faces of cytoplasmic membrane, whereas, at chilling temperatures, the fracture faces were composed of particle-free and particle-containing regions. These findings indicate that lipids of the cytoplasmic membrane were in the liquid-crystalline state at the growth temperatures and in the phase-separation state at the chilling temperatures. Temperatures for the onset of phase separation were 5 and 16°C in cells grown at 28 and 38°C, respectively.     

Valyl tRNA's of Anacystis nidulans

Anacystis nidulans was found to contain three tRNA^val isoacceptors which could be charged also in heterologous systems with aminoacyl synth     

Characterization of Sulphate Uptake in Anacystis nidulans

Sulphate uptake in the blue-green alga Anacystis nidulans appears based upon an active mechanism with a Km of 0.75 μM and V_max of 0.7 pmol/min × 10⁶ cells. Sulphate uptake is competitively inhibited by thiosulphate and sulphite. The sulphate uptake has a pH optimum at 8 and a temperature optimum at 40°C. By increasing the extracellular sulphate concentration from 0.1 to 10 μM the sulphate pool in Anacystis was altered from 8.3, 10^?5M to 5.9, 10^?4M.     

Particle aggregation in photosynthetic membranes of the blue-green alga Anacystis nidulans

Freeze-fracture electron microscopy demonstrates that in photosynthetic membranes of the blue-green alga Anacystis nidulans quenched from a temperature below growth temperature, areas devoid of membrane particles occur. We suggest that this phenomenon is related to phase transitions in the photosynthetic membrane.     

Spectral changes in membrane fragments and artificial liposomes of Anacystis induced by chilling.

Isolated membrane fragments from Anacystis nidulans grown at 39 °C undergo visible spectral changes on chilling, suggesting a carotenoid component is altered. No such changes are seen when cells are grown at 25 °C. The magnitude of the decreased absorbance is a function of the chilling temperature and the media in which membrane fragments are suspended. The spectral decrease following chilling develops relatively slowly and is a function of the cooling rate and final temperature. The absorbance change is reversed if the fragments are heated to near 50 °C subsequent to chilling. Liposomes prepared from a total lipid extract of Anacystis undergo a spectral change on chilling which closely resembles that occurring in whole cells or isolated membrane fragments. Liposomes prepared from an extract of cells grown at 25 °C show only about 30% as great a spectral change as those from cells grown at 39 °C. The spectral bleaching is freely reversible when the liposomes are reheated, but shows a pronounced hysteresis. It is suggested that specific phase changes occur in Anacystis membranes and artificial liposomes on cooling which alter the environment of carotenoid. These changes may relate to previous observations that cells grown at 39 °C cannot survive a cold shock while those grown at 25 °C do.     

Isolated and purified plasma and thylakoid membranes of the cyanobacteriumAnacystis nidulans contain immunologically cross-reactive aa3-type cytochrome oxidase

Cell-free extracts ofAnacystis nidulans were fractionated by discontinuous sucrose density gradient centrifugation resulting in the separation of two distinct types of membranes, the heavier one containing the chlorophyll and the lighter one devoid of chlorophyll. Identity of the latter with plasma membrane was confirmed by labeling of intact cells with impermeant marker,³⁵S-diazobenzenesulfonate, prior to cell disruption. Both membrane fractions were purified individually by repeated recentrifugation on identical gradients. Purified membranes were subjected to dissociating polyacrylamide gel electrophoresis, either type of membranes yielding a distinct polypeptide pattern. After transfer of the polypeptides to nitrocellulose by Western blotting, two of the proteins, with molecular weights of approximately 55,000 and 32,000, respectively, gave strong and specifically complementary cross-reactions with antibodies raised against subunits I and II of the aa₃-type cytochrome oxidase fromParacoccus denitrificans. The findings will be discussed in terms of the presence of aa₃-type cytochrome oxidase in both plasma and thylakoid membranes ofAnacystis nidulans.     

Occurrence of cytochrome aa3 in Anacystis nidulans

The cytochrome content of membrane fragments prepared from the bluegreen alga (cyanobacterium) Anacystis nidulans was examined by difference spectrophotometry. Two b-type cytochromes and a hitherto unknown cytochrome a could be characterized. In the reduced-minus-oxidised difference spectra the a-type cytochrome showed an α-band at 605 nm and a γ-band at 445 nm. These bands shifted to 590 and 430 nm, respectively, in CO difference spectra. NADPH, NADH and ascorbate reduced the cytochrome through added horse heart cytochrome c as electron mediator. In presence of KCN the reduced-minus-oxidised spectrum showed a peak at 600 nm and a trough at 604 nm. Photoaction spectra of O₂ uptake and of horse heart cytochrome c oxidation by CO-inhibited membranes showed peaks at 590 and 430 nm. These findings are consistent with cytochrome aa₃ being the predominant respiratory cytochrome c oxidase in Anacystis nidulans.     

Cold Shock Syndrome in Anacystis nidulans

The phenomenon of cold shock in Anacystis nidulans has been explored further in terms of loss of viability and immediate and subsequent metabolic effects. Cold shock was observed also in two closely related strains in which unsaturated fatty acid contents are also known to be low and temperature-dependent. Loss of viability was maximum for cells grown at temperatures above 40 C (<10⁻⁴ survivors after 5 min at 0 C) but became negligibly small for cells grown below 34 C. Development of the cold-sensitive condition after transfer 25 → 39 C was slow and comparable to rate of growth; development of the insensitive condition after transfer 39 → 25 C was rapid, implying rapid in situ alteration. An immediate metabolic effect, observed as a decrease in rate of photosynthetic O₂ evolution measured at growth temperature, was less severe than loss of viability. Continued light incubation under growth conditions led to slow decay in rate of O₂ evolution accompanied by loss of membrane chlorophyll. The multiple effects which comprise the cold shock syndrome appear to be membrane-related phenomena and thereby provide an experimental probe of normal membrane function.     

Preparation of [U-14C]-labelled glycogen, maltosaccharides, maltose, and D-glucose by photoassimilation of 14CO2 in Anacystis nidulans and selective enzymic degradation.

A procedure is described for the isolation from the phototrophic procaryole Anacystis nidulans of [U-¹⁴C]-labelled glycogen, with high specific radioactivity,formed when NaH¹⁴CO₃ was added to non-dividing cells that continued to photoassimilate CO₂. [U-¹⁴C]-Labelled glycogen was then treated with isoamylase (EC 3.2.1.68), isoamylase plus beta-amylase (EC 3.2.1.2), or glucoamylase (EC 3.2.1.3) to give [U-¹⁴C]-labelled maltosaccharides, maltose-U-¹⁴C, or d-glucose-U-¹⁴C, respectively.     

Characterization of the Proton-Translocating Cytochrome c Oxidase Activity in the Plasma Membrane of Intact Anacystis nidulans Spheroplasts

Intact spheroplasts of the cyanobacterium (blue-green alga) Anacystis nidulans oxidized various exogenous c-type cytochromes with concomitant outward proton translocation while exogenous ferricytochrome c was not reduced. The H⁺/e⁻ stoichiometry was close to 1 with each of the cytochromes and did not depend on the actual rate of the oxidase reaction. Observed proton ejections were abolished by the uncoupler carbonyl cyanide m-chlorophenylhydrazone. Cyanide, azide, and carbon monoxide inhibited cytochrome c oxidation and proton extrusion in parallel while dicyclohexylcarbodiimide affected proton translocation more strongly than cytochrome c oxidation. The cytoplasmic membrane of A. nidulans appears to contain a proton-translocating cytochrome c oxidase similar to the one described for mitochondria.     

Spectral Changes in Anacystis nidulans Induced by Chilling

When Anacystis nidulans, strain TX 20 was grown at 39 C, then rapidly chilled to 0 C, a pigment with a carotenoid-like spectrum was bleached. This effect was not seen when cells which had been grown at 25 C were chilled. The effect seen in 39 C-grown cells was not reversible except under extreme conditions such as heating to near boiling for several minutes. Bleaching could be prevented by prior exposure of cells to glutaraldehyde, but could not be reversed by glutaraldehyde treatment following chilling. The effect occurred upon chilling 39 C-grown cells even after extensive heating at 85 C, a treatment which destroys phycocyanin and metabolic activities. 25 C-grown cells were induced to bleach by chilling when suspended in 50% glycerol. The results are interpreted as indicating a chill-induced change in aggregation state of a carotenoid, which changes its specific absorbance.     

The effects of gibberellic acid on photosynthetic pigments and oxygen evolution inChlamydomonas andAnacystis

Gibberellic acid (GA₃) generally increased the contents of chlorophyll but not carotenoid in bothChlamydomonas reinhardii andAnacystis nidulans grown under continuous irradiation. The photosynthetic oxygen evolution of the algae was also affected by GA₃ except for the high (100 μM) concentration of GA₃.     

Effect of Mn2+ and Ca2+ on O2 evolution and on the variable fluorescence yield associated with Photosystem II in preparations of Anacystis nidulans

Extraction with EDTA of lyophilized and lysozyme treated preparations of the blue-green algae Anacystis nidulans resulted in loss of the capacity for photoevolution of O₂. Reactivation was achieved by the addition of both cations: Mn²⁺ and Ca²⁺ (or to a smaller extent by Mn²⁺ and Sr²⁺). The dual requirement for Mn²⁺ and Ca²⁺ could be demonstrated when the O₂ evolution under short saturating light flashes and the variable chlorophyll fluorescence associated with the reduction of the primary acceptor of Photosystem II was examined. The fluorescence experiments in addition showed that incorporation of the cations was a light dependent step, since the fluorescence rise only started after a lag period.     

Effects of Hydroxylamine on Photosystem II: II. Photoreversal of the NH(2)OH Destruction of O(2) Evolution

The inactivation of O₂-evolving centers by NH₂OH extraction was shown to be reversible. This reversal required light and manganese. This light-induced restoration of active O₂-evolving centers was analyzed using three green algae and the blue-green alga, Anacystis nidulans. The following results were obtained: [List: see text]