Studies on the Hill reaction of membrane fragments of blue-green algae I. Stabilizing effect of various media on the 2,6-dichlorophenol indophenol-Hill activity of membrane fragments obtained from Anabaena cylindrica and Anabaena variabilis

The stability of DPIP-Hill activity of membrane fragments fromblue-green algae was investigated in various suspension media.Two blue-green algae, Anabaena cylindrica and A. variabiliswere used. Activities for the DPIP-Hill reaction were stable in the twoalgal preparations only when preparations were suspended ina medium containing high concentrations of carbohydrates orPEG. Required concentrations of carbohydrates or PEG differedgready in die two preparations; 1.5 M sucrose or 20% PEG forA. cylindrica and 0.3 M sucrose or 6% PEG for A. variabiliswere minimal for maintaining full activity in 2 hr incubationat 0°C, respectively. Below these concentrations, activitiesdecreased rapidly. In both preparations, stabilizing effects,on a molar basis, varied in different kinds of solutes. However,a simple relation was found between the effects and water concentrationsof media. In A. cylindrica, a 50% decay in activity occurredin 2 hr incubation at 0°G in a medium with 43.8 M water,and, in A. variabilis, the water concentration was 53.4 M. In media free of carbohydrate or PEG, Mg++ ion had a moderatestabilizing ability. EDTA acted antagonistically to Mg++. Effectiveconcentrations were the same in two preparations. However, inthe medium containing carbohydrate or PEG, their actions wereinsignificant. Results suggest that the molecular organization in membranesnecessary for Hill reaction is easily destroyed under high waterconcentrations, and that added solutes stabilize the activityby reducing water concentrations. (Received February 13, 1971; )     

Studies on the Hill reaction of membrane fragments of blue-green algae V. A correlation between the solubilization of a photochemically active chromoprotein (ACP) and the inactivation of photosystem II activity in membrane fragments of Anabaena cylindrica

The relationship between a photochemically active chromoprotein(ACP) (cf. ref. 1) and photosystem II was investigated withmembrane fragments of Anabaena cylindrica, A. variabilis andP. boryaman. ACP was solubilized from membrane fragments of A. cylindricabut not from those of A. variabilis or P. boryanum, when themembrane fragments had been incubated in a dilute buffer andhad lost their Hill or photosystem II activity. In A. cylindrica,ACP-solubilization always occurred, independent of photosystemII inactivation, on incubation of the membrane fragments inmedia without PEG. However, the amount of ACP solubilizationaccompanying photosystem II inactivation was twice that withoutphotosystem II inactivation. The increase in ACP solubilizationaccompanying photosystem II inactivation. The kinetics resembledthose for the decrease in 695 nm fluorescence emitted by membranefragments at — 196?C (cf. 2). The ACP solubilized independent of photosystem II inactivationwas assumed to have been released during disruption of intactcells in the preparation of membrane fragments. The slow ACPsolubilization upon the inactivation of photosystem II was attributedto the pigment being bound to membranes. We assume that thephoto-reactive component of ACP, P690 (cf. 3, 4), is releasedfrom the membranes during photosystem II inactivation, and thatP690 is a component of photosystem II which emits the 695 nmfluorescence at — 196?C. (Received March 22, 1974; )     

Studies on the Hill reaction of membrane fragments of blue-green algae II. The reaction steps inactivated at high water concentration

DPIP-photoreduction by membrane fragments of Anabaena cylindricaand A. variabilis was studied to determine which step(s) ofthe Hill reaction system is inactivated on incubation of themembrane fragments in a medium with a high water concentration(cf. 1). Supplementary experiments were done with Anacystisnidulans and Plectonema boryanum. After inactivation of the Hill system at a high water concentration,DPIP-photo-reducing activity was strongly enhanced in the A.variabilis system but less so in the A. cylindrica system byadding DPC, NH₂OH, Mn⁺⁺ or H₂0₂. The activity supported by theadded electron donor was inhibited by DCMU. The steady statelevel of chlorophyll fluorescence was lowered by the inactivationtreatment. In the A. variabilis system, the fluorescence yieldincreased to the original level on the addition of an electrondonor. In the A. cylindrica system, the yield was not so stronglyenhanced as in the A. variabilis system. We inferred that, in A. variabilis, inactivation occurs in thereaction system before the site which receives electrons fromartificial donors, probably including the water oxidation system.In A. cylindrica, besides this site, a site at or near the photochemicalsystem is also blocked. Similar types of inactivation were observed in DPIP-Hill reactionsusing Anacystis nidulans and Plectonema boryanum preparations.The characteristic stability of the Hill reaction system observedin two Anabaena preparations is probably common to the blue-greenalgae. (Received December 10, 1971; )     

Studies on the Hill reaction of membrane fragments of blue-green algae IV. Garotenoid photobleaching induced by photosystem II action

Carotenoid photobleaching induced by the action of photosystemII was investigated with membrane fragments of Anabaena cylindricaand A. variabilis. Carotenoid photobleaching occurred only when ferricyanide and/orCCCP was present in the reaction mixture. Maximum velocity ofthe reaction was obtained in the presence of ferricyanide andCCCP. Difference spectra (light minus dark) indicated that afast carotenoid photobleaching was accompanied by a slow chlorophyllbleaching. The pattern of the difference spectra was identicalto that reported by Yamashita et al. (1) with spinach chloroplasts.The reaction was DCMU-sensitive, though a portion of the activitywas insensitive to DCMU when ferricyanide was present in thereaction mixture. The effect of CCCP on stimulation of carotenoidphotobleaching showed the same function against CCCP concentrationas that on inhibition of DPIP-photoreduction with DPC. Carotenoidphotobleaching was stimulated by ferricyanide and suppressedby ferrocyanide; thereaction rate was reduced fifty percentwith a ferri- and ferrocyanide mixture giving 510 mV redox potential(pH 7.5). Benzoquinone was stimulatory, but DPIP had no effect. Incubation of membrane fragments in a dilute buffer inactivatedthe Hill reaction but neither the DPC-supported DPIP-photoreductionnor carotenoid photobleaching in A. variabilis. In A. cylindrica,incubation inactivated all three reactions. Inactivation ofthe latter two reactions followed the same kinetics. (Received August 31, 1972; )     

The light-induced oxidation-reduction reaction of cytochrome b-559 in membrane fragments of the blue-green alga Anabaena variabilis

Light-induced oxidation-reduction reactions of cytochrome b-559were investigated with membrane fragments of Anabaena variabilisand supplementarily with Plectonema boryanum. The oxidation-reduction reactions of cytochrome b-559 observedwith membrane fragments were similar in their kinetics to thoseof the cytochrome in aged chloroplasts. The reactions were annihilatedby the addition of Ferro, indicating that the cytochrome ofhigh redox potential (E'_o=+373 mV, pH 6.5) was photoreducedand oxidized. Titration with reducing agents indicated that cytochrome b-559is contained in Anabaena membrane fragments in an amount 1.5times as much as the content of P700 on a molar basis; the contentof the species of high redox potential was estimated to be around70%. Kinetic treatment of the photoreduction indicated that the cytochromewas reduced at some site of the electron transport system betweenthe two photosystems. The photo-oxidation depended on the actionof either photosystem II or I even in the presence of DCMU,indicating that the photooxidation was induced by both photosystems.The oxidation by photosystem I action was inhibited by HgCl₂-treatment,indicating that this reaction is mediated by plastocyanin. EDTA (5?10^-3 M) suppressed the cytochrome photoreduction andenhanced the rapid phase of the photooxidation. The latter effectappeared only when an appropriate dark time (3 min) was insertedafter the cytochrome photoreduction. The phenomenon was interpretedas showing that EDTA modifies the reactivity of the electroncarrier which directly donates electrons to cytochrome b-559.The oxidation, and probably also the reduction of cytochromeb-559, was assumed to be regulated by the oxidation-reductionstate of this carrier. (Received April 26, 1974; )     

Further investigation of the light-induced cytochrome b-559 reaction in membrane fragments of the blue-green alga Anabaena variabilis

Oxidation-reduction reactions of the low redox potential cytochromeb-559 were studied for membrane fragments of the blue-greenalga Anabaena variabilis. Cytochrome photooxidation was observableat room temperature when the membrane fragments had been preincubatedat room temperature in the dark. A CCCP addition (10^–4M) strongly enhanced the reaction. Oxidation consisted of a DCMU-sensitive and an insensitive reaction.The former depended on actinic illumination of short wavelength.The latter showed a dependency on longer wavelength light. Theformer was assumed to be induced by the action of photosystemII and the latter by that of photosystem I. The photosystem II oxidation was small before preincubation,and was enhanced by added DPIP or Ferro. This was interpretedas photosystem II action inducing oxidation as well as reduction;reduction being inactivated during dark incubation or beingsuppressed by added redox reagents which compete for electronacceptance from photosystem II so that oxidation was apparentlyenhanced. The oxidationreduction reactions of this cytochromewith low redox potential were assumed to be almost identicalwith those of the high redox potential form, at least in themembrane fragments of Anabaena variabilis. (Received June 8, 1975; )     

The C550 photoresponse at room temperature observed in membrane fragments of the blue-green alga Anabaena variabilis

The C550 photoresponse at room temperature was studied withmembrane fragments of the blue-green alga Anabaena variabilis.The kinetics, light minus dark difference spectrum and DCMUeffect were the same as those reported for spinach chloroplasts.The photoresponse size suggested that the number of the photosystemII center is half that for the photosystem I center in thisorganism grown under our autotrophic culture conditions. (Received September 16, 1975; )     

Fluorescence characteristics of cyanobacteria (blue-green algae)

The fluorescence characteristics of the cyanobacteria Synechocystisaquatilis Sauv., Microcystis firma (Breb. et Lenorm.) Schmidleand Synechococcus leopoliensis (Racib.) Kom. and the green algaScenedesmus quadricauda (Turp.) Breb. were examined. In thethree cyanobacteria, phycocyanin is the main accessory pigment.Phycoerythrin is not present in our investigated strains ofcyanobacteria. The highest excitation of the chlorophyll a (Chla) fluorescence of cyanobacteria resulted from light with wavelengthsof 620–630 nm. A definite ‘Kautsky’ effectis also evident at this wavelength. However, excitation withblue light (420–520 nm) produced only very slight fluorescence.The Kautsky effect is not evident at these wavelengths, evenat high photon flux densities. For Scenedesmus, fluorescencecharacteristics typical of green algae were found. The fluorescenceexcitation of cyanobacteria at 620 nm corresponds to a photosynthesispeak in the action spectrum measured in terms of O₂ production.The results underline the necessity of fluorescence measurementsat several wavelengths whenever mixed populations are involved.Such measurements also present possibilities for more accurateestimation of biomass and potential photosynthetic productionin mixed populations.     

Nitrogen fixation and heterocysts in the blue-green alga Anabaena cylindrica

The site of nitrogen fixation in the blue-green alga Anabaenacylindrica Lemra (Fogg strain) was investigated. Less than 4%of the total nitrogen fixed during a relatively short period(5-15 min) was recovered in heterocysts. When estimated on thecellular nitrogen basis, vegetative cells can fix molecularnitrogen at the same rate as do heterocysts. There was no positivecorrelation between nitrogen fixation and heterocyst formation.Results do not support the hypothesis that the heterocyst isthe main site for nitrogen fixation in blue-green algae. ¹ This work was supported by grant (No. 38814) from the Ministryof Education. (Received July 23, 1971; )     

Electron donor-specificity observed in photosystem I reactions of membrane fragments of the blue-green alga Anabaena variabilis and the higher plant Spinacea oleracea

Electron donating activities of plastocyanins and c-type cytochromesof various organisms for photosystem I reactions were studiedwith membrane fragments of the blue-green alga Anabaena variabilisand the higher plant Spinacea oleracea. In the Anabaena photosystem I reaction, basic but not acidicplastocyanin and c-type cytochromes acted as efficient electrondonors, while only acidic redox proteins were active in thespinach photosystem I reaction. The selective reactivity ofredox proteins in the two photosystem I reactions was observedwith both plastocyanin (or cytochrome) limited and saturatedconditions. These data support our previous observation that photosystemI of blue-green algae differs from those of other green plantswith respect to specificity to the proteinous electron donor(1). (Received August 17, 1971; )     

Effect of nitrate on nitrogen-fixation by the blue-green alga Anabaena cylindrica

The effect of nitrate on nitrogen-fixation in the blue-greenalga Anabaena cylindrica Lemm (Fogg strain) was investigated.At concentrations up to 2x10^–2 M, nitrate neither inhibitedthe activity of nitrogenase nor repressed its formation. Atthe late logarithmic phase, more than 50% of cell nitrogen wasprovided by nitrogen-fixation when the cells were grown in thepresence of nitrate. Ammonia at a concentration of 1x10^–3M completely repressed the formation of nitrogenase, but hadno effect on its activity. Nitrogen-fixing activity in the algavaried to a considerable extent during growth on N₂ and themaximum activity was attained at the middle logarithmic phase.However, atmospheric nitrogen did not directly affect the inductionof nitrogenase. The formation of nitrogenase in A. cylindricaappears to be controlled by the intracellular level of a certainnitrogenous metabolite. ¹ This work was supported by grant No. 38814 from the Ministryof Education. (Received January 26, 1972; )     

Effect of growth temperature on lipid and fatty acid compositions in the blue-green algae, Anabaena variabilis and Anacystis nidulans.

The lipid composition was affected by growth temperature in Anacystis nidulans, but was not in Anabaena variabilis. A. variabilis contained fatty acids of 18 and 16 carbon atoms, which were localized at 1- and 2-positions, respectively, of the glycerol moiety of lipids. Desaturation of C18 acids was affected by the growth temperature. A. nidulans contained fatty acids of 14, 16 and 18 carbon atoms. Monounsaturated and saturated acids were esterified mainly to 1- and 2-position, respectively. Desaturation and chain length of fatty acids were influenced by the growth temperature. The variations in lipid and fatty acid compositions with the growth temperature are discussed in relation to the growth temperature-dependent shift of thermotropic phase transition temperature of the membrane lipids in the blue-green algae.     

Solubilization of nitrate reductase from the blue-green alga Anabaena cylindrica

Nitrate reductase was solubilized and purified from Anabaenacylindrica by Triton X-100 treatment of particulate preparationsfollowed by adsorption on calcium phosphate gel. Reduced methylviologen, FAD or FMN, but not ferredoxin, served as an effectiveelectron donor for the nitrate reduction by solubilized nitratereductase. ¹This work was supported by a grant (4061) from the Ministryof Education (Received June 25, 1970; )     

Carotenoid photobleaching induced by photosystem II action in the membrane fragments of the blue-green alga Anabaena variabilis : Action of O2

Carotenoid photobleaching induced by photosystem II action wasstudied using membrane fragments of the blue-green alga Anabaenavariabilis. Special attention was paid to the action of O₂. Carotenoid photobleaching elicited by carbonyl cyanide m-chlorophenylhydrazone(CCCP) depended on O₂. However, the addition of H₂O₂, sodiumsilicotungstate or potassium ferricyanide (Ferri), an electronacceptor for reaction center II action, removed the O₂-dependency.These results indicate that O₂ acts as the electron acceptorfor this reaction. When both CGCP and Ferri were present, a short illumination(0.25 sec) caused a rapid photobleaching followed by a slowrecovery in the subsequent dark period. The spectrum of theabsorption decrease in the light was identical with that ofthe absorption increase in the subsequent dark, indicating thata reversible process is involved in the carotenoid photobleaching.The size in the dark recovery relative to the light bleachingbecame larger under anaerobic conditions and smaller under higherpartial pressure of O₂. The reuslts were interpreted as indicatingthat O₂ does not function in the primary process including areversible bleaching step, but is involved in the slow and irreversiblebleaching process. (Received April 3, 1978; )