NITRATE REDUCTASE IN PHOTOSYNTHETIC BACTERIUM, RHODOSPIRILLUM RUBRUM. ADAPTIVE FORMATION OF NITRATE REDUCTASE

1. A method was discovered for adapting the cells of Rhodospirillumrubrum to grow on a nitrate medium, a capacity initially lackingin the organism. The adapted cells were able to grow with nitrateas the sole source of nitrogen. The growth responses of theadapted cells towards various nitrogenous sources were investigatedunder various conditions of incubation (aero- and anaerobiosis,light and dark).
2. The adapted cells were found to have simultaneouslyacquiredthe capacity for reducing nitrite and hydroxylamineas wellas nitrate. The path of nitrogen in the adapted cellswas assumedto be as follows: NO₃^– NO₂^– NH₂OH CellularNitrogen.
3. Nitrate metabolism of the adapted cells was investigatedundervarious conditions. In the light, nitrate was reducedand furtherassimilated, leaving insignificant amounts of nitritein themedium. In this case, consumption of nitrate was markedlyinhibitedby other forms of nitrogen (e.g., nitrite, hydroxylamine,aminoacids and ammonium salts). In the dark, nitrate was reducedas the terminal hydrogen acceptor in the oxidative breakdownof organic substances (e.g., malate) in the medium (i.e., nitraterespiration). More nitrite was accumulated in this case thanin the light. Molecular oxygen inhibited the reduction of, aswell as the growth on, nitrate in any of the above cases.
4. Theeffects on the rate of nitrate reduction (and respiratoryoxygenuptake) caused by various experimental factors (pH, nitrateconcentration, electron donors, and addition of hydroxylamine)were investigated, using the resting cells of the adapted organism.

¹ This paper was submitted to the University of Tokyo to fulfillthe requirement for the author's doctorate. ² Present Address: Botanical Institute, Kyoto University, Sakyo-ku,Kyoto. (Received February 14, 1963; )     

Photophosphorylation in intact algae: Effects of inhibitors, intensity of light, electron acceptor and donors

The luciferin-luciferase method was used to determine ATP extractedfrom darkmaintained and light-exposed samples of the green algaChlorella pyrenoidosa and of the blue-green alga Anacystis nidulans.A few measurements on Synechococcus lividus (a bluegreen thermophile,clone 65?C) are also reported.

1. The light-minus-dark ATP levels (ATP) from aerobic cells ofChlorella and Anacystis were negative; however, ATP from Synechococcuswas positive. Large positive ATP was obtained in regularly grown(RG: moderate light) Chlorella treated with oligomycin; darklevels were reduced, light levels remained essentially unaffected.In high-light exposed (HLE) Chlorella, oligomycin reduced bothlight and dark ATP levels, but positive ATP was still obtained.However, in Anacystis, which has a different organization ofthylakoid membrane, oligomycin severely reduced both the lightand the dark ATP levels and the ATP remained negative.
2. Theoligomycin (12 µM) treated Chlorella and the untreatedAnacystis and Synechococcus show the presence of cyclic photophosphorylationunder conditions in which the non-cyclic electron flow fromphotosystem II to photosystem I is blocked by 10 µM 3-(3,4-dichlorophenyl)-l,l-dimethylurea(DCMU), or not allowed to operate by the absence of CO₂. Cyclicphotophosphorylation ranged from 10–30% of the maximumATP in RG, to 40–50% in HLE Chlorella. In RG Chlorella,cyclic and non-cyclic (in the absence of DCMU) photophosphorylation(ATP) saturate at about 10³ ergs cm^–2 sec^–1 and10⁴ ergs cm^–2 sec^–1 and 10⁴ ergs cm^–2 sec^–1red (>640 nm) light, respectively; a lag was observed inthe light curve.
3. In Chlorella, the addition of the photosystemI electron acceptormethyl viologen (MV; 1 mM) increased ATPby twofold. Furtheraddition of DCMU (25 µm) reduced thisto the level observedwith DCMU alone. If 1 mM reduced dichlorophenolindophenol orphenazine methosulphate (DCPIPH₂ or PMSH₂, respectively)wasadded along with DCMU, the ATP level was 30–40% ofthecontrol. Further addition of MV increased the JATP to be70–80%of that of the control. These and other resultsconfirm thepresence of both non-cyclic and cyclic photophosphorylationin vivo, the former predominating in Chlorella, and the latterin Anacystis and Synechococcus.

(Received May 1, 1973; )     

Effect of O2 on the Kinetics of the Flash-Induced 518 nm Absorbance Change in Vivo

The kinetics of the flash induced 518 nm absorbance change (A₅₁₈)in lettuce leaves were found to be dependent on O₂ concentration.(1) Either a lower O₂ partial pressure or the addition of weakred background illumination accelerated the decay of (A₅₁₈)while far-red background light induced a transient acceleration.(2) In the presence of background red light the accelerateddecay could be restored to the original dark level by the additionof O₂. A linear relationship was found between the intensityof red background light and the O₂ pressure required for thisrestoration. (3) The O₂ dependence of (A₅₁₈) decay halftimewas biphasic, the sensitive phase saturating at 0.3 atmospheresO₂ independent of input light energy while the O₂ concentrationneeded to saturate the second phase increased with increasinginput light energy (increasing flash frequency). (4) Treatmentwith N, N'-dicyclohexylcarbodiimide (DCCD) or KCN eliminatedall O₂ and background light effects and DCMU treatment inhibitedall but the sensitive phase of the O₂ dependence on (A₅₁₈) decayhalftime. (5) The extent of the lag phase in the dark recoveryof (A₅₁₈) normally present after preillumination induced accelerationof decay was decreased with added O₂ or KCN. (6) It was concludedthat O₂ competes directly with background red light inducedelectron transport to PS I acceptors to influence the (A₅₁₈)decay. A possible mechanism involving the O₂ sensitive ferredoxin-thioredoxin-reductaseactivation of chloroplast coupling factor 1 ATP-hydrolase activitywas discussed. (Received December 17, 1982; Accepted April 28, 1983)     

The mineral nutrition of cultured chlorophyllous cells of tobacco I. Effects of {pi}salts, {pi}sucrose, Ca, Cl and B in the medium on the yield, friability, chlorophyll contents and mineral absorption of cells

1. The growth rate of cultured free-cells and their contents ofchlorophyll, Mg, K and N reached peaks on media containing M_n+= 60 and 80 meq per liter, or in which _salts=2.7 and 3.6 atm.These concentration levels in the media were considerably higherthan those (_Salts=1.5–2.0 atm) which produced good growthof intact plants. This discrepancy in media concentrations maybe due to differences in the culture conditions and in the morphologyof the materials.
2. Very low Ca²⁺/(Mⁿ⁺–Ca²⁺) equivalentratios of 0.1 to 0.01in a medium were sufficient for good growthof free cells, whilegenerally about unity of the ratio is requiredin a medium forgood growth of intact plants. The differencein the medium compositionmay also be due to morphological differencesin the materials.
3. Addition of Cl^– to the medium furtherpromoted the growthrate and friability of cell clumps.
4. Alow concentration of 0.01 mM BO₃^3– in the medium alsopromoted the friability of cell clumps.

(Received August 15, 1972; )     

Biosynthetic mechanism of glycolate in Chromatium III. Effects of {alpha}-hydroxy-2-pyridinemethanesulfonate, glycidate and cyanide on glycolate excretion

Effects of -hydroxy-2-pyridinemethanesulfonate (-HPMS), 2,3-epoxypropionate(glycidate), and cyanide on the photosynthetic activities ofChromatiumwere studied. -HPMS stimulated photosynthetic CO₂fixation in the bacterial cells in both N₂ and O₂ environments.The formation and subsequent excretion of both glycolate andglycine in the O₂ atmosphere were markedly enhanced by -HPMS.In contrast to a recent report by Zelitch [Arch. Biochem. Biophys.163: 367–377 (1974) ] that glycidate specifically inhibitsglycolate formation in tobacco leaf disks, we found that ithad no influence on CO₂ fixation by Chromatium in either N₂or O₂ atmosphere, and that the synthesis and extracellular excretionof glycolate were markedly stimulated by glycidate treatment.Cyanide (0.01–1 mM) exerted a marked inhibitory effecton photosynthetic CO₂ fixation in N². In O₂ atmosphere, photosynthesiswas stimulated by 0.01 mM cyanide, and inhibited by it abovethis level. Both the incorporation of ¹⁴CO₂ into glycolate andthe total synthesis of glycolate in the light were also enhancedby 0.01 mM cyanide, and strongly inhibited above that concentration. ¹This is paper XXXVI in the series "Structure and Function ofChloroplast Proteins," and the research supported in part bygrants from the Ministry of Education of Japan (No. 111912),the Toray Science Foundation (Tokyo) and the Naito Science Foundation(Tokyo). (Received May 31, 1976; )     

Uptake of Thallium, a Toxic Heavy-Metal, in the Cyanobacterium Synechococcus R-2 (Anacystis nidulans, S. Leopoliensis) PCC 7942

Uptake of the toxic heavy-metal, thallium, was studied in thecyanobacterium Synechococcus R-2 (PCC 7942) using clinicallyavailable ²⁰¹Tl ⁺. Thallium was found to distribute across theplasmalemma passively, and so the accumulation ratio of theion ([Tl⁺]_i/[Tl⁺]_o) could be used to calculate the apparentmembrane potential (­_i,o) of the cells (^ETI⁺_i,o = ­_i,o).The permeability of the plasmalemma to TI⁺ (^PTI⁺ 1 to 5 nms^–1)is higher than that of K⁺. Valinomycin does not increase thepermeability of TI⁺. Transient changes in the ­_i,o of cells,because of electrogenic transport of ions, could be detectedfrom its effects upon the uptake rate of TI⁺. HCO^–₃ hyperpolarizedSynechococcus cells, whereas NH⁺₄, CH₃NH⁺, and K⁺ led to depolarization.The use of TI⁺ as a reporter of ­_i,o has some inherent limitations.Tl⁺ is toxic at very low concentrations (inhibitory effectsare apparent after about 6 h at concentrations as low as 1 mmolm^–3). The rate of equilibration is slow (t_1/25 to 20 min).Equilibration of TI⁺ takes about 2 h, which limits its valueas a membrane potential probe. Large amounts of TI⁺ bind tothe surface of the cells making the method impracticable formeasuring accumulation ratios of less than about 10 (­_i,o)values smaller than about –60 mV). Cultures continuouslyexposed to Tl⁺ (10 mmol m^–3) eventually become TI⁺ resistantby actively extruding TI⁺ (µTI⁺_i,o= –3±0.2kJ mol^–1) and so thallium cannot be used as a ­_i,oprobe in such cells. (Received October 28, 1997; Accepted August 31, 1998)     

Effects of blue light deficiency on acclimation of light energy partitioning in PSII and CO2 assimilation capacity to high irradiance in spinach leaves

Blue light effects on the acclimation of energy partitioningcharacteristics in PSII and CO₂ assimilation capacity in spinachto high growth irradiance were investigated. Plants were grownhydroponically in different light treatments that were a combinationof two light qualities and two irradiances, i.e. white lightand blue-deficient light at photosynthetic photon flux densities(PPFDs) of 100 and 500 µmol m^–2 s^–1. The CO₂assimilation rate, the quantum efficiency of PSII (PSII) andthermal dissipation activity / in young, fully expanded leaves were measured under 1,600 µmol m^–2 s^–1white light. The CO₂ assimilation rate and PSII were higher,while / was lower in plants grown under high irradiancethan in plants grown under low irradiance. These responses wereobserved irrespective of the presence or absence of blue lightduring growth. The extent of the increase in the CO₂ assimilationrate and PSII and the decrease in / by high growth irradiance was smaller under blue light-deficient conditions. These resultsindicate that blue light helps to boost the acclimation responsesof energy partitioning in PSII and CO₂ assimilation to highirradiance. Similarly, leaf N, Cyt f and Chl contents per unitleaf area increased by high growth irradiance, and the extentof the increment in leaf N, Cyt f and Chl was smaller underblue light-deficient conditions. Regression analysis showedthat the differences in energy partitioning in PSII and CO₂assimilation between plants grown under high white light andhigh blue-deficient light were closely related to the differencein leaf N.     

Effect of {alpha}-hydroxy-2-pyridinemethanesulfonate on glycolate metabolism in spinach leaf protoplasts

The addition of -hydroxy-2-pyridinemethanesulfonate (-HPMS)to spinach leaf protoplasts caused a marked inhibition of photosyntheticCO₂ fixation in both air and O₂ atmospheres. In the O₂ atmosphere,¹⁴CO₂ was incorporated into glycine, but upon addition of -HPMS(10 mM), there was a suppression of ¹⁴CO₂ incorporation intothe glycine and serine plus isoleucine fractions, accompaniedby an accumulation of ¹⁴C-glycolate. A marked stimulation ofalanine labeling due to the -HPMS treatment was also observed.Feeding protoplasts with [l–¹⁴C)-glycolate resulted inthe formation of ¹⁴C-labeled glycine, serine, and sugar phosphatesin both light and dark conditions, and a sizable amount of ¹⁴CO₂evolved concomitantly. The results support the notion concerningthe operation of the glycolate pathway in leaf tissue duringphotorespiratory environments. The suitability of protoplastsfor photosynthetic research in conjunction with the use of inhibitorsubstances are discussed, although the results of the presentresearch indicate that the effect of a-HPMS is not confinedto the specific inhibition of the glycolate-oxidase reaction. ¹ This is paper 42 in the series "Structure and Function ofChloroplast Proteins", and the research was supported in partby the grant from the Ministry of Education of Japan (11912,147106), the Toray Science Foundation (Tokyo), the Nissan ScienceFoundation (Tokyo), and the Matsunaga Foundation (to M. N.). (Received July 21, 1977; )     

ENZYMIC FORMATION OF GLUTAMINE IN RICE-PLANT SEEDLINGS

1. Purified preparation from rice-plant seedling catalyses a stoichiometricreaction between ATP, glutamate, and NH₂OH in the presence ofMg⁺⁺ to form glutamyl hydroxamate, ADP and inorganic phosphate.
2. The method of purification and some of the properties of theenzyme are described. Co⁺⁺ can be substituted for Mg⁺⁺. Mn⁺⁺,NaF, and PCMB inhibit the enzyme strongly.
3. Inorganic orthophosphateis liberated from ATP by the additionof or cysteine in the presence of glutamate, Mg⁺⁺ andthis preparation. Glutamine was detectedin the reaction productsby paperchromatography.
4. The same preparation catalyses a reactionbetween gluta mineand NH₂OH in the presence of Mg⁺⁺ or Mn⁺⁺,ADP and inorganicphosphate, to form glutamyl hydroxamate.

¹ Present address: The Department of Chemistry, Faculty of Science,Kanazawa University, Kanazawa. (Received October 31, 1960; )     

Inactivation and Degradation of CuZn-SOD by Active Oxygen Species in Wheat Chloroplasts Exposed to Photooxidative Stress

Changes in CuZn-SOD actvity and content in isolated wheat chloroplastsunder the light, and the involvement of protease(s) and/or activeoxygen species in this process were studied. Both SOD activityand content decayed with exposure time to photooxidative stress.Ascorbate, a H₂O₂ scavenger, prevented photooxidation-associatedinactivation of SOD, while benzoate, a OH scavenger, preventedSOD degradation. Wheat chloroplasts incubated in the dark didnot hydrolyze exogenous or endogenous SOD, either H₂O₂-pretreatedor not. Protease inhibitors did not prevent SOD degradationunder photooxidative treatment, suggesting that plastid protease(s)did not participate in this process. Purified chloroplast CuZn-SODwas exposed to H₂O₂ and or OH-generating systems. had no effect on either SOD activity or stability (estimated bynative PAGE). H₂O₂ up to 700µM inhibited SOD in a dose-dependentmanner and induced charge/mass changes as seen by native PAGE.OH also reduced SOD activity by inducing its fragmentation.High levels of active oxygen, as can be generated under strongstress conditions, could directly inactivate and degrade chloroplasticSOD. ₁ Present address: Departamento de Biología Vegetal,Univer-sidad de Alcalá de Henares, Alcalá de Henares,E-28871 Madrid, Spain     

SYNCHRONOUS CULTURE OF CHLORELLA: I. KINETIC ANALYSIS OF THE LIFE CYCLE OF CHLORELLA ELLIPSOIDEA AS AFFECTED BY CHANGES OF TEMPERATURE AND LIGHT INTENSITY

1. Using the technique of synchronous culture, investigationsweremade of the effects of temperature and light-intensityon cellularlife cycle of Chlorella ellipsoidea. Some improvementsin theculture technique for obtaining a good synchrony of algalgrowthwere described.
2. By following the changes of averagecell volume and cell numberoccurring during culturing, therates of the following processesof life cycle were determined:(i) "growth" (or the increasein cell mass) occurring from thestage of smaller cells (D_a)to the stage of ripened cell (L₃),(ii) "ripening" (or processofformation of "nuclear substances"as estimated from the averagenumber of daughter cells formedfrom single mother cell), and(iii) " maturing and division" which leads to the full maturationof mother cells (L-cells)and their division into separate daughtercells (D-cells).
3. "Growth"and "ripening" were found to be dependent in light,"maturingand division" light-independent. The time requiredfor "growth"and "ripening" (C) is dependent on temperaturebut independentof light intensity, the onset of "maturing anddivision" occurringat the same time (D) of culturing undervaried light intensities.The average cell volume at this stage(L₃),however, was foundto be markedly modified by light intensity;larger with highertemperatures (see Fig. 4).
4. Changes in incubation temperature(under the condition of saturatinglight intensities) were foundto affect the life cycle in thefollowing way: (i) The timeof onset of "maturing and division"(D), varies markedly withculturing temperature; earlier athigher temperatures, (ii)The average cell volume at this stagealso depends on temperature; smaller at higher temperatures.
5. The average number of daughtercells (n) emerging from singlemother cells, was found to beuninfluenced by culturing temperature;(4.0–4.1 underthe conditions of the present study). Itwas found that thedivision number n is remarkably varied bychanging the lightintensity in the "growth" and "ripening"phases; 2.0 at 1 kilolux,3.7 at 5 kilolux, 4.2 at saturatinglight intensities (10 and25 kilolux). This finding was explainedby assuming a light-dependentformation of "nuclear substances"during the "growth" and "ripening"phases, the quantity of thesubstances in the cell at L₃ stagedeterminig the division number.
6. The experimental data wereanalyzed reaction kinetically, therate constants and othercharacteristics of the reactions constitutingthe processesof life cycle were determined, and values forthe apparent activationenergy for each reaction were computed.The reactions were discussedwith special reference to theirrelationship with photosyntheticprocess was discussed.

(Received November 7, 1959; )     

Functional Reconstitution of Plasma Membrane H+-ATPase from Mung Bean (Vigna radiata L.) Hypocotyls in Liposomes Prepared with Various Molecular Species of Phospholipids

The activity of solubilized plasma membrane ATPase is affectedby the nature of exogenously added molecular species of phospholipids.To examine the role of the polar head group and of the molecularspecies of phospholipids in H⁺-pumping, the ATPase solubilizedfrom plasma membranes of mung bean (Vigna radiata L.) hypocotylswas reconstituted in liposomes prepared with a variety of phospholipids. The extent of activation of solubilized plasma membrane ATPasedue to the addition of 1-palmitoyl 2-oleoyl-phospholipids (PO-phospholipids)and asolectin decreased in the following order: POPS POPC asolectin POPG > POPE > POPA (see List of Abbreviations). H⁺-pumpinginto proteoliposomes reconstituted with asolectin and plasmamembrane ATPase was demonstrated by quinacrine fluorescencequenching in the presence of ATP-MgSO₄. H⁺-pumping was inhibitedby VO₄ and gramicidin D. When plasma membrane ATPase was reconstitutedin liposomes prepared with various PO-phospholipids, the abilityof PO-phospholipids to support H⁺-pumping into the proteoliposomesdecreased in the following order: POPG POPS > asolectin POPC. POPE and POPA failed to support any H⁺-pumping. A remarkablyhigh rate of H⁺-pumping was observed in proteoliposomes preparedwith 1-saturated 2-unsaturated fatty acids, such as POPC, butH⁺-pumping could hardly be detected in proteoliposomes preparedwith 1-, 2-unsaturated or 1-, 2-saturated fatty acids, suchas PSPC or DLPC. ATPase activity in proteoliposomes was dependenton the species of PO-phospholipids used for reconstitution anddecreased in the following order: POPS > POPG > POPC asolectin > POPA > POPE. DLPC (see List of Abbreviations)which includes a 1-, 2-unsaturated fatty acid supported onlymarkedly depressed activity. Both H⁺-pumping and the hydrolysis of ATP by the plasma membraneATPase are strongly affected by the polar head group and compositionof the fatty acyl chain of phospholipids used to prepare liposomesfor reconstitution of the ATPase. (Received May 31, 1991; Accepted September 18, 1991)     

EFFECT OF {alpha}-HYDROXYSULFONATES ON PHOTOCHEMICAL REACTIONS OF SPINACH CHLOROPLASTS AND PARTICIPATION OF GLYOXYLATE IN PHOTOPHOSPHORYLATION

1. The effect of -hydroxy sulfonates and sulfite, inhibitors ofglycolate oxidase, on the photochemical reactions of spinachchloroplasts was studied. The photo reduction of ferricyanideand NADP was not affected by the poisons, whereas the photophosphorylationand ¹⁴CO₂ fixation were inhibited.
2. Glyoxylate was photoreducedby the chloroplasts in the presenceof PPNR and glyoxylate reductase,and this reduction was acceleratedby the addition of NADP.ATP formation accompanied with thereduction of glyoxylate bythe illuminated chloroplasts wasobserved. It is supposed thatglyoxylate oxidizes the photoreducedNADPH₂ or PPNR and thusthe photophosphorylation is stimulated.

¹A part of this paper was presented at the annual meeting ofAgricultural Society of Japan, in August, 1964. ²Present address: Radiation Center of Osaka Prefecture, Sakai,Osaka.     

INHIBITION OF THE PHOTOSYNTHETIC CARBON DIOXIDE FIXATION OF GREEN PLANTS BY {alpha}-HYDROXYSULFONATES, AND ITS EFFECTS ON THE ASSIMILATION PRODUCTS

1. Several kinds of a-hydroxysulfonates, the bisulfite additioncompounds of aldehydes and ketones, were found to inhibit thephotosynthetic carbon dioxide fixation of the barley and wheatseedlings, tobacco leaf and Chlorella cells. Bisulfite additioncompounds of glyoxal, glyoxylate and benzaldehyde were moreeffective in this respect than those of formaldehyde and acetaldehyde.
2. The presence of -hydroxysulfonate causes an increase in ratiosof :¹⁴CO₂ incorporated in glycolate and alanine, and a decreasein incorporation in serine, malate, isocitrate and citrate.It was inferred that these changes are caused by the blockingof the formation of glyoxylate through inhibition of glycolicacid oxidase by the poison.
3. A reaction scheme was proposedto account for the above-statedresults, and the bearing ofthese findings on the possible roleof glycolic acid oxidasein the photosynthetic carbon dioxidefixation and in the formationof amino and organic acids wasdiscussed.

(Received December 8, 1961; )     

Biosynthetic mechanism of glycolate in Chromatium 6. Glycolate formation and metabolism under low O21

Under low O₂ (0.05 mM O₂), there was no measurable excretionof glycolate or glycine by Chromatium cells, unlike the caseof their incubation under high (0.7 mM) O₂ However, upon additionof non-radioactive glycolate and glycine to the suspension medium,there occurred a measurable incorporation of ¹⁴CO₂ into thesecompounds, which were then excreted extracellularly; the totalradioactivities measured were approximately 15% of the totalCO₂ fixed photosynthetically. This phenomenon could be as cribedto the dilution of the intracellular pools by the compoundsadded. The results indicate that under low O₂ the glycolatemolecules produced are metabolically further transformed inthe bacterial cells. The incorporation of ¹⁴CO₂ into the extracellularglycolate fraction was maximal at 0.3 mM glycolate in both highand low O₂. Presumably, glycolate formed in the bacterial cellsunder both the high and low O₂ is metabolized in a similar manner,although the excess glycolate and glycine molecules are rapidlyexcreted. During glycolate metabolism CO₂ was evolved from anisonicotinylhydrazide-sensitive reaction, suggesting that thepathway <glycolate glycine . CO₂ was similar in green plants.The results thus indicate that studies on glycolate and glycinemetabolism in the anaerobic bacterium, Chromatium, provide auseful model system for elucidating the mechanism of photorespirationin green plants. (Received May 19, 1978; )     

Fatty acid synthesis by spinach chloroplasts II. The path from PGA to fatty acids

By incorporation of ³H₂O into the fatty acid chain in the presenceof unlabeled precursor, we showed that fatty acids are synthesizedfrom PGA, PEP and pyruvate by intact spinach chloroplasts inthe light. ¹³C-tracer experiments confirmed that 1-C of pyruvateis decarboxylated and 2-C is incorporated into fatty acids bythe chloroplasts. The patterns of fatty acids synthesized fromPGA and pyruvate were the same as that from acetate. The highestrate of fatty acid synthesis was reached at the physiologicalconcentration of PGA (3 mM) and pyruvate (1 mM). These resultsindicate the operation of the following path in the chloroplastsin light: PGA-PEPPyruvateacetylCoAfatty acids. Since citrateand OAA were much less active and malate and glyoxylate wereinert as precursors for fatty acid synthesis, PEP or pyruvatecarboxylation, citrate lyase reaction and malate synthetasereaction are not involved in the formation of acetylCoA andfatty acids. Since pyruvate was much more effective as a substratefor fatty acid synthesis than lactate, acetaldehyde or acetate,direct, decarboxylation path is considered to be the primarypath from pyruvate to acetylCoA. The insignificant effect ofchloroplast-washing on fatty acid synthesis from PGA and pyruvateindicates that the glycolytic path from PGA to pyruvate is associatedwith the chloroplasts. Since pyruvate was more effectively incorporatedinto fatty acids than acetylCoA, it is unlikely that pyruvatedecarboxylation to acetylCoA is due to mitochondria contaminatingthe chloroplast preparation. On the basis of measurements of ³H₂O incorporation in the lightand dark, the activity of fatty acid synthesis in spinach leavesappears to be shared by the activities in chloroplasts (87%)and other organelles (13%). ¹ Present address: Radioisotope Centre, University of Tokyo,Yayoi, Bunkyo 113, Japan. (Received August 26, 1974; )     

Carbon Isotope Ratios of Epidermal and Mesophyll Tissues from Leaves of C3 and CAM Plants

The ¹³C values for epidermal and mesophyll tissues of two C₃plants, Commelina communis and Tulipa gesneriana, and a CAMplant, Kalancho daigremontiana, were measured. The values forthe tissues of both C3 plants were similar. In young leavesof Kalancho, the epidermis and the mesophyll showed S13C valueswhich were nearly identical, and similar to those found in C3plants. However, markedly more negative values for epidermalcompared to mesophyll tissue, were obtained in the mature Kalancholeaf. This is consistent with the facts that the epidermis ina CAM leaf is formed when leaves engage in C₃ photosynthesisand that subsequent dark CO₂ fixation in guard cells or mesophyllcells makes only a small contribution to total epidermal carbon. (Received January 27, 1981; Accepted May 14, 1981)     

Effect of Uncouplers on Photo-reactivation of Tris(pH 8.8) and 2,6-Dichlorophenol Indophenol-treated Chloroplasts

The oxygen-evolving activity of chloroplasts was lost by Tris(pH8.8)-washing and restored by 2,6-dichlorophenol indophenol treatmentand light exposure. One function of light was the generationof a high-energy state (pH) in chloroplasts, because the additionof uncouplers such as carbonylcyanide-m-chlorophenylhydrazone,atebrin, NH₄Cl, gramicidin J(S), valinomycin, A23187 [GenBank] and tetracaineinhibited restoration of the oxygen-evolving activity. The generationof a high-energy state in these chloroplasts was proven by thelight-induced H⁺-incorporation and uncoupler-stimulated electrontransport of the Mehler reaction type. (Received February 15, 1981; Accepted May 12, 1982)     

Maximum H+/h{nu}PSI Stoichiometry of Proton Transport during Cyclic Electron Flow in Intact Chloroplasts Is at Least Two, but Probably Higher than Two

Effects of antimycin A on 9-aminoacridine (9AA) fluorescencequenching by intact chloroplasts during light-dependent electronflow to different electron acceptors indicated that considerablecyclic electron flow occurs concurrently with linear electrontransport already at low PFDs, when oxygen supported electronflow, but not, when nitrite or methylviologen (MV) were present.Quantum efficiencies of the use of 696 and 675 nm light werecalculated for oxygen-, nitrite- and MV-dependent linear electronflows. Since H⁺/e=3 during linear electron transport [Ivanov(1993) Photosynthesis, p. 111; Kobayashi et al. (1995) PlantCell Physiol. 36: 1613] and comparable 9AA fluorescence quenchingindicates comparable transthylakoid proton gradients, totalproton transport could be calculated and part of it could beassigned to linear and the remainder to cyclic electron transportwhen oxygen was electron acceptor. Quanta of 696 nm light notused to support linear electron flow to oxygen at h/e=2 wereassumed to be available for coupled proton transport duringcyclic electron flow. H⁺/h ratios for cyclic electron transportobtained on this basis were consistently higher than 1 and occasionallyapproached 3. No allowance was made in these calculations foroxidized P700 in the reaction center of PSI, which could notdonate electrons to the cyclic pathway, and for reduced Q_A inthe reaction center of PSII. It therefore appears likely thatmaximum H⁺/h ratios in cyclic electron transport are higherthan values calculated in this work. Our observations with intactchloroplasts agree in principle with those of [Heath (1972)Biochim. Biophys. Acta 256: 645] with thylakoids, who also reportedhigh H⁺/ e ratios in cyclic electron transport. These ratiosare briefly discussed in relation to the H⁺/ATP stoichiometryof ATP production during carbon assimilation of leaves and toprotection of chloroplasts against photoinactivation. ²Present address: Timiriasev Institute of Plant Physiology,Russian Academy of Sciences, Botanicheskaya, 35, Moscow, Russia ³Present address: Department of Forestry, Faculty of Agriculture,Kyushu University, Hakozaki, Higashi-ku, Fukuoka, 812 Japan     

Formation of Hydrogen Peroxide and Oxygen Dependence of Photosynthetic CO2 Assimilation by Intact Chloroplasts

1. Hydrogen peroxide excretion by photosynthesizing intact spinachchloroplasts was determined. The rates were dependent on theoxygen concentration and on the ATP/NADPH requirement of thefinal electron acceptor. Upon CO₂ assimilation a maximum rateof 0.9 µmol H₂O₂/mg chlorophyll/hr and half saturationat 7.5 x 10^–5 M O₂ were found. Excretion of H₂O₂ was considerablyreduced upon photosynthetic reduction of glycerate 3-phosphateor oxaloacetate.
2. Light- and HCO₃-saturated CO₂ assimilationwas inhibited bymore than 50% by anaerobic conditions, whereuponquantum efficiencywas also drastically decreased. However,no anoxic influencewas detected with glycerate 3-phosphateas the terminal electronacceptor and the quantum requirementwith this acceptor wasnot increased by anaerobiosis. Thus theenhancing effect ofoxygen on CO₂ assimilation was ascribedto an improvement ofphotosynthetic ATP supply.
3. Since thestimulation of anaerobic photosynthetic CO₂ assimilationbyoxygen was markedly greater than the concomitant increaseinH₂O₂ evolution, photosynthetic oxygen reduction alone isnotsufficient to produce the required additional ATP for theobservedenhanced CO₂ assimilation. But it provides a meansto avoidthe over-reduction of photosynthetic electron carriersand thusenables aerobic cyclic photophosphorylation. This supportsthehypothesis that cyclic photophosphorylation is not an alternativeto ATP formation by "pseudocyclic" electron transport, but ratherthat it depends on the latter.

(Received January 5, 1981; Accepted March 9, 1981)