Energy conversion and changes in physical parameters in chloroplasts and subchloroplast particles II. Energy conversion in chloroplasts and different types of subchloroplast particles

The light-induced absorbance change at 515 nm, light-inducedhydrogen ion uptake and ATP formation were compared in chloroplastsand different types of sonicated subchloroplast particles. Noparallel relationship among the activities for ATP formation,hydrogen ion uptake and the 515-nm change was observed in differenttypes of preparations. NH₄Cl inhibited ATP formation in chloroplastsbut had little effect on subchloroplast particles. In contrast,the light-induced hydrogen ion uptake was inhibited by NH₄Clin a similar manner. Tetraphenylboron (TPB), at 1 µM, inhibited ATP formationby about 30% in both chloroplasts and subchloroplast particles.In the presence of TPB, ATP formation in chloroplasts was stronglyinhibited by NHC₄Cl, but in subchloroplast particles the additionalinhibitory effect of NH₄Cl was small. A synergistic inhibitionof photophosphorylation by valinomycin plus NH₄Cl was much clearer.Although acceleration of the recovery of the 515-nm change byNH₄Cl or valinomycin was moderate, the 515-nm change virtuallydisappeared when NH₄Cl and valinomycin were added simultaneously. Although the membrane potential has a major role as the principaldriving force for ATP formation in subchloroplast particles,the simultaneous abolishment of the pH gradient and membranepotential may be required to uncouple ATP formation. ¹Present address: Fukuoka Women's University, Kasumigaoka, Fukuoka813, Japan. ²Present address: Ryukyu University, Naha, Okinawa 903, Japan. (Received February 5, 1974; )     

Fatty acid synthesis by spinach chloroplasts I. Property of fatty acid synthesis from acetate

Intact chloroplasts (about 70% Class I chloroplasts) isolatedfrom spinach leaves incorporated 150 nmoles of [1-¹⁴C] acetateinto fatty acids per mg chlorophyll in 1 hr at pH 8.3, 25°Cand 25,000 lux. On electron and phase-contrast microscopiescombined with hypotonic treatment of chloroplasts, this syntheticactivity was shown to be proportional to the percentage of ClassI chloroplasts in the preparation. Light was necessary for thesynthesis, the activity in the complete reaction mixture inthe dark being only 2% of that in the light. The synthetic activityincreased with increasing intensities of light to reach saturationat 6,000 lux. CoA and ATP were most effective as cofactors,HCO₃^–, HPO₄^2–, Mg^2$ and Mn^2$ were less effective.ATP could be replaced by ADP in the presence of Pi, suggestingpossible supply of ATP by photophosphorylation. Omission ofthe NADPH-generation system and NADH did not affect the synthesis,indicating sufficient provision of endogenous NADPH and NADHin intact chloroplasts under light. Addition of DTE did notcause recovery of the synthetic activity of intact chloroplastsin the dark. ¹ Present address: Radioisotope Centre, University of Tokyo,Yayoi, Bunkyo, Tokyo 113, Japan. (Received August 26, 1974; )     

Light-induced ATP Formation from Acetyl Phosphate and ADP by Broken Spinach Chloroplasts

Spinach chloroplasts catalyzed ATP formation from acetyl phosphateand ADP when exposed to light. No ATP formation was detectablein the dark. In the absence of ADP, chloroplasts did not hydrolyzeacetyl phosphate in the light or dark. Neither high-energy phosphatessuch as creatine phosphate and phosphoenol pyruvate nor inhibitorsof photophosphorylation competitive with P_i, such as ß-naphthylmonophosphate, phenyl phosphate and pyridoxal 5-phosphate, couldsubstitute for acetyl phosphate as a P_i donor. The apparentK_m values for acetyl phosphate and P_i were 0.81 mM and 0.25mM, respectively. The maximal rate of ATP formation with acetylphosphate and P_i were 331 and 521 µmol ATP formed mg chl^–1hr^–1, respectively. The optimum pH value for acetyl phosphate-dependentATP formation was about 8.0. NH₄Cl, dicyclohexylcarbodiimideand triphenyltin chloride inhibited the acetyl phosphate-dependentATP formation. Acid-base transition also could induce subsequentATP formation from acetyl phosphate and ADP. These results suggestthat the acetyl phosphate-dependent ATP formation requires theformation and the utilization of a proton-motive force as ordinaryphotophosphorylation does. ¹ This work was supported in part by Grants-in-Aid for ScientificResearch from the Ministry of Education, Science and Culture,Japan to H. S. Part of this work was reported at the 1981 AnnualMeeting of the Japanese Society of Plant Physiologists (Sapporo,May 8, 1981). (Received August 25, 1981; Accepted November 1, 1981)     

Effects of Ammonia on Respiration, Adenylate Levels, Amino Acid Synthesis and CO2 Fixation in Cells of Chlorella vulgaris 11h in Darkness

The effects of NH₄Cl on respiration, adenylate and free aminoacid levels as well as dark CO₂ fixation were investigated usingnitrogen-starved Chlorella vulgaris 11h cells with or withoutaddition of methionine sulfoximine (MSX), an inhibitor of glutaminesynthetase. Upon addition of NH₄Cl (1 mM) to the cells not treatedwith MSX, respiration was stimulated and the level of ATP droppedrapidly, while the levels of ADP and AMP increased. NH₄Cl alsostimulated amino acid synthesis, especially of glutamine, andmarkedly enhanced dark CO₂ fixation. Addition of NH₄Cl to MSX-treatedcells stimulated respiration and lowered the level of ATP, butdid not enhance glutamine synthesis and only slightly stimulateddark CO₂ fixation. ⁴On leave from Institute of Medical Science, Advance R &D Co. Minami-Hashimoto, Sagamihara, Kanagawa-ken 220, Japan (Received January 28, 1984; Accepted April 19, 1984)     

Effect of Methionine Sulfoximine on Photosynthetic Carbon Metabolism in Wheat Leaves

Methionine sulfoximine (MSO) greatly reduced the carbon dioxideexchange rate (CER) of detached wheat (Triticum aestivvm L.cv Roland) leaves in 21% O₂, but only slightly reduced it in2% O₂. A supply of 50 mM NH₄Cl had little effect on the CERirrespective of the O₂ concentration. A simultaneous additionof glutamine and MSO protected against the inhibition of photosynthesisto a considerable extent and caused the accumulation of moreNH₃ than did the addition of MSO alone. Fixation of ¹⁴CO₂ in wheat leaves was inhibited by MSO treatmentin 22% O₂, and there was decreased incorporation of ¹⁴G intoamino acids and sugars and increased label into acid fractions.The addition of MSO and glutamine together eliminated the effectof MSO on the photosynthetic ¹⁴CO₂ fixation pattern. NH₄Cl stimulatedthe synthesis of amino acids from ¹⁴CO₂, especially the synthesisof serine in 22% O₂. Our observations show that factors other than the uncouplingof photophosphorylation by accumulated NH₃ may be responsiblefor the early stage of photosynthesis inhibition by MSO underphotorespiratory conditions. ¹Present address: Department of Agricultural Chemistry, KyushuUniversity, Fukuoka 812 Japan. ²Also at U.S. Department of Agriculture, Agricultural ResearchService, Urbana, Illionois 61801, U.S.A. (Received September 13, 1983; Accepted February 2, 1984)     

Light-induced changes in membrane potential in Spirogyra

Spirogyra cells exhibited changes in membrane potential whenthey were exposed to light. Cells made chloroplast-free didnot show any light-induced potential change (LPC) upon illuminationwith white light and also monochromatic red (680 nm) and farred (720 nm) light. LPC was observed when the cell containedonly a small fragment of chloroplast, whether the cell had anucleus or not. The magnitude of LPC depended on the amountof chloroplast in the cell. DCMU at 10^–5 M, CCCP at 10^–5 M and DNP at 10^–4M at pH 5.5 suppressed LPC, while CCCP at 1–5 ? 10^–6M, NH₄Cl at 5 ? 10^–2 M and DNP at 10^–4 M at pH 7.0stimulated LPC. PMS at 10^–4 M stimulated LPC and couldinduce LPC which was completely inhibited by DCMU. These factssuggest that LPC is related to noncyclic and cyclic electronflows. The influences of light and dark conditions and various metabolicinhibitors (DCMU, DNP, CCCP, NH₄Cl) on ATP level have been investigated.No significant difference in the ATP level was observed betweencells in the light and dark. DNP at 10^–4 M (pH 5.5) andCCCP at 5 ? 10^–6 M decreased the ATP level significantly,while DCMU and NH₄Cl only slightly. Good correlation was notfound between the total ATP level and LPC in Spirogyra. LPC occurred even when the external medium contained only asingle salt such as KCl, NaCl or CaSO₄. LPC was also recorded in chloroplasts in situ and in vitro.The mode of LPC of chloroplasts was quite different from thatof the cell. On illumination, the chloroplast potential changedvery rapidly and transiently in the positive direction thenrecovered spontaneously to almost the original potential level. Possible causes of LPC are discussed in relation to the electrogenicion pump. ¹ Present address: Department of Botany, Faculty of Science,University of Tokyo, Hongo, Bunkyo, Tokyo 113, Japan. (Received November 9, 1977; )     

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; )     

STUDIES ON PHOTOPHOSPHORYLATION: I. TWO-STEP EXCITATION KINETICS OF PHOTOPHOSPHORYLATION

Based on the observations on the time lag and the low efficiencyof photophosphorylation at low light intensities, a ‘two-stepexcitation kinetics’ of photophosphorylation of chloroplastswas developed, which could explain some of the hitherto unexplainedfacts concerning photophosphorylation. By analyses of the experimental results along the line of thetheory, it was inferred that the assumed substance (X) responsiblefor ATP formation occurs in a relatively large quantity of about1 mole/5–20 moles of chlorophyll. It was concluded thatthe high energy intermediate (X^**) of ATP formation which wasassumed to accumulate on pre-illuminating the chloroplasts (inthe absence of ADP and Pi) does not represent a side pool ofextra energy, but a substantial intermediate in the normal courseof ATP formation. Alternative possibilities for the explanation of the experimentalfacts were also discussed. ¹This paper is submitted to the University of Tokyo to fulfilla part of the requirements for the doctorate of H. SAKURAI.     

ATP activates DNA synthesis by acting on P2X receptors in human osteoblast-like MG-63 cells

In human osteoblast-like MG-63cells, extracellular ATP increased [³H]thymidineincorporation and cell proliferation and synergistically enhancedplatelet-derived growth factor- or insulin-like growth factor I-induced[³H]thymidine incorporation. ATP-induced[³H]thymidine incorporation was mimicked by thenonhydrolyzable ATP analogs adenosine5'-O-(3-thiotriphosphate) and adenosine 5'-adenylylimidodiphosphate and was inhibited by the P2purinoceptor antagonist suramin, suggesting involvement of P2purinoceptors. The P2Y receptor agonist UTP and UDP and a P2Y receptorantagonist reactive blue 2 did not affect [³H]thymidineincorporation, whereas the P2X receptor antagonist pyridoxalphosphate-6-azophenyl-2',4-disulfonic acid inhibited ATP-induced[³H]thymidine incorporation, suggesting that ATP-inducedDNA synthesis was mediated by P2X receptors. RT-PCR analysis revealedthat MG-63 cells expressed P2X₄, P2X₅,P2X₆, and P2X₇, but not P2X₁,P2X₂, and P2X₃, receptors. In fura 2-loadedcells, not only ATP, but also UTP, increased intracellularCa²⁺ concentration, and inhibitors for severalCa²⁺-activated protein kinases had no effect on ATP-inducedDNA synthesis, suggesting that an increase in intracellularCa²⁺ concentration is not indispensable for ATP-induced DNAsynthesis. ATP increased mitogen-activated protein kinase activity in aCa²⁺-independent manner and synergistically enhancedplatelet-derived growth factor- or insulin-like growth factor I-inducedkinase activity. Furthermore, the mitogen-activated protein kinasekinase inhibitor PD-98059 totally abolished ATP-induced DNA synthesis. We conclude that ATP increases DNA synthesis and enhances the proliferative effects of growth factors through P2X receptors byactivating a mitogen-activated protein kinase pathway.

     

Pyridoxal 5-phosphate, Phenyl Phosphate and Acetyl Phosphate, as Inhibitors of Photophosphorylation Competitive with Phosphate

Pyridoxal 5-phosphate, phenyl phosphate and acetyl phosphate,as well as rß-naphthyl monophosphate, inhibited photophosphorylationof spinach chloroplasts competitively with P_i and noncompetitivelywith ADP. The apparent dissociation constant of the inhibitor-enzymecomplex (K_i) values of pyridoxal 5-phosphate, phenyl phosphateand acetyl phosphate for the P_i site were 1.1, 3.8 and 2.4 _mM,respectively. These organic phosphates inhibited Ca²⁺-ATPaseof the isolated coupling factor 1 (CF₁) (EC 3.6.1.3 [EC] ) noncompetitivelywith ATP. AMP, creatine phosphate, fructose 1,6-bisphosphate,glucose 6-phosphate, 3-phosphoglyceric acid, ribose 5-phosphateand PP_i did not significantly inhibit photophosphorylation.Like rß-naphthyl monophosphate, pyridoxal 5-phosphateand phenyl phosphate inhibited photophosphorylation and thecoupled electron transport, but were almost without effect onthe basal electron transport. On the other hand, acetyl phosphateconsiderably inhibited photophosphorylation, but had almostno effect on the coupled electron transport rate and the basalrate. The results suggest that these organic phosphates inhibitphotophosphorylation by binding at the P_i site on the activecenter of CF₁ and that their binding inhibits the ATPase activityof isolated CF₁. These four organic phosphates which inhibited photophosphorylationcompetitively with Pi could not substitute for ADP or ATP ininhibiting ferricyanide photoreduction by decreasing H⁺-permeabilitythrough CF₁ and in protecting the ATPase of isolated CF₁ againstcold-anion inactivation. ¹ This work was supported in part by Grants-in-Aid for ScientificResearch from the Ministry of Education, Science and Culture,Japan to H.S. (Received May 25, 1981; Accepted September 28, 1981)     

Effect of Ammonia on Dark CO2 Fixation by Anabaena Cells Treated with Methionine Sulfoximine

Dark CO₂ fixation by Anabaena cylindrica was stimulated aboutthree-fold by the addition of NH₄Cl to the cells. The ¹⁴CO₂incorporation experiments showed that ¹⁴C is most rapidly incorporatedinto aspartate and then glutamine by adding NH4CI. Glutamineaccumulated predominantly after the addition of NH₄Cl showingthat NH₄ is incorporated into glutamine by glutamine synthetase.The stimulating effect of NH4Cl on CO₂ fixation and amino acidsynthesis was suppressed by methionine sulfoximine, an inhibitorof glutamine synthetase. It was suggested that dark CO₂ fixationwas stimulated by the action of glutamine synthesis which isenhanced by ammonia. (Received February 10, 1981; Accepted April 2, 1981)     

Intracellular acidification induced by passive and active transport of ammonium ions in astrocytes

We describe anunconventional response of intracellular pH toNH₄Cl in mouse cerebralastrocytes. Rapid alkalinization reversed abruptly to be replaced by anintense sustained acidification in the continued presence ofNH₄Cl. We hypothesize thathigh-velocity NH⁺₄ influx persisted after thedistribution of ammonia attained steady state. From the initial rate ofacidification elicited by 1 mMNH₄Cl in bicarbonate-bufferedsolution, we estimate that NH⁺₄ entered at avelocity of at least 31.5 nmol · min¹ · mgprotein¹. This rateincreased with NH₄Clconcentration, not saturating at up to 20 mMNH₄Cl. Acidification wasattenuated by raising or lowering extracellularK⁺ concentration.Ba²⁺ (50 µM) inhibited theacidification rate by 80.6%, suggesting inwardly rectifyingK⁺ channels as the primaryNH⁺₄ entry pathway. Acidification was 10-foldslower in rat hippocampal astrocytes, consistent with the differencereported for K⁺ flux in vitro. Thecombination of Ba²⁺ and bumetanideprevented net acidification by 1 mMNH₄Cl, identifying theNa⁺-K⁺-2Clcotransporter as a second NH⁺₄ entry route.NH⁺₄ entry viaK⁺ transport pathways could impact"buffering" of ammonia by astrocytes and could initiate theelevation of extracellular K⁺concentration and astrocyte swelling observed in acute hyperammonemia.

     

Fractionation of the fatty acid synthesizing system from the developing soybean cotyledon into a particulate and soluble component

The fatty acid synthesizing system from developing soybean cotyledonswas fractionated intoa precipitate fraction and a supernatantfraction using carbowax-4000. Both fractions were necessaryfor fatty acid synthesis. The supernatant fraction was heatstable, non-dialyzable and lost its activity when incubatedwith pronase. Fatty acid synthesis required NADH and NADPH aswell as ATP, KHCO₃ and MnCl₂. The crude enzyme produced stearicand oleic acid while the recombined system produced predominadystearic acid ¹Presented in part at the American Society of Plant PhysiologistMeeting in Bloomington, Indiana, August 1970 (Received November 27, 1970; )     

Plasmalemma Transport of HCO-3 and OH- in Chara corallina: Inhibitory Effect of Ammonium Sulphate

The influence of (NH₄)₂SO₄ on ¹⁴C assimilation and cyclosisin internodal cells of Chara corallina was investigated. Severeinhibition of ¹⁴C assimilation was found at pH values above7·0, this inhibition being correlated with the exogenouslevel of NH3 rather than NH⁺₄. Cyclosis was also affected athigher concentrations of (NH₄)₂SO₄. This effect was similarlycorrelated with exogenous levels of NH₃. ¹⁴C assimilation was inhibited non-competitively by (NH₄)₂SO₄,the apparent Km being increased from 0·55 to 1·5mM. The results suggest that the site(s) of inhibition is locatedat the plasmalemma, rather than at the chloroplasts. (Evidencein support of in vivo uncoupling of photophosphorylation, bylow concentrations of (NH₄)₂SO₄, was not obtained). Significant perturbation of the OH^– efflux pattern wasobserved as the level of (NH₄)₂SO₄ was increased. Induced migrationof efflux sites indicates that NH₃ may interfere with the cellularmechanism that controls OH^– transport. Using a cell-segmentisolating chamber it was shown that (NH₄)₂SO₄ inhibited OH^–efflux rather than HCO^–₃ transport. This inhibitory effectwas readily reversible. These data are discussed in terms of a possible relationshipbetween the observe NH₄)²SO₄ stimulation of ³⁶Cl^– influxand the effect of this compound on ¹⁴C assimilation.     

The regulation of ammonia uptake in Chara australis

The regulation of ammonia uptake was investigated in internodalcells of the freshwater alga Chara australis. Ammonia uptakewas estimated by monitoring (i) its depletion from the bathingsolution, (ii) the uptake of radiolabelled methylamine, an analogueof ammonia, and (iii) depletion of ammonia in the unstirredlayer with the microelectrode ion-flux estimation technique(MIFE). Distribution of methylamine (¹⁴CH₃NH₃⁺) between thevacuole and cytoplasm was estimated with efflux analysis. Whencells were bathed continuously in solutions containing ammoniaor methylamine, the uptake rates of both amines decreased over12 to 48 h despite the continuing existence of a large electrochemicalgradient favouring influx of the NH⁺₄ and CH₃NH⁺₄ cations. Treatmentwith 1.0 to 10.0 mM MSX, an inhibitor of glutamine synthetase,caused the internal ammonia concentration to rise and reducedthe subsequent uptake of ammonia and methylamine by up to 70%within 2 h. These results suggest that the permease facilitatingNH⁺₄/CH₃NH⁺₄ influx is under feedback or kinetic regulationfrom either internal ammonia or an intermediate of nitrogenassimilation. Treatment with metabolic inhibitors (CCCP, azide and DCMU) andsome weak acids (DMO and butyric acid) for 30 to 60 min inhibitedmethylamine uptake, but the changes in the electrical potentialdifference across the plasma membrane could not account forthe magnitude of inhibition. The rate of cytopiasmic streaming,which is an indicator of the cellular ATP concentration in Chara,was inhibited by many of these treatments. However, under certainconditions of external pH and concentration, butyric acid couldreversibly inhibit ammonia and methylamine uptake without affectingcytoplasmic streaming, demonstrating that a decrease in cytoplasmicATP concentration was not responsible for the inhibition. Theeffect of butyric acid was rapid, causing a 60% inhibition ofuptake in 15 min. We conclude that weak acids can inhibit theNH⁺₄/CH₃NH⁺₄ permease by acidifying the cytoplasm and suggestthat this may also explain the effects of the metabolic inhibitorson ammonia and methylamine uptake. Key words: Ammonia, methylamine, uptake, regulation, Chara     

Effectors of fatty acid synthesis in hepatoma tissue culture cells

An investigation was undertaken to better understand the process of fatty acid synthesis in hepatoma tissue culture (HTC) cells. By comparing the findings to the normal liver some of the differences between normal and cancer tissue were defined. Incubation of the HTC cells in a buffered salt-defatted albumin medium showed that fatty acid synthesis was dependent upon the addition of substrate. The order of stimulation was glucose + pyruvate ～- glucose + alanine ～- glucose + lactate ～- pyruvate > glucose > alanine ? no additions. Fatty acid synthesis in HTC cells was decreased by oleate. In these respects HTC cells are similar to the liver; however, in contrast to the normal liver, N⁶, O²-dibutyryl cyclic adenosine 3′,5′-monophosphate (dibutyryl-cAMP) did not inhibit glycolysis or fatty acid synthesis. The cytoplasmic redox potential, as reflected by the lactate to pyruvate ratio, was found to be elevated compared to normal liver but unchanged by the addition of dibutyryl cAMP. Since higher rates of fatty acid synthesis are associated with lower lactate-to-pyruvate ratios in normal liver, it was expected that by decreasing the lactate-to-pyruvate ratio in HTC cells the rate of fatty acid synthesis would increase. One way to lower the lactate to pyruvate ratio is to increase the activity of the malate-aspartate shuttle. Stimulators of the hepatic malate-aspartate shuttle in normal liver (ammonium ion, glutamine, and lysine) had mixed effects on the redox state and fatty acid synthesis in HTC cells. Both ammonium ion and glutamine decreased the redox potential and increased the rate of fatty acid synthesis. Lysine was without effect on either process. Since NH₄Cl and glutamine stimulate the movement of reducing equivalents into the mitochondria and decrease the redox potential, then the stimulation of fatty acid synthesis by NH₄Cl and glutamine may be due to an increase in the movement of reducing equivalents into the mitochondria. However, if the shuttle were rate determining for fatty acid synthesis the rate from added lactate would be the same as from glucose alone but would be lower than from pyruvate which does not require the movement of reducing equivalents. This was not the case. Lactate and pyruvate gave comparable rates which were higher than glucose alone. Other possible sites of stimulation were investigated. The possibility that NH₄⁺ and glutamine stimulated fatty acid synthesis by activating pyruvate dehydrogenase was excluded by finding that dichloroacetate, an activator of pyruvate dehydrogenase, did not stimulate fatty acid synthesis when glucose was added. Stimulation by NH₄⁺ and glutamine at steps beyond pyruvate dehydrogenase was ruled out by the observation that NH₄⁺ caused no stimulation from added pyruvate. NH₄⁺ and glutamine did not alter the pentose phosphate pathway as determined by ¹⁴CO₂ production from [1-¹⁴C]- or [6-¹⁴C]glucose. Ammonium ion and glutamine increased glucose consumption and increased lactate and pyruvate accumulation. The increased glycolysis in HTC cells appears to be the explanation for the stimulation of fatty acid synthesis by NH₄⁺ and glutamine, even though glycolysis is much more rapid than fatty acid synthesis in these cells. The following observations support this conclusion. First, the percentage increase in glycolysis caused by NH₄⁺ or glutamine is closely matched by the percentage increase in fatty acid synthesis. Second, the malate-aspartate shuttle, the pentose phosphate pathway, and the steps past pyruvate are not limiting in the absence of NH₄⁺ or glutamine.     

Long chain fatty acid synthesis in developing castor bean seeds I. The operation of the path from acetate to long chain fatty acids in a subcellular particulate system

The path of LFA synthesis from acetate in developing castorbean seeds was associated with subcellular 10,000 g particles.Further fractionation of these particles by a stepwise densitygradient method showed the high possibility that the site ofLFA synthesis is the proplastid. A study on cofactor requirementswhen [1-¹⁴C]acetate predominantly incorporated into LFAs indicatedthat synthesis would be achieved by acetyl-CoA carboxylation,malonyl-ACP condensation. ATP, CoA, HCO₃^– and Mg⁺⁺ orMn⁺⁺ were essential for synthesis from acetate by the 10,000gparticulate system. Results of inhibhitor experiment suggestedthat the supply of ATP to the LFA synthesizing system is broughtabout by mitochondrial oxidative phosphorylation, when acetateis the sole precursor for LFA synthesis in this system. TheNADPH generating system was contained in the paticles, althoughthe addition of NADP⁺ and G-6-P increased synthesis. NADH markedlystimulated LFA synthesis from acetate. The primary role of NADHseems to be as a direct reductant in both steps involving thereduction and oxidative desaturation of fatty acid chains; particularly,in the former step, although NADH partially contributes to thesupply of ATP as a respiratory substrate. It is unlikely thatNADH works as a hydrogen donor to NADP⁺. LFA synthesis by thecastor bean particulate system was not stimulated by light,thus differing from that by leaf chloroplasts. (Received July 23, 1973; )     

Biosynthesis of folic acid compounds in plants VI. The occurrence and properties of the dihydrofolate-synthesizing enzyme in pea seedlings

An enzyme, which catalyzes the formation of dihydrofolate fromdihydropteroic acid and L-glutamic acid, was found in pea seedlings.The enzyme was purified approximately 25-fold from the crudeextracts of pea seedlings, and its some properties were investigated.Optimum pH for the enzyme activity was found to be 8.8. Pteroicand tetrahydropteroic acids were not active as substrate. Theenzymatic reaction required as cofactors ATP, divalent (Mg²⁺or Mn²⁺) and univalent (K⁺, NH₄⁺ or Rb⁺) cations. The productwas characterized as dihydrofolic acid by bioautography. MICHAELIS constants for L-glutamic acid, ATP, dihydropteroicacid and Mg²⁺ were 7.0x10^–4, 9.0x10^–5, 3.5x10^–6and 1.2x10^–3 M, respectively. The MICHAELIS constant forMn²⁺ was 3.0x10^–4. The enzyme was inhibited by PCMB orsilver nitrate and, to some extent, by L-aspartic acid. Inhibitionby PCMB was completely reversed by addition of 2-mercaptoethanol.Enzyme activity was distributed widely among plants. The importanceof magnesium and potassium ions for enzyme catalysis is discussed. ¹For the previous paper, Part V, see Reference (30). (Received March 28, 1970; )     

Tentoxin Inhibits Both Photophosphorylation in Thylakoids and the ATPase Activity of Isolated Coupling Factor F1 from the Cyanobacterium Anacystis nidulans

Tentoxin strongly inhibited the ATPase activity of isolatedcoupling factor 1 (AF₁) from the cyanobacterium Anacystis nidulans,with 50% inhibition occurring at 0.3 µM. When thylakoidsfrom A. nidulans were preincubated with 0.3 µM tentoxinfor 30 min, photophosphorylation was inhibited by 50%. Measurementsof fluorescence from 9-aminoacridine indicated that tentoxininhibited the utilization of the proton gradient by ATP formationin thylakoids. These results indicate that tentoxin is a strongenergy-transfer inhibitor of photophosphorylation in A. nidulans.Tentoxin decreased the level of ATP in intact cells both inthe light and in darkness, its effects being much stronger inthe dark. Tentoxin at 50 µM strongly inhibited the growthof the cells. ³Present address: Corporate Research and Development Laboratory,Tonen Co. 1-3-1 Nishi-tsurugaoka, Ohi-machi, Saitama, 354 Japan ⁴Present address: Technology and Engineering Laboratories, AjinomotoCo., Inc. Suzuki-cho 1, Kawasaki, 210 Japan     

Relationship between light-induced potential change and internal ATP concentration in tonoplast-free Chara cells

The effect of the intracellular concentration of ATP ([ATP]₁)on the light-induced potential change (LPC) in tonoplast-freeChara cells was studied. The LPC was hardly affected by loweringthe [ATP]₁ by about 1/10 or by raising it to about 10 timesthe normal cytoplasmic concentration (0.5–1.3 mM). Theinsensitivity of LPC to [ATP]₁ excludes the possibility thatan increase in [ATP]₁ due to photosynthesis may induce the LPC.However, extreme lowering of the [ATP]₁ to about 1–2 µMcompletely inhibited LPC, although photosynthetic O₂ evolutionwas not significantly inhibited. This fact supports the hypothesisthat light stimulates the putative H⁺pump fueled by ATP. Theuncoupling agents DNP and CCCP greatly depolarized the membrane,and inhibited LPC strongly, but they did not decrease [ATP]₁.Photosynthetic O₂ evolution was inhibited to some extent by2 µM CCCP and strongly inhibited by 0.1 mM DNP. Sincethe membrane resistance increased significantly, these chemicalsare believed to act on the membrane as an inhibitor of the electrogenicH⁺ pump not as an H⁺conductor. Introduction of 1 mM ATP intocells treated with uncouplers, to a large extent restored theirability to produce LPC although the membrane potential in darknesswas maintained at a low level. ¹Present address: Niigata College of Pharmacy, 5829 Kamishinei-cho,Niigata 950-21, Japan. ²Present address: Department of Agricultural Chemistry, Collegeof Agriculture, Kyoto University, Kyoto 606, Japan. ³Present address: Department of Botany, Faculty of Science,University of Tokyo, Hongo, Tokyo 113, Japan. (Received March 9, 1979; )