The Role of Glycollic Acid in the Photoassimilation of Acetate by Chlorella pyrenoidosa

The kinetics of ³H-acetate assimilation by Chlorella pyrenoidosain the light were examined. The primary products of assimilationwere glycollate and succinate. After 10 sec glycollate contained45 per cent and succinate 25 per cent of the tritium incorporatedby the cells. The percentage of the total tritium in glycollateand succinate fell with time while that in citrate increased.Initially the specific activities (µc of ³H per µmoleof acid) of succinate and glycollate were greater than citrate.When ³H-¹⁴C-2-acetate was added to the cells, total dpm for³H and ¹⁴C in glycollate rapidly reached a steady state andgave a ³H/¹⁴C ratio of 10, compared with a ³H/¹⁴C ratio of 4in the acetate. This ³H/¹⁴C ratio in glycollate is found because³H is derived from ³H-¹⁴C-2-acetate and because the ¹⁴C is dilutedwith cold carbon from elsewhere. The addition of ¹⁴CO₂ at thesame time as ³H-¹⁴C acetate decreased the ³H/¹⁴C ratio in glycollatebut incorporation of ¹⁴C from ¹⁴CO₂ into glycollate was slowerthan incorporation from ¹⁴C-2-acetate. Although ¹⁴C from acetaterapidly appeared in glycollate, ¹⁴C-labelled glyoxylate wasnot detected. The ³H/¹⁴C ratio observed in glycollate rulesout formation of glycollate from acetate via glycoaldehyde.The available evidence did not support glycollate formationvia the Calvin cycle. ¹⁴C from ¹⁴C-Z-acetate appeared in glycollatebefore it did in phosphoglyceric acid. Total dpm for ³H, ¹⁴C,and ³H/^l4C ratio in Calvin cycle intermediates were not in equilibriumwith glycollic acid.     

The Photometabolism of Acetate by Chlorella pyrenoidosa

Chlorella pyrenoidosa can utilize sodium acetate as a carbonsource for growth in the light. Growth proceeds under aerobicconditions both in the presence and in the absence of carbondioxide, but under anaerobic conditions only in its presence.The assimilation of acetate does not result from oxidation tocarbon dioxide followed by photosynthetic fixation because theproducts of ¹⁴C-acetate assimilation are different from theproducts of ¹⁴CO₂ fixation in the presence of unlabelled acetate. In aerobic conditions 10-⁶ M DCMU induces a pattern of acetateassimilation in the light similar to that in the dark. Thus,in the presence of DCMU in the light, less acetate carbon isincorporated into cells, particularly into lipids, polysaccharide,and protein, and more is released as carbon dioxide than inits absence. The effect of 4 x 10^-3 M MFA on acetate assimilationin the presence of 10^-6 M DCMU is the same in light and dark.Acetate assimilation is unaffected by desaspidine and sodiumbisulphite. The mean generation time of C. pyrenoidosa growing on acetatein the light under aerobic conditions is 20 hours. When 10^-5M DCMU is added the mean generation time is 60 hours, the sameas that for Chlorella growing on acetate in the dark. The activityof the enzymes of the glyoxylate cycle, isocitrate lyase (E.C.4.1.3.1.)and malate synthetase (E.C.4.1.3.2.) is repressed in the light,but activity of both enzymes increases markedly when DCMU isadded.     

The Effect of Cycloheximide (Actidione) on Protein and Nucleic Acid Synthesis by Chlorella

Incorporation of ¹⁴C-phenylalanine, ¹⁴C-carbon dioxide, ¹⁴C-glucose,and ¹⁴C-glycine into the protein of Chlorella is inhibited bycycloheximide. A concentration of 2.5 µg per ml inhibitsincorporation by about 80 per cent; increasing the concentrationup to 10 µg per ml does not increase the degree of inhibition.The incorporation of ¹⁴C-adenine into ribonucleic acid (RNA)and deoxyribonucleic acid (DNA), and of ¹⁴C-glucose into polysaccharideis also inhibited. Unlike inhibition of protein synthesis, thatof nucleic acid and polysaccharide synthesis is observed onlyafter some delay. The delay is shortest for DNA synthesis andlongest for polysaccharide synthesis. Inhibition of ¹⁴C-glycineincorporation into DNA and RNA follows a similar pattern tothat obtained with ¹⁴C-adenine but the delay is much shorter.Cycloheximide also inhibits the formation of isocitrate lyasc(isocitrate-glyoxylate lyase, EC 4.1.3.1 [EC] ) when autotrophicallygrown cells are supplied with acetate.     

STUDIES ON THE METABOLISM OF UREA AND OTHER NITROGENOUS COMPOUNDS IN CHLORELLA ELLIPSOIDEA: III ASSIMILATION OF UREA

Assimilation of urea by Chlorella ellipsoidea was investigatedby using ¹⁴C-urea. It was revealed that urea carbon metabolizedby the N-starved cell was almost quantitatively recovered incarbon dioxide under dark-aerobic conditions. The rate of ureaconsumption was considerably influenced by the N-content ofalgal cells, practically no metabolism of urea being observedwith the cells containing more than 7 per cent N on a dry weightbasis. Similar results were also obtained when urea was replacedwith ammonia as nitrogen source. Based on the results obtained,a tentative scheme for the assimilation process of urea in Chlorellawas proposed. (Received February 7, 1960; )     

Dynamics of Carbon Photosynthetically Assimilated in Nodulated Soya Bean Plants under Steady-state Conditions 1. Development and Application of 13CO2 Assimilation System at a Constant 13C Abundance

A long-term, steady-state ¹³CO₂ assimilation system at a constantCO₂ concentration with a constant ¹³C abundance was designedand applied to quantitative investigations on the allocationof photoassimilated carbon in nodulated soya bean (Glycine maxL.) plants. The CO₂ concentration in the assimilation chamberand its ¹³C abundance were maintained constant with relativevariances of less than ±0.5 per cent during an 8-h assimilationperiod. At the termination of 8-h ¹³CO₂ assimilation by plantsat early flowering stage, the currently assimilated carbon relativeto total tissue carbon (measured by the degree of isotopic saturation)were for young leaves (including flower buds), 13.9 per cent;mature leaves, 15.7 per cent; stems+petioles, 5.9 per cent;roots, 5.4 per cent and nodules, 6.9 per cent, 48 h after theend of the ¹³CO₂ assimilation period, they were 12.3, 7.5, 7.4,6.8 and 6.1 per cent, respectively. The treatment with a highconcentration of nitrate in the nutrient media significantlydecreased the allocation of ¹³C into nodules. Experiments on¹³CO₂ assimilation by plants at the pod-filling stage were alsoconducted. Labelling by ¹³C was weaker than at the early floweringstage, but an intense accumulation of ¹³C into reproductiveorgans was observed. Glycine max L., nodulated soya bean plants, ¹³CO₂ assimilation, carbon dynamics     

The photosynthetic production of oxalic acid in Oxalis corniculata

The biogenesis of oxalic acid in Oxalis corniculata has beeninvestigated. In O. corniculata the bulk of the oxalic acidis produced by CO₂ fixation both in light and in darkness butthe rate of its photosynthetic formation is much higher thanin darkness. Several other plants some of which are known toaccumulate oxalic acid e.g., Biophytum sensitivum, Averrhoacarambola, Impatiens balsamina, Amorphophallus campanulatusand Colocassia antiquorum also fix ¹⁴CO₂ into oxalic acid photosyntheticallywithin 1 min of exposure to the gas. In O. corniculata ¹⁴C canbe detected in oxalic acid within 5 sec and about half of thetotal ¹⁴C fixed in the 70% ethanol soluble fraction can be locatedin this compound after 5 min. This is accompanied by a declineof radioactivity in two compounds, the chromatographic behaviourand melting points of one of which and its DNP hydrazone aresimilar to those of an authentic sample of glyoxylic acid. Whenglyoxylate 1, 2-¹⁴C is incubated with Oxalis leaf homogenateit is converted to oxalate-¹⁴C. Glycolate is also metabolizedto oxalate. The conversion of both glycolate and glyoxylateare favoured by light. The C₂ compounds acetate and glycinehowever are utilized rather poorly. Sucrose-¹⁴C is also notmetabolized markedly for this purpose. (Received August 20, 1969; )     

Synthesis of Citrulline and Arginine in Chlorella pyrenoidosa

The distribution of radioactivity in Chlorella during dark ¹⁴CO₂fixation was investigated either (a) in normal cells with andwithout added ammonium chloride, or (b) in nitrogen-starvedcells supplied with intermediates of the Krebs-Henseleit ureacycle. In the control experiments almost all the activity was presentin compounds of or associated with, the tricarboxylic acid cycle. The amino-acids citrulline and arginine became radioactive onlyin the presence of ammonia or ornithine where initially theycomprised 40–60 per cent. of the total activity, reactionsof the Krebs–Henseleit urea cycle being implicated intheir formation. No evidence could be found for a complete ureacycle. Unidentified compounds deriving their radioactivity fromthe C₄ carbon of citrulline and/or arginine were detected andformed up to 40 per cent. of the total ¹⁴CO₂ incorporated after25 min.     

Respiratory Mechanisms in the Aroid Spadix

The flowers of Skunk-cabbage (Symplocarpus foetidus), like thespadix tissues of other Aroids, have a rapid, carbon monoxideand cyanide (HCN) resistant respiration; oxygen uptake is independentof the oxygen partial pressure over a wide range. Cell fractionswere isolated by differential centrifugation and their oxidativeactivities studied. Oxidation of succinate and citrate by mitochondriacan be inhibited 50 to 60 per cent. by 1 X 10^–3 M. HCN,and antimycin A (AA) causes partial inhibitions. An active mitochondrialcytochrome-c oxidase is present, and it shows a typical sensitivityto cyanide. The mitochondria possess an active reduced diphosphopyridine-nucleotide(DPNH) oxidase system, which is inhibited roughly 80 per cent.by 1 X 10^–3 M. HCN and 1.7 µg./ml. AA. The microsomalDPNH oxidase, which is less sensitive to inhibitors, is lessactive per gramme of tissue than that on the mitochondria. Thefinal supernatant shows little DPNH oxidase. With all fractions,reduced triphosphopyridine nucleotide (TPNH) is oxidized muchmore slowly than DPNH. DPNH-cyto-chrome-c reductase activitywas measured; the mitochondrial system is partially blockedby AA, whereas the microsomal activity is AA-insensitive. Spectro-photometricexamination of a preparation of solubilized mitochondria showedthat cytochromes a, b, and c are present. The results are discussedwith reference to the pathway and localization of hydrogen andelectron transport in the Aroid spadix.     

Transients in the Photosynthetic Carbon Reduction Cycle Produced by Iodoacetic Acid and Ammonium Chloride

Changes in ¹⁴C content of metabolites in photosynthesising Chlorellahave been investigated following the addition of iodoaceticacid or ammonium chloride. The ¹⁴C content of phosphoglyericacid increases in the former and decreases in the latter case.Both reagents divert ¹⁴C from sucrose and polysaccharide intocompounds of and associated with the tricarboxylic acid cycle.The principal site of iodoacetic acid inhibition is triose phosphatedehydrogenase whereas ammonium chloride stimulates the conversionof phosphoglyceric acid to phosphoenolpyruvate and pyruciv acid.The latter suggests a direct effect of the ammonium ion on phosphoglyceromutase,enolase, or pyruvic kinase in vivo. Changes in the concentrationof alanine, aspartic acid, glutamic acid, serine, and glutamineupon addition of the ammonium ion are not well correlated withtheir ¹⁴C labelling patterns.     

The Oxidation of 14C-labelled Glucose by Chlorella vulgaris: 1. The Time Course of 14CO2 Production

Glucose, either uniformly labelled with¹⁴C, or specificallylabelled in the I, 2, or 6 position, was added to C. vulgaris.Radio-active carbon dioxide was produced initially ten timesfaster from glucose-I-¹⁴C than from glucose-6-¹⁴C. This differencewas found with carbohydrate-starved cultures, exponentiallygrowing cultures, and cultures assimilating ammonia or nitraterapidly. A similar difference was also found with C. pyrenoidosaand Ankistrodesmus. 37 per cent. of the ¹⁴C added as glucose-¹-¹⁴Cto exponentially growing cells was recovered as carbon dioxidebut generally the recovery was less than this. Only 5 per cent.of ¹⁴C added as glucose-6-¹⁴C was recovered as carbon dioxide.The specific activity of the carbon dioxide produced was considerablylower than that of the carbon in the added glucose.     

Studies of pesticide effects on Chlorella metabolism I. Effect of herbicides on complex lipid biosynthesis

Various herbicides were tested for possible effects on biosynthesisof complex lipids in Chlorella using ¹⁴C-U-acetate as a precursor.Among the herbicides tested, Hill reaction inhibitors causedinhibition of ¹⁴C-incorporation by 60 to 80 per cent at a concentrationof 5 mg/liter, and noticeable alteration in the labeling patternof glyco- and phospholipids. Proportions of mono- and digalactolipidsmarkedly decreased while those of phosphatidyl ethanolamineand phosphatidyl glycerol increased. In terms of net synthesis,phosphatidyl ethanolamine was affected, if at all, only slightlyby Hill reaction inhibitors, while the other complex lipidsdecreased to various degrees. (Received February 9, 1973; )     

The Effect of Isonicotinyl Hydrazide on the Photosynthetic Incorporation of Radioactive Carbon Dioxide into Ethanol-Soluble Compounds of Chlorella

The effect of 10^-2M. isonicotinyl hydrazide (isoniazid) on theincorporation of radioactive carbon dioxide by Chlorella duringphotosynthesis has been studied under steady-state conditionsat two carbon dioxide concentrations. Isoniazid treatment resultsin increased radioactivity in sucrose, glycollic acid, and glycineand decreased radioactivity in sugar monophosphates, serine,and alanine. An unidentified compound which is strongly radioactiveafter short-term exposures to ¹⁴CO₂ is present in isoniazid-treatedcells. It is suggested that isoniazid pre-dominantly inhibitsthe conversion of glycine to serine.     

The Incorporation of 14CO2 into Green Peas in the Dark

Shelled green peas (ripening seeds of Pisum sativum var. Onward)were kept in the dark for 2 or 3 days in an atmosphere, eitherof air or 10 per cent carbon dioxide in air, containing ¹⁴CO₂.Samples were removed at intervals, the acids of the T.C.A.C.extracted, estimated, and their content of ¹⁴C measured. Incorporationof ¹⁴C was mainly into the carboxyl carbon atoms of the acidswhich, with the exception of citrate, rose in specific activityrapidly for the first 4–6 h and then levelled off androse slowly for the rest of the experiment. The final valuesattained, again with the exception of C-6 of citrate, were muchbelow that of the tissue carbon dioxide. The cause of this failureto equilibrate with tissue carbon dioxide is discussed. Twomain carboxylation reactions are proposed, one from pyruvate(or other three carbon acid) to malate and the other from -oxoglutarateto oxalsuccinate and so to C-6 of citrate. The value of thevelocity constant of the first of these reactions was shownto be markedly decreased by increase in tissue carbon dioxidewhile that for the second carboxylation was unaffected. ¹⁴Cmoved into soluble amino-acids rapidly at first and then moreslowly; protein received ¹⁴C at a high rate throughout the experimentsmainly by isotopic exchange reactions. Calculations were madeof the rate of movement of carbon in the T.C.A.C. which wouldhave been required to give the observed changes in specificactivity of the metabolites but no scheme tested fitted allthe results satisfactorily.     

Auxin-promoted Transport of Metabolites in Stems of Phaseolus vulgaris L.: SOME CHARACTERISTICS OF THE EXPERIMENTAL TRANSPORT SYSTEMS

Indol-3yl-acetic acid (IAA) applied to sterns of Phaseolus vulgarisseedlings, decapitated above primary leaves, enhanced the mobilizationof ¹⁴C-metabolites to the treated stumps and this effect wasapparent within 3–6 h of applying the hormone. More than90 per cent of the total ¹⁴C-activity transported to the stumpswas detected in the alcohol-soluble extracts. In all treatments,less than 5 per cent of the ¹⁴C-photosynthate exported fromthe primary leaves was translocated upwards. Accumulation of¹⁴C-activity was also increased when the IAA was applied laterallyto intact internodes. This effect was obtained when ¹⁴C wassupplied either above or below the point of hormone application.By selective heat girdling, it was shown that the auxin affected¹⁴C transport when either the root ‘sink’ was removedor transpiratory flow of water through the treated internodewas maintained. Decapitated stems treated with plain lanolinfor 3 d were found to retain their responsiveness to auxin interms of enhanced metabolite transport. Heat-girdling experimentsand estimates of ¹⁴C transport velocity suggested that mostof the ¹⁴C movement was restricted to the phloem of treatedstumps. Similar effects of IAA on a transport in excised stemsegments of Phaseolus vulgaris were observed.     

METABOLIC COMPARTMENTATION IN THE BRAIN: METABOLISM OF A TRICARBOXYLIC ACID CYCLE INTERMEDIATE, [1,4-14C] SUCCINATE, AFTER INTRACEREBRAL ADMINISTRATION

Abstract— The metabolism of a tricarboxylic acid cycle (cycle) intermediate, [1.4-'¹⁴C]succinate, was studied in the brain at 2 20 min after intracerebral injection. The oxidation of [¹⁴C]succinate was rapid, as shown by the incorporation of ¹⁴C into cycle amino acids which accounted for about 30 per cent and 70 per cent of the tissue -“Cat 2 and 10 min respectively. During the whole experimental period the specific radioactivity of glutamine was about three times higher than that of glutamate. Thus exogenous [¹⁴C]succinate elicited signs of metabolic compartmentation similar to those seen after the administration of short chain fatty acids or amino acids. A computer programme, based on data obtained previously on the metabolic compartmentation of acetate and of glucose in the brain, was used to simulate the kinetics of labelling of cycle amino acids after an input of [1.4-¹⁴C]succinate. The correspondence of the simulated data with the experimental results was good in the first 10 min after injection, although the deviations were significant at later time points. Incorporation of ¹⁴C into GABA was very low (< 1 per cent of the amino acid -¹⁴C) after the injection of [1.4-¹⁴C]succinate. Further, labelled GABA formation was not detected in the decapitated rat brain labelled in vivo with [1.4-¹⁴C]succinate 2 min beforehand. Since the oxidation of [l,4-¹⁴C]succinate via the cycle yields unlabellcd GABA. whereas the reversal of the reactions in the GABA bypath may introduce ¹⁴C from succinate into the GABA pool, the results indicate that this reversal is negligible even under the most favourable conditions, i.e. post mortem when both the NADH/NAD⁺ ratios and [¹⁴C]succinate concentrations arc high. The observations are therefore consistent with the view that glutamate is the predominant and probably the only source of GABA carbon in the brain both in vivo and post mortem.     

Assimilation of 14CO2 by the Inflorescence of Poa annua L. and Lolium perenne L.

The relative assimilatory activity of the inflorescence, itsindividual components, and the leaves of flowering tillers ofPoa annua L. and Lolium perenneL. was determined over the periodfrom inflorescence emergence to seed shedding. The pattern of¹⁴CO₂ fixation was similar for both species and the inflorescencewas by far the most important assimilatory organ of the reproductivetiller, particularly over the latter period of seed developmentas leaf senescence progressed. With the exception of the seedsall parts of the inflorescence showed significant assimilatoryactivity and the lemmas and paleas accounted for 40–50per cent of the total ¹⁴C fixed by the inflorescence in bothspecies. The importance of the grass inflorescence as a photosyntheticstructure is discussed in relation to similar studies on cereals. Poa annua, Lolium perenne, carbon dioxide assimilation, inflorescence     

The Oxidation of 14C-labelled Glucose by Chlorella vulgaris: 2. The Fate of Radioactive Carbon

Most of the ¹⁴C added as glucose to carbohydrate-starved cellsof Chlorella Vulgaris can be recovered as alcohol-soluble compoundsor as polysaccharide. Only 5–I6 per cent., depending onthe position of ¹⁴C in the glucose supplied, is released ascarbon dioxide. Similar results were obtained with Chlorellapyrenoidosa and Ankistrodesmus. The labelled alcohol-solublecompounds in Chlorella vulgaris include amino-acids, particularlyglutamic acid, aspartic acid, and alanine, and, when glucose-I-¹⁴Cis metabolized, the amount of ¹⁴C recovered in these amino-acidsis about the same as that recovered as carbon dioxide. Degradationof the glucose incorporated into polysaccharide shown that theC₁ and C₆ atoms of glucose rapidly interchange when in the cells.The bearing of these results on attempts to estimate the relativeimportance of different pathways of glucose breakdown is discussed.     

Post-transcriptional Control of Nitrate Reductase Formation in Green Algae

Cycloheximide (2·0 µg ml^–1) inhibits theincorporation of [¹⁴C]phenylalanine and [¹⁴C]adenine into insolublecompounds in Ankistrodesmus braunii. 6-Methylpurine (1·0mM) inhibits only the incorporation of [14C]adenine and it isconcluded that it inhibits RNA synthesis. When ammonium-growncells of Ankistrodesmus or Chlorella are nitrogen-starved orwhen ammonium-grown cells of Dunalitlla are resuspended in nitratemedium, the appearance of nitrate reductase in these organismsis not inhibited by 6-methylpurine. The appearance of nitratereductase activity in Ankistrodesmus or Chlorella is inhibitedby 6-methylpurine when ammonium-grown organisms are preincubatedwith this substance for 1-2 h before nitrogen starvation. Itis concluded that cells growing with ammonium and lacking nitratereductase activity nevertheless contain preformed mRNA for nitratereductase synthesis.     

Metabolism of Pyrimidines in Protoplasts from Cultured Catharanthus roseus Cells

The metabolism of [2-¹⁴C]thymine, [2-¹⁴C]thymidine, [2-¹⁴C]uraciland [¹⁴C]uridine was investigated in protoplasts obtained fromsuspension cultures of Catharanthus roseus. Most of the exogenouslysupplied thymine, thymidine and uracil was degraded, and salvageof these pyrimidines accounted for 5–36 per cent of thetotal amount of ¹⁴C-labelled precursors which was metabolized.However, more than 80 per cent of the labelled uridine was utilizedfor the biosynthesis of nucleotides and nucleic acids, and therest was degraded. In contrast to the results from protoplastsof sugar cane cells in suspension culture, the data indicatethat protoplasts possess a pathway for the degradation of pyrimidines,and that the overall metabolism of these pyrimidines in protoplastsis very similar to the metabolism in the intact cells. Catharanthus roseus, madagascar periwinkle, protoplasts, pyrimidine metabolism