Further Studies on the Acid Metabolism of Aspergillus niger: THE FORMATION AND UTILIZATION OF OXALIC ACID

1. Some recent works on the formation of oxalic acid by variousfungi are critically considered.
2. The present work deals withthe role of oxalic acid in the metabolismof Aspergillus niger.
3. When glucose solutions were supplied to preformed mats ofthefungus oxalic acid accumulated, attaining an equilibriumlevelwhich was not exceeded despite the presence of a considerableconcentration of glucose.
4. When the glucose supplies were depletedthe oxalic acid concentrationfell steeply to a low level.
5. Theconcentration of oxalic acid was dependent on the glucoseconcentration.In three separate series of experiments it wasshown that theoxalic acid concentration diminished with increasingglucoseconcentration.
6. Similar results were obtained when the cultureswere rearedfrom spores on culture solutions with the normalamounts ofnutrient salts but different glucose concentrations.
7. In all cases the CO₂ output increased with the glucose concentration.
8. When cultures were supplied with glucose+oxalic acid, theconcentrationof the latter fell steeply to the equilibriumlevel attainedon glucose only. In a culture receiving glucose+oxalicacid,with the oxalic acid concentration somewhat below thenormalequilibrium concentration, the formation of oxalic acidfromthe glucose ceased as soon as the equilibrium level hadbeenattained.
9. When 1 per cent. oxalic acid only was suppliedto the fungusthe concentration gradually diminished to a lowlevel. When3 per cent. oxalic acid was supplied the rate ofacid utilizationsoon fell to low value.
10. In several experimentsit was shown that the rate of CO₂ outputwas higher from culturessupplied with glucose+excess oxalicacid than from culturessupplied with glucose only.
11. The rate of oxalic acid carbonloss was always below that ofthe CO₂ carbon output both incultures supplied with oxalicacid only and in cultures receivingglucose+oxalic acid.
12. The cultures were incapable of utilizingneutral sodium oxalateand the presence of this substance hadno effecft on the ofCO₂ output.
13. The results indicate thatthe utilization of oxalic acid isassociated with the liberationof at least an equivalent amountof CO₂.
14. It is suggested thatthe utilization of oxalic acid is promotedby the presence ofglucose, thus accounting for the lower oxalicacid concentrationsand higher rates of CO₂ output of cultureswith higher glucoseconcentrations.

     

Metabolism of Slices of the Tomato Stem

The rate of respiration of tomato stem slices varied considerably,the highest values (Qo₂, 2–3) being obtained for plantsin a good nutritional state, and the lowest (Qo₂, 1) in starvedplants. The respiratory quotient of 1.0 remained constant. Glucose fermentation was found to follow both glycolytic andalcohol fermentation pathways, the ratio of ethyl alcohol: lacticacid being 6.6:1. Fermentation seems to take place accordingto the Embden-Meyerhof scheme, as shown by the presence of someof these enzymes operative in this scheme and by inhibitionexperiments. In the presence of oxygen there was no formationof alcohol or lactic acid. Pyruvate added to tomato stem slices was metabolized by directoxidation to acetic acid and by dismutation to lactic and aceticacids and CO₂ The metabolism of acetic acid was demonstratedby its condensation with oxaloacetic acid to form citrate, thisbeing the second time that synthesis of citric acid by thismechanism has been found in plants. The presence of aconitase,of isocitric dehydrogenase, of succinic dehydrogenase, and ofmalic dehydrogenase, as well as the inhibition of respirationby malonic acid, favour the hypothesis that oxidation of carbohydratein tomato stem slices proceeds via the citric acid cycle. Thepossibility of an auxiliary route, the malic acid oxidationpathway, also was demonstrated. Tomato stem tissue anaerobicallysplit malic acid into glycolic acid. The further oxidation ofglycolic, glyoxylic, and formic acid was demonstrated. In experiments with C¹⁴-labelled acetate and butyrate a dilutionof the C¹⁴-labelled acids was found after incubation indicatingnew formation of these acids and of active participation offatty acid metabolism in the metabolic activities of the tissue. With the exception of alanine, added amino acids produced adefinite increase in O₂ uptake without extra formation of ammonia. Experimental demonstration of the possibility of electron transportfrom substrate to molecular oxygen in respiration via polyphenoloridase was provided by the attainment in a tomato tissue homogenateof a coupled oxidation-reduction between -ketoglutarate andcatechol with DPN and tyrosinase as the catalysts. The presenceof cytochrome oxidase was also demonstrated. Thus both systemspossibly may take part in the respiration of tomato stem slices.     

STUDIES ON THE METABOLISM OF A SULFUR-OXIDIZING BACTERIUM II. THE SYSTEM OF CO2-FIXATION IN THIOBAC1LLUS THIOOXIDANS

1. In the early stage of CO₂-fixation by Thiobacillus thiooxidans,which was incubated aerobically in the presence of sulfur, mostpart of the fixed carbon was found in the phosphate ester fraction.
2. The fixation was inhibited by NaF, picolinic acid, PCMB, azide,dipyridyl, o-phenanthroline, monoiodoacetic acid, and arsenite,each in the concentration range where the sulfur oxidation wasnot affected strongly.
3. The crude extract of this organismcould fix CO₂ in the presenceof ATP, R-5-P and Mg⁺⁺. Most partof the fixed carbon was foundin PGA.
4. The crude extract showedthe CO₂-fixation coupled with the H₂S-oxidationin the presenceof ADP.
5. An appreciable reduction of PGA could not be detectedin thepresence of reducing systems, involving TPNH and DPNH.

(Received March 6, 1962; )     

STUDIES ON THE PATHWAY OF SULFIDE PRODUCTION IN A COPPER-ADAPTED YEAST

Metabolism of some sulfur-containing substances was studiedin a copper-resistant strain of yeast (R), its parent strain(P) and respiratory-deficient(RD) mutants from them. The resultsobtained are as follows:

1. Using sulfate, sulfite and thiosulfate as sulfur sources, Rproducedmore H₂S than P, and both of these had the activityhigher than their RD mutants. All of them produced a large amountof H₂S from cysteine, but only little from methionine, cysteinesulfinic acid and S-sulfocysteine.
2. From sulfite and thiosulfate,P and R produced more H₂S inaerobicthan in anaerobic condition.With sulfate and cysteine, however,H₂S production did not differunder those conditions.
3. In both P and R, the sulfate-to-sulfiteand sulfite-to-sulfidereactions were remarkably lowered byiron and zinc deficiencies.But the cysteine-to-sulfide reactionwas not affected by themetal-deficiencies.
4. H₂S productionfrom sulfate was remarkably depressed by highconcentrationsof pantothenate.
5. Rates of reaction steps on a plausible pathway from sulfatetosulfide and to organic sulfur compounds areestimated forthe strainsused. R is characterized by its largecapacity ofthe reaction step from sulfate to sulfite, and excessivesulfitethus formed is liberatedas sulfide not by the way ofcysteine.

¹Present address: Research Reactor Institute, Kyoto University,Kumatori-cho, Sennan-gun, Osaka     

CHANGES IN LEVELS OF PYRIDINE NUCLEOTIDES IN CHLORELLA CELLS DURING THE COURSE OF PHOTOSYNTHESIS

1. Using intact cells of Chlorella, the effects of CO₂ on thelevelsof oxidized and reduced forms of DPN and TPN in the lightandin the dark were investigated.
2. It was found that the light-inducedchanges of the DPNH-levelwere not affected by the presenceor absence of CO₂. On theother hand, the light-induced increaseof TPNH was suppressedin the presence of CO₂ and the levelof TPNH which was raisedon illumination in the absence of CO₂was lowered by the provisionof CO₂.
3. On the basis of thesefindings, it was concluded that TPNH,but not DPNH, is participating,in some way, in the mechanismof photosynthesis.
4. Discussionswere made on the difference in the sites of participationofTPNH and of the photogenic reducing agent (R) in the pathofcarbon in photosynthesis.

(Received February 28, 1960; )     

Carbon Dioxide Fixation by Barley Roots

The non-volatile, 80 per cent.ethanol-soluble products of fixationhave been investigated in excised roots, using C^14O₂ and radiochromatography. The main radioactive compounds separated were malic, citric(or iso-citric), aspartic, and glutamic acids, asparagine andglutamine. Less activity was present in serine, tyrosine, -ketoglutaricacid, and alanine, and in a number of unidentified compounds. The uptake of C^14O₂ was inhibited by virtually anaerobic conditions. From the above observations it is considered likely that C¹⁴is transformed through the reactions of the tricarboxylic acidcycle. C¹⁴ in the soluble fraction was markedly increased by maintainingthe root material in water rather than in a nutrient solutionprior to exposure to C^14O₂ This increase was chiefly in malicacid.     

STUDIES ON THE METABOLISM OF A SULFUR-OXIDIZING BACTERIUM III. POSTOXIDATIVE FIXATION OF CARBON DIOXIDE

1. The cells of Thiobacillus thiooxidans, which had been in contactwith sulfur or sulfide in air (or CO₂-free air), could fix addedCOa very rapidly after replacing air with nitrogen. This fixationis designated as the postoxidative fixation.
2. "Preoxidation"of the sulfur compounds is mandatory for theoccurrence of thepostoxidative fixation.
3. The cells which had preliminarilyoxidized sulfide could notshow the CO₂-fixation, when theywere placed under an anaerobiccondition in the absence of thesulfur compound.
4. These results indicate that sulfur compoundsmay have an importantrole as the electron donor for the reductionof CO₂, besidestheir role as the substrate of respiration tosecure energyfor the fixation of CO₂

(Received March 6, 1962; )     

Oxygen enhancement of photosynthesis in Anacystis nidulans cells1

Oxygen enhanced photosynthetic ¹⁴CO₂ fixation in Anacystis nidulanscells. Results obtained under different conditions revealedthe following properties of the oxygen enhancement:

1. The enhancement was most significant at ca. 10% O₂. Furtherincrease in oxygen concentration decreased the enhancing effect.The rate under 100% O₂ was equivalent to or a little higherthan that under N₂ gas.
2. b) With the increase in CO₂ concentration,the magnitude ofthe enhancing effect decreased. No oxygen enhancementwas observedwhen the CO₂ concentration. was raised to 9,000ppm.
3. c) The enhancement was observed only at high light intensities.No enhancement was observed when the rate of photosynthesiswas limited by light intensity.
4. Ribulose 1,5-diphosphate (RuDP)carboxylase activity was demonstratedin the extract obtainedfrom A. nidulans cells. We also foundthat the RuDP carboxylaseactivity in this extract was competitivelyinhibited by oxygen.
5. Based on the above-mentioned results, the possible mechanismunderlying the observed enhancing effect of oxygen was discussed.

(Received May 10, 1976; )     

ORGANIC ACID SYNTHESIS IN RESPONSE TO EXCESS CATION ABSORPTION IN VACUOLATE AND NON-VACUOLATE SECTIONS OF CORN AND BARLEY ROOTS

1. ¹⁴CO₂ fixation into organic acids in tips and proximal sectionsof both corn and barley roots was studied as a function of thenature and concentration of the salt in the external solution.
2. In comparison with the level of ¹⁴CO₂ fixation by vacuolateproximal sections in KCI, incorporation was markedly enhancedin K₂SO₄ and diminished in CaCk. By contrast, non-vacuolateroot tips were indifferent to the type of external salt withrespect to UCO₂ incorporation into organic acids.
3. The effectof salt type on organic acid formation from ¹⁴CO₂was most pronouncedat relatively high concentrations.
4. The conclusion was reachedthat organic acid synthesis in responsetoexcess cation uptakeis the result of cation movement into thevacuole, and thattransport into the vacuole is mediated bythe low-affinity componentof the dual mechanisms involved inion absorption.

¹Present address: Government Forst Experiment Station, Meguro,Tokyo.     

The Organic Acid Metabolism of Bramley's Seedling Apple Peel1

1. The effect of various Krebs cycle acids on the respirationofdisks of apple peel at various stages of maturity was measuredin a Warburg respirometer.
2. Peel tissue from apples at thepre-climacteric and early post-climactericstages apparentlycontain sufficient of the Krebs cycle acidsused, with the exceptionof succinate, to maintain oxidativeprocesses at a maximum.
3. The addition of malate causes a large increase in the CO₂-outputof peel from post-climacteric and senescent fruit but not frompre-climacteric fruit, and a close correlation exists betweenthe climacteric and this decarboxylation of malate. The decarboxylationof malate does not affect the rate of O₂-uptake of peel tissue.The possible part played by the decarboxylation of malate inthe increased CO₂-output at the climacteric is discussed.
4. Addedpyruvate is decarboxylated by the tissue at all stagesof storagelife.
5. The decarboxylation of added malate is an aerobic fermentation,resulting in the quantitative production of acetaldehyde. Althoughthe presence of oxygen is necessary, the rate of O₂-uptake isnot affected by the reaction. Pyruvate decar boxylation doesnot require the presence of oxygen.
6. The O₂-uptake of peelfrom senescent apples can be stimulatedby addition of malate,succinate, and a-ketoglutarate. No evidencewas obtained, however,of oxidation of fumarate, citrate, orpyruvate. The additionof malate to senescent tissue restoresthe lower endogenousrate of O₂-uptake to that of early postclimacteric tissue.
7. Succinate and fumarate are toxic to peel tissue at concentrationabove 0.02M.

     

Coupling of malate decarboxylation to CO2 fixation and the reduction of 3-phosphoglyceric acid in corn bundle sheath cells,2

1. In the presence of NADP⁺ and Mg⁺⁺, the bundle sheath strandsisolated from corn (Zea mays) leaves by cellulase treatmentsdecarboxylated malate in the light at an initial rate (200 µmoles/mgchl.hr), which was sufficient to account for photosyntheticCO₂ fixation in intact leaves. This rate gradually slowed downand then stopped. The final level of the malate decarboxylatedwas approximately equal to the amount of NADP⁺ added.
2. Rapidand continued decarboxylation of malate was observed whenNADP⁺,3-phosphoglyceric acid and ATP (and Mg⁺⁺) were addedtogether.The addition of ADP instead of ATP showed a similareffect.Light did not show any effect on the malate decarboxylationin the presence of ATP or ADP.
3. When malate was added to thebundle sheath strands in the presenceof exogenous NADP⁺ NADP⁺was rapidly reduced. The reductionstopped after 2 min when,73% of the added NADP⁺ was reduced.The further addition of3-phosphoglyceric acid and ATP broughtabout a decrease in theNADPH-level, which rose again to attaina new steady level.
4. The transfer of radioactivity from (1-¹⁴C-3-phosphoglycericacid to dihydroxyacetone phosphate in the bundle sheath strandsin the presence of ATP and NADP⁺ was greatly enhanced by theaddition of malate.
5. In the presence of ribose 5-phosphateand ATP, the rate of ¹⁴C-transferfrom (4-¹⁴C)-malate to theintermediates of the reductive pentosephosphate cycle was equalto that of ¹⁴CO₂ fixation in the light.

All these results support the current view that in the bundlesheath cells of C₄ plants belonging to the NADP-malic enzyme-group,the decarboxylation of malate is coupled to the fixation ofthe released CO₂ and the reduction of 3-phosphoglyceric acidformed as a result of CO₂ fixation. ¹ Part of this research was reported at the 40th Annual Meetingof the Botanical Society of Japan Osaka, December, 1975. ³ Present address: Laboratory of Chemistry, Faculty of Medicine,Teikyo University, 359 Otsuka, Hachioji-City, Tokyo 173, Japan. (Received April 30, 1977; )     

Diurnal Rhythm and Characteristics of Photosynthesis and Respiration in the Leaf and Root of a Phalaenopsis Plant

A hybrid Phalaenopsis plant was grown hydroponically on a nutrientsolution of Hyponex in the greenhouse. Typical daily patternsof CO₂ fixation, production of malic acid and citric acid andpH of the leaf and root were determined. The rate of primaryfixation of CO₂ in the leaf increased markedly in the evening,remained high until well into the afternoon, then decreasedsharply. The pattern of production of organic acids resultedfrom the fact that the rate of uptake of CO₂ gas was highestat night and fell during the day. A high correlation betweenpH value and level of malic acid in the leaves was observed,and an exponential relationship appeared to exist between theseparameters. These rhythmic sequences were not observed in theroot. The results suggest that metabolism in the leaf had characteristicsof CAM (Crassulacean Acid Metabolism), while the root did not. (Received May 6, 1988; Accepted October 25, 1988)     

LIGHT-INDUCED REDUCTION OF NITRATE, NITRITE AND HYDROXYLAMINE IN A BLUE-GREEN ALGA, ANABAENA CYLINDRICA

1. Reduction of nitrate, nitrite and hydroxylamine by intact cellsof Anabaena cylindrica was investigated with special referenceto the stimulating effect of light on these processes.
2. Itwas found that in light and under anaerobic condition thesecompounds are reduced to ammonia, with the production of extraoxygen. The stoichiometry of the reactions under these conditionscan be represented as follows: HNO₂+H₂O=NH₂+2O₂ HNO₂+H₂O=NH₂+1O₂ NH₂OH+H₂O=NH₂+O₂+H₂O
3. Reduction of nitrite and hydroxylaminewas markedly suppressedby CMU in the light but not in the dark.KCN inhibited reductionto the same extent both in the lightand in the dark. Reductionin the light was much less sensitiveto the uncoupling agent,DNP, than was that in the dark.
4. Atlow light intensities, CO_2– was suppressed by 20–30per cent by the simultaneous provision of nitrite, but the nitritereduction was not affected at all by CO₂. At high light intensities,reduction of nitrate and nitrite was considerably acceleratedby CO₂
5. On the basis of these findings, a possible mechanismfor thelight stimulation of the reactions in question was brieflydiscussed.

(Received August 22, 1962; )     

The Effect of Temperature and Light on Gas Exchange and Acid Accumulation in the C3-CAM Plant Clusia minor L

Gas exchange and organic acid accumulation of the C₃-CAM intermediateClusia minor L. were investigated in response to various day/nighttemperatures and two light regimes (low and high PAR). For bothlight levels equal day/night temperatures between 20°C and30°C caused a typical C₃ gas exchange pattern with all CO₂uptake occurring during daylight hours. A day/ night temperatureof 15°C caused a negative CO₂ balance over a 24 h periodfor low-PAR-grown plants while high-PAR-grown plants showeda CAM gas exchange pattern with most CO₂ uptake taking placeduring the dark period. However, there was always a considerablenight-time accumulation of malic acid which increased when thenight-time temperature was lowered and had its maximum (54 mmolm^–2) at day/night temperature of 30/15°C. A significantamount of malic acid accumulation (23 mmol m^–2) in low-PAR-grownplants was observed only at 30/15°C. Recycling of respiratoryCO₂ in terms of malic acid accumulation reached between 2·0and 21·5 mmol m_–2 for high-PAR-grown plants whilethere was no significant recycling for low-PAR-grown plants.Both low and high-PAR-grown plants showed considerable night-timeaccumulation of citric acid. Indeed under several temperatureregimes low-PAR-grown plants showed day/night changes in citricacid levels whereas malic acid levels remained approximatelyconstant or slightly decreased. It is hypothesized that lowand high-PAR-grown plants have different requirements for citrate.In high-PAR-grown plants, the breakdown of citrate preventsphotoinhibition by increasing internal CO₂ levels, whereas inlow-PAR-grown plants the night-time accumulation of citric acidmay function as an energy and carbon saving mechanism. Key words: C. minor, C₃, CAM, citric acid, light intensity     

EFFECT OF CHROMATIC LIGHTS ON PHYCOBILIN FORMATION IN A BLUE-GREEN ALGA, TOLYPOTHRIX TENUIS

1. The formation of phycobilin pigments in a blue-green alga Tolypothrixtenuis was investigated with special reference to the effectsof preillumination with colored lights.
2. It was discoveredthat the algal cells are capable of formingphycobilin pigmentsin the dark, if they have been previouslyilluminated for severalhours in the presence of CO₂.
3. The color of light applied inthe later period of preillumination(chromatic illumination)was found to affect the ratio of phycoerythrinto phycocyaninformed in the subsequent dark period. A greenlight acceleratesthe dark-formation of phycoerythrin, a redlight that of phycocyanin,and the two lights counteractingwith each other in their effects.
4. These directive effects of the "chromatic illumination" canbe accomplished within a very short period, for instance, in3 minutes if it is preceded by sufficient "preillumination"with an incandescent or day light fluorescent light. The reactionsoccurring during the period of chromatic illumination does notrequire the presence of CO₂ and the aerobic condition.
5. Thealga can be grown heterotrophically when supplied with casaminoacids and glucose. Under such a condition the alga forms phycocyanintogether with chlorophyll and carotenoids, but not phycoerythrin.
6. On the basis of the results obtained, a tentative scheme forthe biosynthesis of phycobilin pigments in the alga was proposed,assuming the light-induced formation of unknown precursors whichare converted into phycocyanin and phycoerythrin in the subsequentdark period.

(Received July 4, 1960; )     

STUDIES ON THE MECHANISM OF GROWTH INHIBITING EFFECT OF LIGHT

1. A substance which inhibits indoleacetic acid (IAA)-and naphthaleneaceticacid (NAA)-induced elongation of Avena coleoptile section andIAA-induced Avena coleoptile curvature was found in an ethersoluble neutral fraction of water extract of sunflower leavesand in agar blocks containing the diffusate from young sunflowerleaves.
2. This substance also inhibits the growth of isolatedsunflowerepicotyl.
3. The R_f value (0.9) of the substance ona paper chromatogramdeveloped with ammoniacal iso-propanolindicates that it isidentical with the inhibitor reported byAUDUS et al. (1956),but not with inhibitor-ß.
4. Theinhibitor can be transported from leaf to stem, and thetransportseems to be accelerated by illuminating the leaf.
5. The auxindiffused from sunflower leaf into agar block may beidenticalwith IAA.
6. A substance, which has the same properties as theinhibitorfrom sunflower leaf, was obtained in crystalline formfrom theleaf of Jerusalem artichoke.
7. The mechanism of growthinhibition caused by this crystallinesubstance seems to involveinactivation of a sulfhydryl group.
8. The reason why the stemgrowth of sunflower seedlings is reducedby strong light isdiscussed: the amount of the inhibitor transportedfrom leafto stem is increased under strong light, and in thestem, growthinhibition is caused by a direct effect of thisinhibitor ongrowth and by its inhibiting effect on the transportof IAAfrom leaf to stem.

¹ Present address: Botanical Garden, Faculty of Science, Universityof Tokyo, Tokyo (Received February 15, 1961; )     

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; )     

EFFECT OF SOME SULFHYDRYL REAGENTS ON LIGHT-INDUCED CO2-FIXATION IN CHLORELLA

1. Using intact cells of Chlorella ellipsoidea, investigationswere made on the effects of some SH-reagents (IAA, CMB and arsenite)upon various reactions pertaining to the primary photogenicagent (designated by R) formed in the mechanism of photosynthesis.
2. The pre-illumination experiments using ¹⁴CO₂ as a tracer haveled us to the inference that (i) the process of photochemicalformation of R is inhibited by IAA, that (ii) the spontaneousdecay of R in the dark is markedly accelerated by CMB and arsenite,but not at all affected by IAA, and that (iii) the participationof R in the cyclic path of carbon leading to the fixation ofCO₂ is not affected by IAA and CMB.
3. Based on the assumptionthat R is a reducing agent, it was discussedthat the fact mentionedunder (iii) is incompatible with theidea that the reductionof PGA to triose phosphate be the soleor rate-determining reductivestep in the cyclic path of carbonin photosynthesis.
4. The possibilitythat R may have a functional SH-group (s) wasinvoked to accountfor the observation that the decay of R inthe dark was markedlyaccelerated by CMB and arsenite.

(Received February 11, 1960; )     

PHOTOCHEMICAL INTERCONVERSION BETWEEN PRECURSORS OF PHYCOBILIN CHROMOPROTEIDS IN TOLYPOTHRIX TENUIS

1. The photochemical conversion between the precursors of phycocyaninand phycoerythrin in Tolypothrix tenuis was investigated.
2. Itwas found that the conversion of phycocyanin-precursor intophycoerythrin-precursor was induced by green light, and thereverse reaction by red light. These reactions proceeded exponentially, indicating that the photochemical process was acceleratedautocatalytically by the reaction-product.
3. The rates of thesephotochemical reactions were found to beunaltered by varyingthe incubation temperature (0? to 35?)and the composition ofthe gas atmosphere (presence or absenceof CO₂ and of O₂ orby an inhibitor of photosynthesis, p-chlorophenyldimethylurea.
4. The action spectra of the photochemical interconversions betweenprecursors of phycobilin chromoproteids were found to be distinctlydifferent from the absorption spectra of chlorophyll and carotenoids.The most effective wavelength for inducing the conversion ofphycocyanin- into phycoerythrin-precursor (541 mµ) isnear the absorption maximum of phycoerythrin (565 mµ),and that of the reverse reaction (641 mµ) is near theabsorption maximum of phycocyanin (620 mµ). Additionaldata, indicating that the phycobilin chromoproteids themselvesdo not participate in these processes as light absorber, werealso presented.
5. On the basis of these results, a possiblemechanism of the photochemicalinterconversion between the precursorsof phycobilin chromoproteidsis proposed.

(Received March 13, 1962; )     

The Regulation of Citric Acid Accumulation and Carbon Recycling During CAM in Ananas comosus

The carbon balance of shade-grown Ananas comosus was investigatedwith regard to nitrogen supply and responses to high PAR. Netdark CO₂ uptake was reduced from 61.2 to 38.5 mmol CO₂ m^–2in N limited (–N) plants grown under low PAR (60 µmolm^–2 s^–1) and apparent photon yield declined from0.066 to 0.034 (mol 0².mol^–1 photon), although photosyntheticcapacities (measured under 5% CO₂) were similar. Following transferfor 7 d to high PAR (600. µmol m^–2 s^–1), netCO² uptake at night increased by 14% in +N plants, and daytimephotosynthetic capacity was higher, with a maximum value of7.8 µmol m^–2 s^–1. The magnitude of dark CO₂ fixation during CAM was measured asdawn—dusk variations in leaf-sap titratable acidity (H+)and as the proportion of malic and citric acids. The contributionfrom re-fixation of respiratory CO₂ recycling (measured as thedifference between net CO₂ uptake and malic acid accumulation)varied with growth conditions, although it was generally lower(30%) than reported for other bromeliads. Assuming a stoichiometryof 2H+: malate and 3H+: citrate, there was a good agreementbetween titratable protons and enzymatically determined organicacids. The accumulation of citric acid was related to nitrogensupply and PAR regime, increasing from 7.0 mol m–3 (+Nplants) to 18 mol m^–3 (–N plants) when plants weretransferred to high PAR; malate: citrate ratios decreased from13.1 to 2.5 under these conditions. Under the low PAR regime, leaf-sap osmotic pressure increasedat night in proportion to malic acid accumulation. However,following the transfer to high PAR for 7 d, there was a muchgreater depletion of soluble sugars at night which correspondedto a decrease in leaf-sap osmotic pressure. Although a rolefor citric acid in CAM has not been properly defined, it appearsthat the accepted stoichiometry for CAM in terms of gas exchange,titratable acidity, malic acid and osmotic pressure may nothold for plants which accumulate citric acid. Key words: Ananas comosus, CAM, citric acid accumulation, carbon recycling