Effects of dark preincubation and chloramphenicol on blue light-induced CO2 incorporation in Chlorella cells

Chlorella cells incubated in the dark longer than 12 hr showedpronounced blue light-induced ¹⁴CO₂ fixation into aspartate,glutamate, malate and fumarate (blue light effect), whereasthose kept under continuous light showed only a slight bluelight effect, if any. 2) During dark incubation of Chlorellacells, phosphoenolpyruvate carboxylase activity and the capacityfor dark ¹⁴CO₂ fixation decreased significantly, whereas ribulose-1,5-diphosphatecarboxylase activity and the capacity for photosynthetic ¹⁴CO₂fixation (measured under illumination of white light at a highlight intensity) did not decrease. 3) In cells preincubatedin the dark, intracellular levels of phosphoenolpyruvate and3-phosphoglycerate determined during illumination with bluelight were practically equal to levels determined during illuminationwith red light. 4) The blue light effect was not observed incells incubated widi chloramphenicol, indicating that blue light-inducedprotein synthesis is involved in the mechanism of the effect. (Received April 9, 1971; )     

Effects of disalicylidenepropandiamine and near far-red light on 14CO2-fixation in Chlorella cells

1) With Chlorella ellipsoidea cells, in the presence of 5x10^–6M DSPD, or in its absence, the amounts of ¹⁴CO₂ incorporatedin P-esters, serine-plus-glycine and alanine were larger underred light than under blue light, whereas blue light specificallyincreased ¹⁴CO₂-incorporation in aspartate, glutamate, malateand fumarate (blue light effect). The amount of total ¹⁴C fixedunder blue or red light was greatly decreased by the additionof DSPD. When the concentration of DSPD was raised to 5x10^–4M, practically no radioactivity was found, under blue or redlight, in aspartate, glutamate and fumarate. Radioactivity inalanine was greatly increased. Effects of higher concentrationof DSPD are explained as due to the inhibition of PEP carboxylaseactivity in Chlorella cells. 2) The percentage incorporation of ¹⁴C into aspartate and theother compounds mentioned above, under near infra-red illuminationwas significantly smaller than that under blue light and wasalmost equal to that under red light. These results along withthe effect of 5x10^–6 M DSPD, exclude the possibility thatcyclic photophosphorylation is involved in the "blue light effect"mechanism. (Received December 12, 1969; )     

Comparison of carbon dioxide fixation and the fine structure in various assimilatory tissues of Amaranthus retroflexus L

The pattern for primary products of CO₂-fixation and the chloroplaststructure of Amaranthus retrqflexus L., a species which incorporatescarbon dioxide into C₄ dicarboxylic acids as the primary productof photosynthesis, were compared in various chlorophyll containingtissues,i.e., foliage leaves, stems, cotyledons and pale-greencallus induced from stem pith. Despite some morphological differencesin these assimilatory tissues, malate and aspartate were identifiedas the major compounds labelled during a 10 sec fixation of¹⁴CO₂ in all tissues. Whereas, aspartate was the major componentin C₄-dicarboxylic acids formed in foliage leaves, malate predominatedas the primary product in stems, cotyledons and the pale-greencallus. The percentage of ¹⁴C-radioactivity incorporated intoPGA and sugar-P esters increased and ¹⁴C-sucrose was detectedin the prolonged fixation of ¹⁴CO₂ in the light, not only infoliage leaves, but also in stems and cotyledons. ¹ This work was supported by a Grant for Scientific ResearchNo. 58813, from the Ministry of Education, Japan. ² Present address: Institute of Applied Microbiology, Universityof Tokyo, Tokyo, Japan. ³ Present address: Department of Biochemistry, University ofGeorgia, Athens 30601. Georgia, U. S. A. (Received July 10, 1971; )     

Green Light Drives CO2 Fixation Deep within Leaves

Maximal ^l4CO₂-fixation in spinach occurs in the middle of thepalisade mesophyll [Nishio et al. (1993) Plant Cell 5: 953],however, ninety percent of the blue and red light is attenuatedin the upper twenty percent of a spinach leaf [Cui et al. (1991)Plant Cell Environ. 14: 493]. In this report, we showed thatgreen light drives ¹⁴CO₂-fixation deep within spinach leavescompared to red and blue light. Blue light caused fixation mainlyin the palisade mesophyll of the leaf, whereas red light drovefixation slightly deeper into the leaf than did blue light.¹⁴CO₂-fixation measured under green light resulted in less fixationin the upper epidermal layer (guard cells) and upper most palisademesophyll compared to red and blue light, but led to more fixationdeeper in the leaf than that caused by either red or blue light.Saturating white, red, or green light resulted in similar maximal¹⁴CO₂-fixation rates, whereas under the highest irradiance ofblue light given, carbon fixation was not saturated, but itasymptotically approached the maximal ¹⁴CO₂-fixation rates attainedunder the other types of light. The importance of green lightin photosynthesis is discussed. ¹Supported in part by grants from Competitive Research GrantsOffice, U.S. Department of Agriculture (Nos. 91-37100-6672 and93-37100-8855).     

Photosynthetic metabolism of 14CO2 in the process of the "glucose-bleaching" of Chlorella protothecoides

Changes in photosynthetic carbon metabolism during the glucosebleaching of Chlorella protothecoides cells were investigatedusing NaH¹⁴CO₃ as tracer. Several hours after incubating thegreen algal cells in the glucose medium in the dark, the ratesof ¹⁴C-incorporation into glucose polymers and sucrose decreasedand the incorporation into the lipid fraction (fatty acids)greatly increased. At this stage, the rate of photosynthetic¹⁴CO₂ fixation and the chlorophyll content were practicallythe same as in the starting green cells. Afterwards, the photosyntheticcapacity and chlorophyll content continued to decrease throughoutthe experimental period. In contrast, when photosynthetic ¹⁴CO₂fixation of green cells was carried out in the medium containingglucose, the rate of ¹⁴C-incorporation into glucose polymersincreased, though there was no change in the incorporationsinto sucrose and the lipid fraction. ¹Part of this investigation was reported at the Conference "ComparativeBiochemistry and Biophysics of Photosynthesis" (Japan-U.S. CooperativeScience Program) held at Hakone, Japan in 1967. ²Present address: Faculty of Agriculture, Tamagawa University,Machida-shi, Tokyo, Japan. (Received June 10, 1974; )     

Regulation of CO2-fixation in Chlorella by light of varied wavelengths and intensities

1) The wavelength effects on ¹⁴CO₂-fixation by Chlorella cellswere studied, using monochromatic light of different light intensities. 2) Blue light (453 mµ) stimulated the incorporation of¹⁴C into aspartate, glutamate and malate. Red light (679 mµ),on the other hand, stimulated its incorporation into P-esters,free sugars and insoluble material. 3) The blue light effect was observed in the presence of CMUat concentrations completely suppressing ordinary photosyntheticCO₂-fixation. 4) The blue light effect in the presence of CMU was inducedat very low intensities. At 453 mµ, 300 erg cm^–2sec^–1 was sufficient for complete saturation. 5) Time courses of ¹⁴C-incorporation into individual compoundswere investigated. Irrespective of the wavelength of the illuminatinglight, the first stable CO₂-fixation product formed under weaklight (400–500 erg cm^–2 sec^–1) was citrulline.At higher light intensities (4,000–7,000 erg cm^–2sec^–1), PGA was the first stable CO₂-fixation product.The incorporation of ¹⁴C into citrulline was not inhibited byCMU. 6) Experimental results indicate that both blue light-inducedincorporation of ¹⁴C into amino and organic acids and the incorporationof ¹⁴C into citrulline induced by low intensity light are operatedby a mechanism(s) independent of ordinary photosynthetic CO₂-fixation.Possible effects of light regulating the carbon metabolism inalgal cells are discussed. (Received July 24, 1969; )     

Effects of Light Quality on Photosynthetic Carbon Metabolism in C4 and C3 Plants: Rapid Movements of Photosynthetic Intermediates Between Mesophyll and Bundle Sheath Cells

The influence of varying light intensity and quality on thecarbon labelling patterns in Rumex vesicarius (a C₃ plant),Setaria italica (a malate-formingC₄ plant), and Amaranthus paniculatus(an aspartate-forming C₄ plant) was studied. In A. paniculatusand B. vesicarius blue light decreased the transfer of radioactivityto sugars and starch but in S. italica only slightly decreasedradioactivity in sugar phosphates, sucrose, and insolubles.Negligible transfer was observed from the C₄ acids to sugarphosphates, sucrose, and starch under dim blue-green and blue-yellowlights in S. italica and A. paniculatus. Blue light favouredthe formation of malate, aspartate, and alanine in all threeplants. The differential effect of blue and red light suggesteda variation in the mechanisms of C₄-photosynthesis in Setariaand Amaranthus. Leaves of S. italica and A. paniculatus were allowed to photosynthesizein ¹⁴CO₂ for 5 s and then the distribution of the labelled productsbetween the mesophyll and the bundle sheath cells was determinedduring subsequent photosynthesis in ¹²CO₂. Malate and aspartatewhich appeared initially in the mesophyll layer moved rapidlyinto the bundle sheath cells. Phosphoglyceric acid originatingin the bundle sheath moved swiftly to the mesophyll layer. Sugarphosphates were recovered from both the mesophyll and the bundlesheath cells. Most of the starch was found in the bundle sheathcells while sucrose and alanine were localized in the mesophyllcells.     

Operation of the reductive pentose phosphate cycle daring the induction period of photosynthesis in Chlorella

When Chlorella oulgaris ll h cells grown in air containing 4%CO₂ (high-CO₂ cells) were given low concentrations of¹⁴CO₂ (<150ppm), the initial rate of photosynthetic ¹⁴CO₂ fixation wasvery low and linear ¹⁴CO₂ fixation was observed after an inductionperiod which lasted for ca. 45 min. No such induction period was observed when high-CO₂ cells weregiven high concentrations of ¹⁴CO₂ (10,000 ppm) or when IOW-CO₂cells were given either low or high concentrations of ¹⁴CO₂,supporting the observations by Briggs and Whittingham (l). However,irrespective of CO₂ concentrations during growth and of ¹⁴CO₂concentrations during the experiments, most of the ¹⁴C was incorporatedinto phosphate esters during the initial periods of photosynthetic¹⁴CO₂ fixation. These results are in sharp contrast to the reportby Graham and Whittingham (4). ¹ Requests for reprints should be addressed to S. Miyachi, RadioisotopeCentre, University of Tokyo, Bunkyo-ku, Tokyo 113, Japan. (Received June 30, 1979; )     

Photosynthetic and light-enhanced dark fixation of 14CO2 from the ambient atmosphere and 14C-bicarbonate infiltrated through vascular bundles in maize leaves

1. The capacity of light-enhanced dark fixation of ¹⁴CO₂ from theambient atmosphere decayed following time-course characteristicsof a first-order reaction (half-life, 1–2 min). The levelof phosphoenolpyruvate in maize leaves under CO₂-free air didnot decrease in the dark subsequent to preillumination. Theseresults indicate that phosphoenolpyruvate carboxylase is activatedin light and quickly inactivated in the following darkness.
2. Removal of oxygen from the atmosphere did not exert any effecton the products of light-enhanced dark fixation of ¹⁴CO₂ providedfrom the atmosphere, the major labeled compounds being malateand aspartate. This confirms that the transfer of carboxyl carbonof C₄-acids to form 3-phosphoglycerate is light-dependent.
3. WhenNaH¹⁴CO₃ solution was vacuum-infiltrated through vasculartissuesof maize leaves, the main initial photosynthetic ¹⁴CO₂fixationproducts were phosphate esters. This indicates thatby thistechnique, ¹⁴CO₂ could be directly provided to the bundlesheathcells, and was fixed via the reductive pentose phosphatecycle.On the other hand, the main initial ¹⁴CO₂-fixation productswere malate and aspartate even when ¹⁴CO₂ was provided throughvascular tissues in the dark immediately following preillumination.The possible regulatory mechanisms underlying the above findingsare discussed.

¹ This work was reported at the 4th International Congress onPhotosynthesis, Reading, September 1977. Request for reprintsshould be addressed to S. Miyachi, Institute of Applied Microbiology,University of Tokyo, Bunkyo-ku, Tokyo 113, Japan ² Present address: Okinawa Branch of Tropical Agriculture ResearchCenter, Ishigaki-shi, Okinawa 907, Japan. (Received October 28, 1977; )     

Glycine-serine transformation in the photosynthetic bacterium Chromatium vinosum

The metabolic transformation of glycine into serine in the photosyntheticbacterium Chromatium vinosum was accompanied by the evolutionof CO₂ due to decarboxylation of glycine. Isonicotinylhydrazideinhibited both ¹⁴CO₂ evolution and the formation of ¹⁴C-serinefrom ¹⁴C-glycine. The results indicate that a glycine-serinetransformation reaction takes place which is analogous to thatoccurring in green leaf tissues. Glycine may be metabolisedthrough serine by this reaction. The light stimulation of ¹⁴CO₂evolution and ¹⁴C-serine formation from 14C-glycine by the Chromatiumcells are judged to be results of the light-induced enhancementof ¹⁴C-glycine uptake by the bacterial cells. ¹This is paper 53 in the series "Structure and Function of ChloroplastProteins" and paper 7 of the series "Biosynthetic Mechanismof Glycolate in Chromatium". Paper 6 of the latter series isRef. 3 by Asami and Akazawa (1978). ²This study was aided by research grants from the Ministry ofEducation, Science and Culture of Japan and the Nissan ScienceFoundation (Tokyo). ³Postdoctoral Fellow (1980) of the Japan Society for the Promotionof Science. (Received May 20, 1980; )     

Role of carbonic anhydrase in photosynthetic CO2 fixation in Chlorella

Chlorella vulgaris 11h cells grown in air enriched with 4% CO₂(high-CO² cells) had carbonic anhydrase (CA) activity whichwas 20 to 90 times lower than that of algal cells grown in ordinaryair (containing 0.04% CO₂, low-CO₂ cells). The CO₂ concentrationduring growth did not affect either ribulose 1,5-bisphosphate(RuBP) carboxylase activity or its Km for CO₂. When high-CO₂ cells were transferred to low CO₂ conditions,CA activity increased without a lag period, and this increasewas accompanied by an increase in the rate of photosynthetic¹⁴CO₂ fixation under ¹⁴CO₂-limiting conditions. On the otherhand, CA activity as well as the rate of photosynthetic ¹⁴CO₂fixation at low ¹⁴CO₂ concentrations decreased when low-CO₂cells were transferred to high CO₂ conditions. Diamox, an inhibitor of CA, at 0.1 mM did not affect photosynthesisof low-CO₂ cells at high CO₂ concentration (0.5%). Diamox inhibitedphotosynthesis only under low CO₂ concentrations, and the lowerthe CO₂ concentration, the greater was the inhibition. Consequently,the CO₂ concentration at which the rate of photosynthesis attainedone-half its maximum rate (Km) greatly increased in the presenceof this inhibitor. When CO₂ concentration was higher than 1%, the photosyntheticrate in low-CO₂ cells decreased, while that in high-CO₂ cellsincreased. Fractionation of the low-CO₂ cells in non-aqueous medium bydensity showed that CA was fractionated in a manner similarto the distribution of chlorophyll and RuBP carboxylase. These observations indicate that CA enhances photosynthesisunder CO₂-limiting conditions, but inhibits it at CO₂ concentrationshigher than a certain level. The mechanism underlying the aboveregulatory functions of CA is discussed. ¹This work was reported at the International Symposium on PhotosyntheticCO₂-Assimilation and Photorespiration, Sofia, August, 1977 (18).Requests for reprints should be addressed to S. Miyachi, RadioisotopeCentre, University of Tokyo, Bunkyo-ku, Tokyo 113, Japan. (Received December 11, 1978; )     

Effects of Sodium on Photosynthesis in Panicum coloratum

Foliar application of NaCl to sodium-deficient Panicum coloratumstimulated photosynthesis, as did application via roots. Effectsof sodium on photosynthetic responses to internal concentrationsof CO₂ under different light intensities and initial productsof ¹⁴CO₂ fixation suggested that CO₂ fixation and aminationof oxalacetate were limited by sodium deficiency. ² Present address: Institute for Life Science Research, NihonNohyaku Co., Ltd., Kawachi-Nagano, Osaka, 586 Japan.     

A comparative study on the effect of O2 on photosynthetic carbon metabolism by Chlorobium thiosulfatophilum and Chromatium vinosum

The reductive carboxylic acid cycle appears to be the majorcarbon assimilation pathway in green sulfur bacteria, Chlorobiumthiosulfatophilum. While cyanide was relatively ineffectivein inhibiting the bacterial photosynthetic CO₂ fixation, photosynthesiswas strongly impaired in an O₂-containing atmospheric environment.No glycolate formation was detected in Chlorobium under an O₂atmosphere. In the purple sulfur bacteria, Chromatium vinosum,however, photosynthesis was highly sensitive to cyanide, andin a short-term incubation (up to 10 min) photosynthetic CO₂fixation was found to be relatively indifferent to an O₂-containingatmosphere of up to 100% O₂. Significant formation of glycolatewas demonstrated upon a very brief exposure to O₂, whereas thetotal photosynthetic CO₂ fixation was slightly affected. However,ribulose-1,5-bisphosphate carboxylase activity in Chromatiumextract was competitively inhibited by O₂ in a similar mannerto the higher plant enzyme, K¹(O₂) value being 0.7 mM at pH8.2. The percentage of incorporation of ¹⁴CO₂ into glycolateand glycine under an O₂-containing atmosphere declined withincreasing levels of bicarbonate concentrations in the medium.The Warburg effect and biosynthetic mechanisms involving glycolatein photosynthetic bacteria are discussed. ¹ This is paper XXXIX in the series "Structure and Functionof Chloroplast Proteins". Paper XXXVIII is reference (6) Asamiand Akazawa (1977). This research was supported in part by grantsfrom the Ministry of Education of Japan (111912), the TorayScience Foundation (Tokyo), and the Japan Securities ScholarshipFoundation (Tokyo). (Received January 28, 1977; )     

Glutamine synthesis in germinating castor bean endosperm

The pathway of glutamine synthesis in germinating castor beanendosperm was investigated by feeding experiments with (2,3-¹⁴C)succinateand by determining enzyme activities related to pyruvate formationand utilization. ¹⁴C of (2,3-¹⁴C)succinate was rapidly and sequentiallyincorporated into amino acids in the following order: aspartateor alanine, glutamate and glutamine. ¹⁴CO₂ was slowly released,especially during the early hours of incubation. Fluorocitrateinhibited ¹⁴CO₂ release while aminooxyacetate stimulated itslightly. Fluorocitrate inhibited the incorporation of ¹⁴C intoglutamate and glutamine. Aminooxyacetate inhibited ¹⁴C incorporationinto aspartate, alanine, glutamate and glutamine. Glutaminesynthetase activity was detected in a soluble fraction. NAD-malicenzyme activity was detected in mitochondria by sucrose densitygradient centrifugation. Activities of pyruvate decarboxylaseand aldehyde dehydrogenasewere detected. Aldehyde dehydrogenasewas partially purified about 60-fold by ammonium sulfate fractionationand the DEAE-cellulose chromatography. The Km values of theenzyme were 0.71 miu for NAD and 0.43 mM for acetaldehyde. Basedon these results and properties of pyruvate kinase reportedpreviously (9), the metabolism of pyruvate in cytosol and mitochondriawas discussed in connection with glutamine synthesis in germinatingcastor bean endosperm. (Received August 25, 1978; )     

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; )     

Role of carbonic anhydrase in photosynthesis in Chlorella derived from kinetic analysis of 14CO2 fixation1

Time courses of photosynthetic ¹⁴CO₂ fixation and its simulationare presented for Chlorella cells grown under low CO₂ concentration(low-CO₂ cells) and subsequently exposed to 0.2 mM NaH¹⁴CO₃or 130 ppm ¹⁴CO₂ in the presence or absence of carbonic anhydrase(CA) in the suspending medium. It was shown that Chlorella cells utilized only free CO₂ whenNaHCO₃ was given in the presence or absence of CA, or when CO₂was bubbled in the absence of CA. However, the present simulationindicated that both CO₃ and HCO₃^– were utilized when CO₂was given in the presence of CA. Based on these results, weconcluded that 1) Chlorella cells absorb only free CO₂ and 2)this gas is provided to algal cells in two ways, i.e., by directand indirect CO₂ supply. Usually, the dissolved CO₂ is directlyutilized by the algal cells (direct supply of CO₂). However,when the concentration of dissolved CO₂ is extremely low andwhen there is CA, CO₂ reconverted from HCO₃^– is also utilizedby Chlorella cells (indirect supply of CO₂). The utilizationof HCO₃^– indicated by the above simulation was explainedby the indirect supply of CO₂. We further assumed that the indirectsupply of CO₂ to ribulose 1,5-bisphosphate carboxylase occursmainly in the chloroplasts of low-CO₂ cells containing highCA. Thus, under low CO₂ concentrations, low-CO₂ cells can carryout more efficient CO₂ fixation than high-CO₂ cells, resultingin the lower apparent Km(CO₂). ³Department of Biology, Faculty of Science, Niigata University,Niigata, Japan. (Received April 2, 1980; )     

Suppressive effect of light on the formation of DNA and on the increase of deoxythymidine monophosphate kinase activity in Chlorella protothecoides

As previously demonstrated, chlorophyll-less cells of Chlorellaprotothecoides are obtained when the alga is grown in a mediumrich in glucose and poor in a nitrogen source (urea). When thesecells are incubated in a medium enriched with a nitrogen source,there occurs, besides greening of algal cells, an active formationof DNA followed by synchronous cellular division. The DNA formationand cellular division are markedly suppressed by light of acomparatively low intensity. Blue light is most effective andred light least effective in suppression. The effect of light on the level of dTMP kinase activity inthe algal cells was investigated in relation to the photoinhibitionof DNA formation. It was found that light suppresses the increaseof dTMP kinase activity in the algal cells which starts in advanceof active DNA synthesis, and that blue light has a strongersuppressive effect than red light. ¹Present address: Institute of Medical Science, University ofTokyo, Tokyo.     

Role of Carbonic Anhydrase and Identification of the Active Species of Inorganic Carbon Utilized for Photosynthesis in Chora corallina

Carbonic anhydrase (CA, EC. 4.2.1.1 [EC] ) activity in air-grown Characorallina was detected mainly in the intracellular fraction,most of which composed of chloroplasts and cytoplasmic gel,and not on the cell surface. Only minor levels of CA activity,on the basis of equivalent volumes, were detected in the cellsap and the cytoplasmic sol. The maximum rate of photosynthetic O₂ evolution by air-grownChara corallina at pH 6.0 was twice that at pH 7.6, while theapparent K_m for external inorganic carbon (C_i) at pH 7.6 wasabout three times that at pH 6.0. However, the apparent K_m(CO₂)was about three times larger at pH 6.0 than at pH 7.6. The K_m(C_i)-valueat pH 7.6 increased severalfold in the presence of acetazolamide(AZA), an inhibitor of CA, but no inhibition was observed atpH 6.0. The pH-dependence may be due to differences in the permeabilityof AZA at the given pH values. Fixation of ¹⁴CO₂ at 20 µMand of H¹⁴CO₃^– at 200 µM over the course of 5 swas very similar at pH 7.4. Addition of CA significantly suppressedthe photosynthetic ¹⁴CO₂-fixation but it stimulated the H¹⁴CO₃^–-fixation.This result indicates that free CO₂ is an active species ofC_i that is incorporated into the cell during photosynthesis. These results together suggest the following: (1) Free CO₂ isutilized for photosynthesis, (2) CA is mainly located insidethe cell and functions to increase the affinity for CO₂ in photosynthesisby facilitating the supply of CO₂ from the plasmalemma to thesite of CO₂-fixation. ³Present address: Biological Laboratory, The University of theAir, Wakaba 2-11, Chiba, 260 Japan. (Received December 9, 1988; Accepted March 22, 1989)     

Effects of CO2 concentration during growth on subsequent photosynthetic CO2 fixation in Chlorella1

The maximum rate of photosynthetic ¹⁴CO₂ fixation (V_max) aswell as the concentration of CO₂ at which the rate of photosynthetic¹⁴CO₂ fixation attains one-half its maximum velocity (K_m) inChlorella vulgaris 11h cells was strongly dependent on the concentrationof CO₂ continuously provided during the algal growth. The V_max (µmoles ¹⁴CO₂ fixed/ml pcv?min) and K_m (% CO₂)of the algal cells which had been grown in air containing 4%CO₂ (by volume) were ca. 10 and 0.15–0.17, while thosein the cells which had been grown in ordinary air (containing0.04% CO₂) were 7 and 0.05–0.06, respectively. When the concentration of CO₂ in the bubbling gas was loweredfrom 4 to 0.04% during the algal growth, their photosynthetickinetics attained the respective lower steady levels after 5–10hr. On the other hand, when the photosynthetic kinetics weredetermined 24 hr after raising the concentration of CO₂ from0.04 to 4%, the V_max and K_m-values were found to have alreadyattained the respective higher levels. (Received October 15, 1976; )