An efficient method of selecting photoautotrophic cells from cultured heterogeneous cells

A new and efficient method was demonstrated for the establishmentof photoautotrophic cultures of plant cells. Leaf segments ofAtropa belladonna, Datura stramonium and Hyoscyamus niger wereinoculated on sugar-free Linsmaier-Skoog agar medium then aeratedwith 1% CO₂ enriched air under 3,000 to 5,000 lux of illumination.Under these regulated conditions we could select photoautotrophicgreen cells efficiently, and these cells subsequently have grownwell under photoautotrophic conditions. ¹Department of Horticulture and Agriculture, Faculty of Agriculture,Kobe University, Kobe 657, Japan (Received June 12, 1980; )     

Form of Inorganic Carbon Utilized for Photosynthesis in Chlamydomonas reinhardtii1

The effect of carbonic anhydrase (CA) on time courses of photosynthetic¹⁴C incorporation in the presence of ¹⁴CO₂ or NaH¹⁴CO₃ was studiedwith cells of Chlamydomonas reinhardtii which had been grownunder ordinary air (low-CO₂ cells) or air enriched with 4% CO₂(high-CO₂ cells). Experimental data obtained at 20°C andpH 8.0 suggested that the major form of inorganic carbon utilizedby high-CO₂ cells was CO₂, while that utilized by low-CO₂ cellswas HCO₃^–. The cell suspension showed CA activity which was comparableto that observed in the sonicate of cells. Both activities werehigher in low-CO₂ cells than in high-CO₂ cells. The mechanism by which HCO₃^– is utilized by low-CO₂ cellsof C. reinhardtii is discussed. ³Present address: Department of Biology, Faculty of Science,University of Niigata, Niigata 950-21, Japan. (Received August 4, 1982; Accepted January 19, 1983)     

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; )     

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; )     

A Mutant of Arabidopsis thaliana That Defines a New Locus for Glycine Decarboxylation

A novel photorespiratory mutant of Arabidopsis thaliana, designatedgld2, was isolated based on a growth requirement for abnormallyhigh levels of atmospheric CO₂. Photosynthetic CO₂ fixationwas inhibited in the mutant following illumination in air butnot in atmosphere containing 2% O₂. Photosynthetic assimilationof ¹⁴CO₂ in an atmosphere containing 50% O₂ resulted in accumulationof 48% of the soluble label in glycine in the mutant comparedto 9% in the wild type. The rate of glycine decarboxylationby isolated mitochondria from the mutant was reduced to 6% ofthe wild type rate. In genetic crosses, the mutant complementedtwo previously described photorespiratory mutants of A. thalianathat accumulate glycine during photosynthesis in air due todefects in glycine decarboxylase (glyD, now designated gld1)and serine transhydroxymethylase (stm). Because glycine decarboxylaseis a complex of four enzymes, these results are consistent witha mutation in a glycine decarboxylase subunit other than thataffected in the gld1 mutant. The two gld loci were mapped tochromosomes 2 and 5, respectively. ³Present address: Department of Crop and Soil Sciences, MichiganState University, East Lansing, MI 48824, U.S.A. ⁴Present address: Department of Applied Bioscience, Facultyof Agriculture, Hokkaido University, Kita-Ku, Sapporo, 060 Japan ⁵Present address: Department of Biology, Carnegie Institutionof Washington, 290 Panama Street, Standford, CA 94305, U.S.A.     

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; )     

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; )     

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; )     

Utilization Modes of Inorganic Carbon for Photosynthesis in Various Species of Chlorella

Rates of CO₂ and HCC₃^– fixation in cells of various Chlorellaspecies in suspension were compared from the amounts of ¹⁴Cfixed during the 5 s after the injection of a solution containingonly ¹⁴CO₂ or H¹⁴CO₃^–. Results indicated that irrespectiveof the CO₂ concentration during growth, Chlorella vulgaris 11h and C. miniata mainly utilized CO₂, whereas C. vulgaris C-3,C. sp. K. and C. ellipsoidea took up HCO₃^– in additionto CO₂. Cells of C. pyrenoidosa that had been grown with 1.5%CO₂ (high-CO₂ cells) mainly utilized CO₂, whereas those grownwith air (low-CO₂ cells) utilized HCO₃^– in addition toCO₂. Cells that utilized HCO₃^– had carbonic anhydrase(CA) on their surfaces. The effects of Diamox and CA on the rates of CO₂ and HCO₃^–fixation are in accord with the inference that HCO₃^– wasutilized after conversion to CO₂ via the CA located on the cellsurface. CA was found in both the soluble and insoluble fractions;the CA on the cell surface was insoluble. Independent of the modes of utilization, the apparent K_m (NaHCO₃)for photosynthesis was much lower in low-CO₂ cells than in high-CO₂ones. The fact that the CA in the soluble fraction in C. vulgarisC-3 was closely correlated with the K_m(NaHCO₃) indicates thatsoluble CA lowers the K_m. ¹ Dedicated to the late Professor Joji Ashida, one of the foundersand first president of the Japanese Society of Plant Physiologists. ⁴ On leave from Research and Production Laboratory of Algology,Bulgarian Academy of Sciences, Sofia. (Received September 14, 1982; Accepted March 1, 1983)     

A Mutant of Chlamydomonas reinhardtii with Reduced Rate of Photorespiration

Photorespiration rates under air-equilibrated conditions (0.04%CO₂ and 21% O₂) were measured in Chlamydomonas reinhardtii wild-type2137, a phosphoglycolate-phosphatase-deficient (pgp1) mutantand a suppressor double mutant (7FR2N) derived from the pgp1mutant. In both cells grown under 5% CO₂ and adapted air for24 h in the suppressor double mutant, the maximal rate of photorespiration(phosphoglycolate synthesis) was only about half of that ineither the wild type or the pgp1 mutant (18-7F) cells. In theprogeny, the reduced rate of photorespiration was accompaniedby increased photosynthetic affinity for inorganic carbon andthe capacity for growth under air whether accompanied by thepgp1 background or not. Tetrad analyses suggested that thesethree characteristics all resulted from a nuclear single-genemutation at a site unlinked to the pgp1 mutation. The decreasein photorespiration was, however, not due to an increase inthe CO₂/O₂ relative specificity of ribulose-1,5-bisphosphatecarboxylase/oxygenase of 7FR2N or of any other suppressor doublemutants tested. The relationship between the decrease in therate of photorespiration and the CO₂-concentrating mechanismis discussed. ³ Current address: Institute of Botany, Academy of Sciences,Patamdar Shosse, 40, Baku, 370073, Azerbaijan. ⁴ Current address: Department of Management and InformationScience, Jobu University, 270-1, Shinmachi, Tano, Gunma, 370-1393Japan.     

Ultrastructure of Dunaliella tertiolecta Cells Grown under Low and High CO2 Concentrations1

The cells of Dunaliella tertiolecta grown under ordinary air(low-CO₂ cells) had a well developed pyrenoid with many morestarch granules than those grown under air enriched with CO₂(high-CO₂ cells). The chloroplast was located close to the plasmamembranein low-CO₂ cells, while that in high-CO₂ cells was located inthe inner area of the cells. Chloroplast envelope was electronicallydenser in low-CO₂ cells than in high-CO₂ cells, while the oppositeeffect of CO₂ was observed for the plasmamembrane. ²On leave from Institute of Biology, University of Novi Sad,Novi Sad, Yugoslavia. (Received November 7, 1985; Accepted March 5, 1986)     

Changes in Photosystem Stoichiometry in Response to Environmental Conditions for Cell Growth Observed with the Cyanophyte Synechocystis PCC 6714

Changes in photosystem stoichiometry in response to shift ofenvironments for cell growth other than light regime were studiedwith the cyanophyte Synechocystis PCC 6714 in relation to thechange induced by light-quality shift. Following two environment-shiftswere examined: the shift of molecular form of inorganic carbonsource for photosynthesis from CO₂ to HCO₃^– (CO₂ stress)and the increase in salinity of the medium with NaCl (0.5 M)(Na⁺ stress). Both CO₂ and Na⁺ stresses induced the increasein PSI abundance resulting in a higher PSI/PSII stoichiometry.CO₂ stress was found to elevate simultaneously Cyt c oxidaseactivity (V_max). The feature was the same as that caused bylight-quality shift from preferential excitation of PSI to PSII(light stress) though the enhancement by either stress was smallerthan that by light stress. Under our experimental conditions,PSI/PSII stoichiometry appeared to increase at a fairly constantrate to the basal level even when the basal level had been differentlydetermined by the light-quality. Enhancing rates for PSI/PSIIstoichiometry and for Cyt c oxidase activity were also similarto each other. Since the two stresses affect the thylakoid electrontransport similarly to the shift of light-quality, we interpretedour results as follows: three environmental stresses, CO₂, Na⁺,and light stresses, cause changes in electron turnover capacityof PSI and Cyt c oxidase under a similar, probably a common,mechanism for monitoring redox state of thylakoid electron transportsystem. ¹On leave from Department of Biology, College of Natural Science,Kyngpook National University, Taegu 702-701, Korea. ₂Present address: Department of Marine Bioscience, Fukui Pre-fecturalUniversity, Obama, Fukui, 917 Japan.     

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)     

Changes in Photosynthetic Characteristics Induced by Transferring Air-Grown Cells of Chlorococcum littorale to High-CO2 Conditions

When air-grown cells of Chlorococcum littorale was enrichedwith CO₂, growth was enhanced after a lag period of one to twodays at 20% CO₂, and 3 to 6 days at 40% CO₂. Changes in therate of photosynthesis measured as oxygen evolution and CO₂fixation, were similar to those observed for growth. Duringthe initial inhibition of photosynthesis in 40% CO₂, the activityof PSII was suppressed. In contrast, PSI activity was greatlyenhanced. Air-grown cells of C. littorale possessed comparatively highcarbonic anhydrase (CA) activity which was localized insidethe cells and on the cell surface. Under high CO₂ concentrationsextracellular CA activity was greatly suppressed and intracellularactivity almost completely abolished. Phosphoenol pyruvate carboxylaseactivity was also suppressed in high CO₂-grown cells. Ribulose-l,5-bisphosphatecarboxylase activity was higher in high-CO₂ grown cells thanin air-grown cells. The above results indicated that the lagphase induced by 40% CO₂ was due to suppression of PSII activity. ¹Part of this work was reported in the International PhotosynthesisCongress, Nagoya, 1992.     

Metabolism of p-Hydroxybenzoate via Hydroxyquinol by Trichosporon cutaneum WY2-2: Characterization of the Pathway using Superoxide Dismutase as a Stabilizer of Hydroxyquinol

Trichosporon cutaneum WY2-2 was shown to metabolize p-hydroxybenzoatevia protocatechuate and hydroxyquinol. Using superoxide dismutaseas a stabilizer of hydroxyquinol, the conversion of protocatechuateto hydroxyquinol and the ring fission process of hydroxyquinolwere confirmed. Hydroxyquinol was chemically identified as theproduct of protocatechuate hydroxylase reaction. Partially purifiedprotocatechuate hydroxylase was highly specific for protocatechuate;its K_m values for protocatechuate and NADH were 17.6 and 12.4µM, respectively. It catalyzed equimolar CO₂ formation,NADH oxidation and O₂ consumption from protocatechuate. Hydroxyquinoldioxygenase was highly specific for hydroxyquinol, with a K_mof 2.9 µM. ¹A preliminary account of this work was presented at the 81stMeeting of the Chubu-branch of Agricultural Chemical Societyof Japan, Gifu, October, 1980. ²Present address: Biological Institute, Faculty of Science,Nagoya University, Nagoya 464, Japan. ³Present address: Shin Nihon Chemical Co. Ltd... 19-10, Showa-cho,Anjoh, Aichi 446, Japan. (Received November 15, 1985; Accepted August 27, 1986)     

Pathway of mannitol formation during photosynthesis in brown algae

Eisenia bicyclis, Arame, was allowed to photosynthesize in seawatercontaining H¹⁴CO₃^–, and ¹⁴C-mannitol was isolated fromits fronds. The ratio of ¹⁴C-total/¹⁴C₁ + ¹⁴C₆ in the ¹⁴C-mannitolwas found to be about 8.0 at 1 min-illumination, but graduallydecreased with time to 3.0, showing uniform radioactivity distribution.Mannitol therefore seems to be formed in brown algae throughthree carbon compounds. Enzymes which may be involved in the possible biosynthetic pathwayof mannitol, i.e. aldolase, hexose diphosphatase, mannitol-1-phosphataseand glucosephosphate isomerase were present in extracts fromseveral brown algae. Some of their properties are discussed. ¹Contribution from the Shimoda Marine Biological Station ofTokyo Kyoiku University, No. 187. ²Present address: Reseach Institute, Seikagaku Kogyo Co., Ltd.,Yamato-machi, Kitatama-gun, Tokyo, Japan. (Received December 13, 1968; )     

Alkalization of the Medium by Unicellular Green Algae during Uptake Dissolved Inorganic Carbon

When Chlorella vulgaris 11h, Chlorella vulgaris C-l, Chlamydomonasreinhardtii, Chlamydomonas moewusii, Scenedesmus obliquus, orDunaliella tertiolecta were illuminated in with 0.5 mM NaHCO₃,the pH of the medium increased in a few minutes from 6 to about9 or 10. The alkalization, which was accompanied by O₂ evolution,was dependent on light, external dissolved inorganic carbon(DIC) as HCO^-₃, and algae grown or adapted to a low, air-levelCO₂ in order to develop a DIC concentrating mechanism. Therewas little pH increase by algae without a DIC concentratingprocess from growth on 3% CO₂ in air. Photosynthetic O₂ evolutionwithout alkalization occurred using either internal DIC or externalCO₂ at acidic pH. The PH increase stopped between pH 9 to 10,but the alkalization would restart upon re-acidification betweenpH 6 and 8. Alkalization was suppressed by the carbonic anhydraseinhibitors, acetazolamide, ethoxyzolamide or carbon oxysulfide.The pH increase appeared to be the consequence of the externalconversion of HCO^–₃ into CO₂ plus OH^– during photosynthesisby cells with a high affinity for CO₂ uptake. Cells grown onhigh CO₂ to suppress the DIC pump, when given low levels ofHCO^–₃ in the light, acidified the medium from pH 10 to7. Air adapted Scenedesmus cells with a HCO^–₃ pump, aswell as a CO₂ pump, alkalized the medium very rapidly in thelight to a pH of over 10, as well as slower in the dark or inthe light with DCMU or without external DIC and O₂ evolution.Alkalization of the medium during photosynthetic DIC uptakeby algae has been considered to be part of the global carboncycle for converting H₂CO₃ to HCO^–₃ and for the formationof carbonate salts by calcareous algae from the alkaline conversionof bicarbonate to carbonate. These processes seem to be a consequenceof the algal CO₂ concentrating process. ¹Present address: Department of Biology, Faculty of Science,Niigata University, Niigata, 950-21 Japan.     

Photosynthetic and Photorespiratory Enzymes in Widely Divergent Plant Species with Special Reference to the Moss Ceratodon purpureus: Properties of Ribulose Bisphosphate Carboxylase/ Oxygenase, Phosphoenolpyruvate Carboxylase and Glycolate Oxidase

Rintamäki, E. and Aro, E.-M. 1985. Photosynthetic and photorespiratoryenzymes in widely divergent plant species with special referenceto the moss Ceratodon purpureus: Properties of ribulose bisphosphatecarboxylase/oxygenase, phosphoenolpyruvate carboxylase and glycolateoxidase.—J. exp. Bot. 36: 1677–1684. Km(CO₂) values and maximal velocities of ribulose bisphosphatecarboxylase/oxygenase (E.C. 4.1.1.39 [EC] ) were determined for sixplant species growing in the wild, consisting of a moss, a fernand four angiosperms. The maximum velocities of the RuBP carboxylasesvaried from 0.13 to 0.;62 µmol CO₂ fixed min^–1 mg^–1soluble protein and the Km(CO₂) values from 15 to 22 mmol m^–3CO₂. The highest Km(CO₂) values found were for the moss, Ceratodonpurpureus, and the grass, Deschampsia flexuosa. These plantsalso had the highest ratios of the activities of RuBP carboxylaseto RuBP oxygenase. Glycolate oxidase (E.C. 1.1.3.1 [EC] ) activitieswere slightly lower in D.flexuosa, but not in C. purpureus,than for typical C₃ species. Phosphoenolpyruvate carboxylase(E.C. 4.1.1.31 [EC] ) was not involved in the photosynthetic carboxylationby these two plants. However, another grass, Phragmites australis,was intermediate in PEP carboxylase activity between C₃ andC₄ plants The properties of RuBP carboxylase/oxygenase are discussedin relation to the activities of PEP carboxylase and glycolateoxidase and to the internal CO₂ concentration. Key words: RuBP carboxylase, oxygenase, Km(CO₂), moss     

Wavelength effects on photosynthetic carbon metabolism in Chlorella

To study the wavelength-effect on photosynthetic carbon metabolism,¹⁴C-bicarbon-ate was added to Chlorella vulgaris 1 lh suspensionunder monochromatic blue (456 nm) and red (660 nm) light. Thelight intensities were so adjusted that the rates of ¹⁴CO₂ fixationunder blue and red light were practically equal. Analysis of¹⁴C-fixation products revealed that the rates of ¹⁴CO₂ incorporationinto sucrose and starch were greater under red light than underblue light, while blue light specifically enhanced ¹⁴CO₂ incorporationinto alanine, aspartate, glutamate, glutamine, malate, citrate,lipid fraction and alcohol-water insoluble non-carbohydratefraction. Pretreatment of the algal cells in phosphate mediumin the dark, which was essential for the blue light enhancementof PEP carboxylase activity, was not necessary to induce theabove wavelength effects. Superimposition of monochromatic bluelight at low intensity (450 erg.cm^–2.sec^–1) on thered light at saturating intensity caused a significant decreasein the rate of ¹⁴CO₂ incorporation into sucrose and increasein incorporation into alanine, lipid-fraction, aspartate andother related compounds, indicating that the path of carbonin photosynthesis is regulated by short wavelengdi light ofvery low intensity. Possible effects of wavelength regulationof photosynthetic carbon metabolism in algal cells are discussed. ¹ Part of this investigation was reported at the XII InternationalBotanical Congress, Leningrad, 1975 and the Japan-US CooperativeScience Seminar "Biological Solar Energy Conversion", Miami,1976. Requests for reprints should be addressed to S. Miyachi,Radioisotope Centre, University of Tokyo, Bunkyo-ku, Tokyo 113,Japan. ⁴ Present address: Department of Chemistry, Faculty of PharmaceuticalSciences, Teikyo Univ., Sagamiko, Kanagawa, Japan. (Received August 6, 1977; )