Carbonic Anhydrase of a Unicellular Red Alga Porphyridium cruentum R-l. I. Purification and Properties of the Enzyme

Cells of Porphyridium cruentum R-l, a unicellular red alga,grown under ordinary air (0.04% CO₂) showed much higher activityof carbonic anhydrase (CA) than those grown under CCvenrichedair (2% CO₂). CA activity was not detected in a suspension ofintact cells, and was detectable only after the cells had beenhomogenized, indicating that this enzyme was localized onlywithin the algal cells. After partial purification of Porphyridium CA, its mol wt wasestimated as 59 kDa by SDS-PAGE and 55 kDa by gelfiltration.This suggests that the native enzyme is a monomer. Its activitywas not affected by benzensulfonamides, potent inhibitors ofCAs isolated from Chlamydomonas and other organisms. Chloride(or bromide) ions was essential for CA activity. CA activitymarkedly decreased when the cell extract had been incubatedat pH lower than 7 before assay. Upon readjusting the pH ofthe preincubation medium to 9 or higher, the enzyme activitywas restored, indicating that the inactivation is reversible. (Received April 17, 1987; Accepted July 21, 1987)     

Transport and Fixation of Inorganic Carbon during Photosynthesis in Cells of Anabaena Grown under Ordinary Air: III. Some Characteristics of the HCO3--Transport System in Cells Grown under Ordinary Air

In cells of cyanobacterium Anabaena variabilis grown under ordinaryair (low-CO₂ cells), the transport of both CO₂ and HCO₃^–was significantly enhanced by Na⁺. This effect was pronouncedas the external pH increased. When low-CO₂ cells were treatedwith an inhibitor of carbonic anhydrase (CA), only CO₂ transportbut not HCO₃^– transport, was inhibited. The initial rateof photosynthetic carbon fixation as a function of the concentrationof internal inorganic carbon (IC) was practically the same irrespectiveof whether CO₂ or HCO₃^– was externally supplied. Theseresults suggest that IC is actively transported through theplasma membrane in a form of HCO₃^– probably by some transporterand that the transmembrane Na⁺ gradient is involved in thisIC transport system. Free CO₂ may be hydrated by CA to HCO₃^–and then transported to the cells by this transporter. On the other hand, CO₂ is actively taken up by cells grown withair containing 5% CO₂ (high-CO₂ cells) though the enhancingeffect of Na⁺ was much smaller in high- CO₂ cells than in low-CO₂cells. The initial rate of fixation as a function of internal IC concentrationindicated that the rate of the carboxylation reaction of accumulatedIC is higher in I0W-CO₂ cells than in high-CO₂ cells. The studieswith ethoxyzolamide indicated that even in low-CO₂ cells, CAdoes not function inside Anabaena cells. These results suggestthat inside the low-CO₂ cells of Anabaena, some mediator(s)facilitates the transport of IC to RuBPCase. (Received January 23, 1987; Accepted April 24, 1987)     

Variation of Phosphoenolpyruvate Carboxylase Activity in Dunaliella Associated with Changes in Atmospheric CO2 Concentration

In Dunaliella tertiolecta, D. bioculata and D. viridis the activitiesof phosphoenolpyruvate carboxylase and carbonic anhydrase werehigher in the cells grown in ordinary air (low-CO₂ cells) thanin those grown in air enriched with 1–5% CO₂ (high-CO₂cells), whereas in Porphyridium cruentum R-1 there was no differencein phosphoenolpyruvate carboxylase activity between these twotypes of cells. Apparent K_m(NaHCO₃) values for photosynthesisin low-CO₂ cells of all species tested were smaller than thosein high-CO₂ cells. Most of the ¹⁴C was incorporated into 3-phosphoglycerate,sugar mono- and di-phosphates during the initial periods ofphotosynthetic NaH¹⁴CO₃ indicating that both types of cellsin D. tertiolecta are C₃ plants. (Received May 27, 1985; Accepted June 25, 1985)     

Kinetic Studies on the Active Species of Inorganic Carbon Absorbed by the Cells of Dunaliella tertiolecta

Cells of Dunaliella tertiolecta which had been grown in ordinaryair (low-CO₂ cells) had high carbonic anhydrase (CA) activityon the cell surface and mainly utilized HCO₃^– for photosynthesis.When CA activity on the cell surface was inhibited by Diamoxor subtilisin, the cells utilized CO₂. When bovine CA was added,the subtilisin-treated low-CO₂ cells utilized mainly HCO₃^–.When grown in air containing 2% CO₂, the cells had low CA activityon the cell surface, and preferred CO₂ to HCO₃^–. Kineticanalysis of these results indicated that low-CO₂ cells of D.tertiolecta absorb CO₂ which was converted from HCO₃^–via the CA located on the cell surface. (Received June 29, 1985; Accepted October 9, 1985)     

Enzymatic Inactivation of Extracellular Carbonic Anhydrase and its Effect on K1/2 (CO2) for Photosynthesis in Chlorella ellipsoidea C-27

The ratio of the extracellular to the intracellular activityof carbonic anhydrase (CA) in cells of Chlorella ellipsoideaC-27, adapted to low levels of CO₂ for 24 h (low-CO₂ cells),was about one to one. Treatment of intact cells with PronaseP inactivated about one-half of the extracellular CA activitywithout affecting photosynthetic activity. The CA activity incell homogenates and in cell-wall ghosts liberated during celldivision was completely inactivated by the same treatment. Pretreatmentwith Glycosidase mix, Chitosanase and Macerozyme enhanced theinactivation of the CA activity in intact cells. These resultssuggest that extracellular CA is evenly distributed throughoutthe whole cell-wall region. The apparent K_1/2 for dissolved inorganic carbon (DIC) in low-CO₂cells doubled when extracellular CA was inactivated by treatmentwith Pronase P, but the K_1/2 obtained was still one-half ofthat in high-CO₂ cells. Photosynthetic ¹⁴CO₂-fixation in low-CO₂cells was enhanced by acetazolamide, whereas H¹⁴CO₃^–-fixationwas suppressed. The results suggest that CO₂ is a dominant substrateutilized by cells and that HCO₃^– is utilized after conversionto CO₂. The present results show that both intracellular andextracellular CA contribute to the increase in affinity forDIC during photosynthesis in low-CO₂ cells of Chlorella ellipsoideaC-27. (Received May 7, 1990; Accepted July 18, 1990)     

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; )     

Role of Carbonic Anhydrase in Photosynthesis of Blue-Green Alga (Cyanobacterium) Anabaena variabilis ATCC 29413

The affinity for NaHCO₃ (CO₂) in photosynthesis of Anabaenavariabilis ATCC 29413 was much higher in the cells grown underordinary air (low-CO₂ cells) than in those grown in air enrichedwith 2–4% CO₂ (high-CO₂ cells) (pH 8.0, 25?C). Ethoxyzolamide(50 µM) increased the K_m(NaHCO₃ in low-CO₂ cells aboutnine times (from 14.3 to 125), while the maximum rate of photosynthesisdecreased about 20%. When high-CO₂ cells were transferred tolow-CO₂ conditions, carbonic anhydrase (CA) activity increased,while K_m(NaHCO₃) in photosynthesis decreased from 140 to 30µM within about 5 h. The addition of CA to the suspensionof both high- and low-CO₂ cells enhanced the rates of photosyntheticO₂ evolution under CO₂-limiting conditions. The rate of ¹⁴CO₂fixation was much faster than that of H¹⁴CO₃^– fixation.The former reaction was greatly suppressed, while the latterwas enhanced by the addition of CA. These results indicate thatthe active species of inorganic carbon utilized for photosynthesiswas free CO₂ irrespective of the CO₂ concentration given duringgrowth. It is suggested that CA plays an active role in increasingthe affinity for CO₂ in photosynthesis of low-CO₂ cells of thisblue-green alga. (Received January 24, 1984; Accepted October 22, 1984)     

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)     

Form of inorganic carbon utilized for photosynthesis in Chlorella vulgaris 11 h cells

The rate of photosynthetic ¹⁴CO₂ fixation in Chlorella vulgaris11h cells in the presence of 0.55 mM NaH¹⁴CO₃ at pH 8.0 (20?C)was greatly enhanced by the addition of carbonic anhydrase (CA).However, when air containing 400 ppm ¹⁴CO₂ was bubbled throughthe algal suspension, the rate of ¹⁴CO₂ fixation immediatelyafter the start of the bubbling was suppressed by CA. Theseeffects of CA were observed in cells which had been grown inair containing 2% CO₂ (high-CO₂ cells) as well as those grownin ordinary air (containing 0.04% CO₂, low-CO₂ cells). We thereforeconcluded that, irrespective of the CO₂ concentration givento the algal cells during growth, the active species of inorganiccarbon absorbed by Chlorella cells is free CO₂ and they cannotutilize bicarbonate. The effects observed in the high-CO₂ cellswere much more pronounced than those in the high-CO₂ cells.This difference was accounted for by the difference in the affinityfor CO₂ in photosynthesis between the high- and low-CO₂ cells. (Received May 19, 1978; )     

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; )     

Carbonic Anhydrase from the Blue-Green Alga (Cyanobacterium) Anabaena variabilis

Carbonic anhydrase (CA) activity was detected in homogenatesfrom Anabaena variabilis ATCC 29413, M-2 and M-3, but not inthe suspension of the intact cells. Activity was higher in cellsgrown in ordinary air (low-CO₂ cells) than in those grown inair enriched with 2–4% CO₂ (high-CO₂ cells). Fractionationby centrifugation indicated that the CA from A. variabilis ATCC29413 is soluble, whereas both soluble and insoluble forms existin A. variabilis M-2 and M-3. The addition of dithiothreitoland Mg^{2 $} greatly decreased the CA activity of A. variabilisATCC 29413. The specific activity of the CA from A. variabilis ATCC 29413was increased ca. 200 times by purification with ammonium sulfate,DEAE-Sephadex A-50 and Sephadex G-100. Major and minor CA peaksin Sephadex G-100 chromatography showed respective molecularweights of 48,000 and 25,000. The molecular weight of the CAdetermined by polyacrylamide disc gel electrophoresis was 42,000?5,000.The activity of CA was inhibited by ethoxyzolamide (I₅₀=2.8?10^-9M), acetazolamide (I₅₀=2.5?10^-7 M) and sulfanilamide (I₅₀=2.9?10^-6M). (Received January 5, 1984; Accepted April 26, 1984)     

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)     

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)     

Transport and Fixation of Inorganic Carbon in the Cells of Chlorella vulgaris 11h Grown under Ordinary Air

Intracellular accumulation of inorganic carbon (C_i) and itsfixation in photosynthesis were investigated using siliconeoil layer filtering centrifugation technique with the cellsof Chlorella vulgaris 11h grown under ordinary air. Both CO₂and HCO₃^– were transported into the cells from the reactionmedium and accumulated in the cells, but the rate of transportwas much faster for the former than the latter. ¹⁴C-fixationfrom the total transported C_i was much more efficient when CO₂was added in the external medium than when HCO₃^– was added.This indicates that CO₂ and HCO₃^– were not converted tothe common compound in the cells during the initial period ofphotosynthesis. Accumulation of Cⁱ into the cells was much lesssusceptible to low temperature than its fixation. Accumulationof Cⁱ was also observed in the dark. Ethoxyzolamide, an inhibitorof carbonic anhydrase (CA), inhibited the fixation of accumulatedCO₂ in the cells, suggesting that CA enhanced the supply ofCO₂ to the reaction site of ribulose bisphosphate carboxylasein the stroma. Mechanism for transport and fixation of Cⁱ duringphotosynthesis in low-CO₂ cells of C. vulgaris 1lh was proposedfrom these results. (Received March 19, 1986; Accepted June 26, 1986)     

Release of Carbonic Anhydrase from the Cell Surface of Chlamydomonas reinhardtii by Trypsin

Treatment with trypsin of Chlamydomonas reinhardtii cells grownin ordinary air (low-CO₂ cells) caused almost complete releaseof carbonic anhydrase (CA) into the suspending medium, but didnot affect the shape and kinesis of the cells. These resultsindicate that most of the CA exists on the cell surface of low-CO₂cells. The released CA has the same molecular weight, specificactivity and susceptibility to various CA inhibitors as thatpurified from non-treated low-CO₂ cells. (Received August 24, 1985; Accepted November 20, 1985)     

Activities of Carbonic Anhydrase and Carboxylating Enzymes in Chlamydomonas segnis Adapted and Adapting to Air Levels of Carbon Dioxide

Activities of carbonic anhydrase (CA), phosphoenolpyruvate carboxylase(PEPCase) and ribulose 1,5-bisphosphate carboxylase (RuBPCase)were compared in air- and 5% CO₂adapted and adapting cells ofChlamydomonas segnis during the cell cycle in continuously illuminatedsynchronous cultures. Air-adapted cells exhibited considerablylower PEPCase activities, but higher RuBPCase and CA activitiesthan 5% CO²-adapted cells. Most (75 to 88%) of the CA activityin air-adapted cells appeared to be located in the periplasmicspace. Transferring 5% CO₂-adapted cells to air scarcely influencedRuBPCase activity, but led to 85% decrease in the activity ofPEPCase and to 400% increase in that of CA. In such air-adaptingcells, more than half (54 to 70%) of the CA activity was intracellular.The proposal that PEPCase and RuBPCase in addition to CA maybe involved in the regulation of inorganic carbon uptake byair-adapted and adapting cells under CO₂-limiting conditionsis discussed. (Received June 11, 1987; Accepted September 5, 1987)     

An Evidence Indicating That a Weak Orange Light Absorbed by Phycobilisomes Causes Inactivation of PSII in Cells of the Red Alga Porphyridium cruentum Grown under a Weak Red Light Preferentially Exciting Chl a

Changes in the PSII fluorescence upon shift of light qualitywere studied with the red alga Porphyridium cruentum IAM R-1and supplementarily with P. cruentum ATCC 50161, the cyanophytesSynechocystis spp. PCC6714 and PCC6803 and Synechococcus sp.NIBB1071. When Porphyridium cruentum grown under a weak redlight (PSI light) preferentially absorbed by Chl a was illuminatedwith a weak orange light (PSII light) mainly absorbed by phycobilisomes(PBS), a change of PSII fluorescence at room temperature wasinduced. The ratio of Fvm (Fm— Fo) to Fm was reduced rapidlyaccompanying the increase in Fo (T^1/2 ca. 3 min). The effectsof DCMU and 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinoneindicated that the fluorescence change is induced when plastoquinonepool is highly reduced. The fluorescence change after a shortPSII light illumination was reversible; it rapidly recoveredin the dark (T ^1/2 ca. 3 min). The reversibility was graduallyreduced and disappeared after 40 h under PSII light accompanyingdecrease in PSII activity per PBS down to almost 50%. Sincethe pattern of the fluorescence change resembles that observablewhen PSII is photoinactivated, PSII light probably induces thephotoinactivation of PSII, possibly reversibly at first andirreversibly after prolonged illumination. Such a rapid fluorescencechange was insignificant in Synechocystis sp. either PCC6714or PCC6803. Only a slow and small decrease in Fvm/Fm level appearedafter prolonged PSII light illumination (the reduction of PSIIactivity per PBS was around 20%). In Porphyridium, shift fromPSII light to PSI light caused a rapid and chloramphenicol-sensitiveFvm/Fm elevation during the first 10 h while the increase inPSH activity per PBS was only 10% of that before the light shift.Then, a gradual elevation followed up to the level at the steadystate under PSI light. A similar rapid increase in Fvm/Fm wasobserved with Synechocystis PCC6714, in which the synthesisof PSII is not regulated, suggesting that a rapid increase inFvm/Fm does not reflect the acceleration of the synthesis ofPSII. Results were interpreted as that (1) PSII light causesphotoinactivation of PSII. Such a photoinactivation is markedin Prophyridium cells grown under PSI light. (2) In Porphyridium,changes in the abundance of PSII upon shift of light qualityare largely attributed to the photoinactivation of this type. (Received February 19, 1999; Accepted June 14, 1999)     

Photosynthetic Characteristics of Chloroplasts Isolated from Euglena gracilis Z Grown Photoautotrophically

Photosynthetically competent chloroplasts were isolated fromcells of Euglena gracilis Z grown photoautotrophically in 1.5%CO₂. The isolated chloroplasts were intact and substantiallyfree from cytosolic, mitochondrial and microbody materials.The effects of some compounds on the activity of photosynthetic¹⁴CO₂ fixation were examined. The optimal pH and sorbitol concentrationwere 8.0 and 0.33 M, respectively. The chloroplasts requireda high level of P, (5 to 20 mM) for the maximal rate of photosynthesis.They were insusceptible to 10 mM of free Mg²⁺. ATP, ADP andAMP at 1 to 5 mM notably stimulated photosynthesis, althoughhigh concentrations of AMP were unfavorable. In the assay mediumdeveloped for this study, the chloroplasts exhibited photosyntheticactivity of 120µmoles-mg^–1 Chl-h^–1 at 30?C. Chloroplasts could also be isolated from cells grown under ordinaryair. The rate of photosynthetic ¹⁴CO₂ fixation at 1 mM NaH^l4CO₃was higher in these chloroplasts than in those isolated fromcells grown in 1.5% CO₂, whereas at 10 mM NaH^l4CO₃, the ratesof the two types of chloroplasts were nearly the same. Theseresults suggest that the CO₂ concentration given during growthof the algal cells affects the affinity for dissolved inorganiccarbon at the chloroplast level. (Received March 30, 1987; Accepted August 17, 1987)     

Intraspecific variation in the light/dark modulation of ribulose 1,5-bisphosphate carboxylase-oxygenase activity in soybean

A comparative study was made of the inhibition of ribulose-1,5-bisphosphatecarboxylase-oxygenase (Rubisco) amongst six cultivars of Glycinemax L. Merr., associated with synthesis of 2-carboxyarabinitol1-phosphate (CA1P) during darkness. Significantly lower meanvalues of dark inhibition of Rubisco were observed in soybeancv. Davis than in cvs Bragg, Cobb, Hardee, Gordon, and Kirby.The CA1P synthesis/degradation cycle during dark/light transitionsremained operational in cv. Bragg plants grown at low irradiance(40 µmol photons m–2 s–1). However, CA1P synthesisand degradation rates were slower in the dark (t_0.5 = 240 versus25 min), and light (t_0.5 = 20 versus 3.8 min) respectively,as compared to plants grown at higher irradiance (550 µmolphotons m^–2 s^–1). In addition, the activation stateof Rubisco in low-light-grown plants showed only a small declineafter a transition to darkness. We conclude that (a) cultivar-dependentvariation occurs amongst soybeans with respect to CAlP regulationof Rubisco, and (b) soybeans acclimated to low irradiance maydepend more on CA1P synthesis/degradation to regulate Rubisco,and less on changes in the enzyme activation state. Key words: Activation state, Glycine max, photosynthesis, Rubisco, 2-carboxyarabinitol 1-phosphate