O2-stimulated synthesis of bacteriochlorophyll and carotenoids in marine bacteria

We examined the effects of a limitation of the O₂-supply onthe syntheses of bacteriochlorophyll a_p and carotenoids in isolatesof aerobic marine bacteria, OCh 101 and OCh 114, grown heterotrophically.Whereas they formed these pigments fairly well under high aerationin the dark, a limitation of the O₂-supply resulted in the decreasedsyntheses of bacteriochlorophyll in both strains. Synthesesof carotenoids also were depressed under low aeration but toa lesser extent (especially in OCh 101) than the depressionof bacteriochlorophyll synthesis. Aerobic incubation of a cultureof OCh 101, that previously had been grown semiaerobically,induced the supplementary synthesis of bacteriochlorophyll.This induction was inhibited almost completely by chloram-phenicol.The absorption spectra of suspensions and solvent extracts ofcells grown aerobically or semiaerobically are reported. (Received May 30, 1980; )     

Photochemical Activities of Bacteriochlorophyll in Aerobically Grown Cells of Aerobic Heterotrophs, Erythrobacter Species (OCh 114) and Erythrobacter longus (OCh 101)

Reversible photo-oxidation of cytochromes and reversible photobleachingof bacteriochlorophyll were observed in aerobically grown cellsof the aerobic heterotroph, the Erythrobacter species (OCh 114).Light inhibited O₂-uptake by cells of this bacterium and Erythrobacterlongus (OCh 101). A vesicular structure of intracytoplasmicmembrane systems was observed in sections of aerobically growncells of OCh 114. These bacteria may be called aerobic photosyntheticbacteria (i.e., photosynthetic bacteria which can utilize lightenergy under aerobic conditions but not under anaerobic conditions). (Received September 9, 1981; Accepted December 2, 1981)     

O2 Regulation of Bacteriochlorophyll Synthesis in the Aerobic Bacterium Erythrobacter

This study examined the effect of oxygen on the bacteriochlorophyll(Bchl) synthetic activity of the aerobic marine bacterium Erythrobacter.The activity of the orange-pigmented strain E. longus OCh 101was highest at full atmospheric oxygen tension, while that ofthe pink-pigmented strain Erythrobacter sp. OCh 114 was lowat this tension and not observed in the absence of oxygen. (Received January 26, 1987; Accepted August 13, 1987)     

Excitation and Emission Spectroscopy of Membranes and Pigment-protein Complexes of an Aerobic Photosynthetic Bacterium, Erythrobacter sp. OCh 114

Emission and excitation spectra of steady-state fluorescencefrom membranes and isolated pigment-protein complexes of anaerobic photosynthetic bacterium, Erythrobacter sp. strain OCh114 indicated high efficiency of energy transfer from Bchl 806to Bchl 870 and from carotenoids to bacteriochlorophyll. Thus,this bacterium has a highly efficient light-harvesting systemtypical of photosynthetic bacteria. (Received August 3, 1989; Accepted January 27, 1990)     

Increases in Cellular Levels of Cytochrome cd1 in Roseobacter denitrificans upon Irradiation with Green Light during Aerobic Growth

The cellular level of cytochrome cd₁, the nitrite reductaseof the aerobic photosynthetic bacterium Roseobacter denitrificans,increased considerably when the cells were grown aerobicallyunder white light. The action spectrum for the increase, determinedboth spectroscopically and immunologically, revealed that greenlight at 561 nm was most effective, while blue light between400 and 500 nm was fairly effective. Red and far-red light (650–900nm) absorbed by the bacterio-chlorophyll had no effect, eventhough bacteriochlorophyll and carotenoids were formed normallyduring the growth of cells. Diphenylamine, an inhibitor of thebiosynthesis of carotenoids abolished the increase in levelsof the cytochrome, a result that suggests that a carotenoid(s)was responsible for this phenomenon. The bulk carotenoids seem,however, to be unlikely the candidates for the photoreceptorsbecause they did not accumulate in the light-grown cells. Attemptsto detect archaerhodopsin, 11-cis and all-trans retinal by immunologicalor HPLC analysis were unsuccessful. Although we failed to identifythe photoreceptor, it is clear that R. denitrificans has a green-lightsignal-transduction system that controls the expression of cytochromecd₁. (Received April 19, 1993; Accepted July 12, 1993)     

Hydrogen Effect on Nitrogenase (C2H2 Reduction) Response to Oxygen in Bradyrhizobium japonicum-Phaseoleae Symbioses

The influence of hydrogenase in Bradyrizobum-Phaseoleae symbioseswas studied ex-planta and in-planra in soybean (Glycine max)and cowpea (Vigna unguiculata). The hydrogenase was activatedby the addition of hydrogen in the incubation gas phase whichmodified the response of nitrogenase activity of Hup⁺ (hydrogenuptake positive) symbiosis to the external oxygen partial pressure.For bacteroids the hydrogenase expression increased nitrogenaseactivity at supraoptimal pO₂, acting possibly as a respiratoryprotection of nitrogenase. However, at suboptimal pO₂, nitrogenaseactivity of Hup⁺ bacteroids decreased with hydrogen, a phenomenonattributed to the lower efficiency of ATP synthesis from hydrogenthan from carbon substrates oxidation. For undisturbed nodules,the hydrogenase expression in soybean increased the optimalpO₂ for ARA (COP), from 35.3 to 40.3 kPa O₂, and the ARA atsupraoptimal pO₂; at suboptimal PO₂ there was a negative effectof hydrogenase on ARA, although this inhibition was less thanon bacteroids and was not detected if plants were grown at 15°C rather than 20 °C root temperature. No H₂ effectwas detected on cowpea nodules. The results on soybean nodulesare consistent with the concept that symbiotic nitrogen fixationis oxygen-limited and that hydrogenase activity has no beneficialeffect on nitrogen fixation in O₂ limitation. Key words: Glycine max, hydrogenase, nitrogenase, nitrogen fixation, nodules, Vigna unguiculata     

Roles of bacteriochlorophyll and carotenoid synthesis in formation of intracytoplasmic membrane systems and pigment-protein complexes in an aerobic photosynthetic bacterium, Erythrobacter sp. strain OCh114.

Synthesis of bacteriochlorophyll and carotenoids was inhibited in an aerobic photosynthetic bacterium, Erythrobacter sp. strain OCh114, by alpha, alpha'-dipyridyl and diphenylamine. Formation of two pigment-protein complexes, reaction center-B870 (RC-B870) and B806, and development of the intracytoplasmic membranes of the cells were studied by spectral analysis and electron microscopy. Inhibition of bacteriochlorophyll synthesis by alpha, alpha'-dipyridyl, which was accompanied by a decrease in carotenoid synthesis, suppressed formation of intracytoplasmic membranes in the cells. Growth under illumination had a similar effect on formation of pigments and membranes. On the other hand, inhibition of carotenoid synthesis by diphenylamine did not suppress either development of the membrane system or bacteriochlorophyll synthesis. Formation of RC-B870 and B806 complexes, however, was differentially affected by blockage of carotenoid synthesis. In the presence of diphenylamine, the B806 complex was formed in a much smaller amount than the RC-B870 complex. These results suggest that, in Erythrobacter sp. strain OCh114, bacteriochlorophyll plays an essential role in intracytoplasmic membrane development, and carotenoids are important for assembly of pigment-protein complexes.     

Active oxygen participation in chlorophyll destruction and lipid peroxidation in SO2-fumigated leaves of spinach

Chlorophyll a and carotenoids of spinach began to be destroyed2 to 3 hr after fumigation with 2 ppm SO₂ under light, whereaschlorophyll b was undamaged during 8 hr of exposure to SO₂.Pheophytin a was not affected by the fumigation. When disks excised from leaves fumigated with SO₂ at 2 ppm for2 hr were illuminated, chlorophyll a and carotenoids were brokendown, while they were not destroyed in darkness. The destructionof these pigments was suppressed under nitrogen. Chlorophylla destruction was inhibited by l,2-dihydroxybenzene-3,5-disulfonate(tiron), hydro-quinone and ascorbate, but not by l,4-diazabicyclo-[2,2,2]-octane(DABCO), methio-nine, histidine, benzoate and formate. Chlorophylla destruction was inhibited by phenazine methosulfate but stimulatedby methyl viologen. Addition of superoxide dismutase (SOD) tothe homogenate of SO₂-fumigated leaves inhibited the chlorophylla destruction. The activity of endogenous SOD was reduced to40% by 2-hr fumigation before the loss of chlorophyll was observed.These results suggest that chlorophyll a destruction by SO₂was due to superoxide radicals (O₂^–). Moreover, malondialdehyde (MDA), a product of lipid peroxidation,was formed in SO₂-fumigated leaves. MDA formation was inhibitedby tiron, hydroquinone and DABCO but not by benzoate and formate.MDA formation was increased by D₂O. These results suggest thatlipid peroxidation in SO₂-fumigated leaves was due to singletoxygen ¹O₂ produced from O_2^–. (Received May 15, 1980; )     

Active oxygen participation in chlorophyll destruction and lipid peroxidation in SO2-fumigated leaves of spinach

Chlorophyll a and carotenoids of spinach began to be destroyed2 to 3 hr after fumigation with 2 ppm SO₂ under light, whereaschlorophyll b was undamaged during 8 hr of exposure to SO₂.Pheophytin a was not affected by the fumigation. When disks excised from leaves fumigated with SO₂ at 2 ppm for2 hr were illuminated, chlorophyll a and carotenoids were brokendown, while they were not destroyed in darkness. The destructionof these pigments was suppressed under nitrogen. Chlorophylla destruction was inhibited by l,2-dihydroxybenzene-3,5-disulfonate(tiron), hydro-quinone and ascorbate, but not by l,4-diazabicyclo-[2,2,2]-octane(DABCO), methio-nine, histidine, benzoate and formate. Chlorophylla destruction was inhibited by phenazine methosulfate but stimulatedby methyl viologen. Addition of superoxide dismutase (SOD) tothe homogenate of SO₂-fumigated leaves inhibited the chlorophylla destruction. The activity of endogenous SOD was reduced to40% by 2-hr fumigation before the loss of chlorophyll was observed.These results suggest that chlorophyll a destruction by SO₂was due to superoxide radicals (O₂^–). Moreover, malondialdehyde (MDA), a product of lipid peroxidation,was formed in SO₂-fumigated leaves. MDA formation was inhibitedby tiron, hydroquinone and DABCO but not by benzoate and formate.MDA formation was increased by D₂O. These results suggest thatlipid peroxidation in SO₂-fumigated leaves was due to singletoxygen ¹O₂ produced from O_2^–. (Received May 15, 1980; )     

Action Spectra for Inhibition by Light of Accumulation of Bacteriochlorophyll and Carotenoid during Aerobic Growth of Photosynthetic Bacteria

Action spectra for the inhibition by light of the accumulationof photosynthetic pigments during the aerobic growth of a photosyntheticbacterium, Rhodobacter sphaeroides, and an aerobic photosyntheticbacterium, Erythrobacter sp. strain OCh 114, were determinedover the range of wavelengths from 380 to 870 nm. The actionspectra for the inhibition of accumulation of bacteriochlorophyllin both R. sphaeroides and Erythrobacter sp. strain OCh 114indicated that the maximum inhibition occurred at approximately400 nm and a low level of inhibition occurred at 575 and 770nm. In R. sphaeroides, the action spectrum for the inhibitionof accumulation of carotenoid paralleled that for the inhibitionof accumulation of bacteriochlorophyll over the same range ofwavelengths. These results indicate that in both species, grownunder aerobic conditions, the same photoreceptor is involvedin the inhibition. One possible candidate for the relevant photoreceptormay be the precursor(s) to bacteriochlorophyll. It is possiblethat the photoreceptor is decomposed by light absorbed by itselfor by an unidentified photoreceptor that absorbs blue light(a photo-sensitizer). It is suggested that the accumulationof carotenoid is dependent on the stability of the bacteriochlorophyll. (Received September 16, 1988; Accepted March 2, 1989)     

Inhibition of nitrogenase activity and nodule oxygen permeability by water deficit

Short-term effects of water deficit on nitrogenase activitywere investigated with hydroponically grown soybean plants (Glycinemax L. Merr. cv. Biloxi) by adding polyethylene glycol (PEG)to the hydroponic solution and measuring nitrogenase activity,nodule respiration, and permeability to oxygen diffusion (P_o).These experiments showed a rapid decrease in acetylene reductionactivity (ARA) and nodule respiration. A consequence of thedecreased respiration rate was that P_o calculated by Fick'sLaw also decreased. However, these results following PEG treatmentwere in direct conflict with a previous report of stabilityin P_o determined by using an alternative technique. To resolvethis conflict, an hypothesis describing a sequence of responsesto the initial PEG treatment is presented. An important findingof this study was that the response to water deficit inducedby PEG occurred in two stages. The first stage of decreasednodule activity was O₂-limited and could be reversed by exposingthe nodules to elevated pO₂. The second stage which developedafter 24 h of exposure to PEG resulted in substantial loss innodule activity and this activity could not be recovered withincreased pO₂. Severe water deficit treatments disrupt noduleactivity to such a degree that O₂ is no longer the major limitation. Key words: Glycine max, N₂ fixation, soybean, oxygen permeability, water deficit     

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.     

Preferential inhibition by ethidium bromide of photosynthetic apparatus formation in Rhodopseudomonas spheroides cells

Ethidium bromide (EB) inhibited growth of cells of the non-sulfurpurple photosynthetic bacterium Rhodopseudomonas spheroides.The inhibitory action of EB on the light-anaerobic culturedcells was stronger than on dark-aerobic cultured ones. EB alsosuppressed the induced synthesis of bacteriochlorophyll (Bchl)and carotenoids in the dark-aerobically grown cells incubatedwith gentle aeration under no-growth conditions, suggestingthat the target of the inhibitory action of EB on the photosyntheticgrowth of R. spheroides cells is chromatophore formation. EBdepressed the incorporation of ³H- or ¹⁴C-uracil into both RNAand DNA fractions from cells incubated with gentle aeration.In contrast, inhibition by EB of ³H-uracil incorporation intothe DNA fraction was not observed under vigorous aeration. Ourfindings seemed to favor the hypothesis described previously(10) that lowering the intracellular oxidation-reduction potentialmight bring about a unique synthesis or turnover of DNA responsiblefor chromatophore formation. (Received December 22, 1977; )     

Quantitative relationship between two reaction centersin the photosynthetic system of blue-green algae

The quantitative relationship between reaction centers I andII was studied with blue-green algae Anabaena cylindrica, Anabaenavariabilis and Anacystis nidulans grown under different lightconditions. The number of reaction centers I was estimated fromthe P700 content and that of reaction centers II, from the O₂yield of repetitive short flashes. Supplementary determinationswere done with three other blue-green algae and one red alga.The maximum number of reaction centers II counted from the O₂yield of repetitive short flashes was markedly smaller thanthe total number of P700 in all algae tested when the algaewere grown under weak light; in the extreme case (Anabaena cylindrica),the ratio was only 0.258?0.015. This ratio became larger andclose to unity when the algae were grown under stronger light.Variation in the number of reaction centers in a single cellsuggested that reaction center I was a variable component. Ourresults indicate that the proportion of the two reaction centersmay markedly vary in blue-green algae depending on the growthconditions (Received November 13, 1978; )     

Physiological and hypoxic O2 tensions rapidly regulate NO production by stimulated macrophages

Nitric oxide (NO) production by inducible NO synthase (iNOS) is dependent on O₂ availability. The duration and degree of hypoxia that limit NO production are poorly defined in cultured cells. To investigate short-term O₂-mediated regulation of NO production, we used a novel forced convection cell culture system to rapidly (response time of 1.6 s) and accurately (±1 Torr) deliver specific O₂ tensions (from <1 to 157 Torr) directly to a monolayer of LPS- and IFN-stimulated RAW 264.7 cells while simultaneously measuring NO production via an electrochemical probe. Decreased O₂ availability rapidly (30 s) and reversibly decreased NO production with an apparent K_mO₂ of 22 (SD 6) Torr (31 µM) and a V_max of 4.9 (SD 0.4) nmol·min^–1·10^–6 cells. To explore potential mechanisms of decreased NO production during hypoxia, we investigated O₂-dependent changes in iNOS protein concentration, iNOS dimerization, and cellular NO consumption. iNOS protein concentration was not affected (P = 0.895). iNOS dimerization appeared to be biphasic [6 Torr (P = 0.008) and 157 Torr (P = 0.258) >36 Torr], but it did not predict NO production. NO consumption was minimal at high O₂ and NO tensions and negligible at low O₂ and NO tensions. These results are consistent with O₂ substrate limitation as a regulatory mechanism during brief hypoxic exposure. The rapid and reversible effects of physiological and pathophysiological O₂ tensions suggest that O₂ tension has the potential to regulate NO production in vivo. inducible nitric oxide synthase; substrate limitation; nitric oxide consumption     

Evidence for the Occurrence of Feedback Inhibition of Photosynthesis in Rice

The response of photosynthesis in the flag leaf of rice (Oryzasativa) to elevated CO₂ or reduced O₂ was investigated relativeto other environmental factors using steady-state gas exchangetechniques. We found under moderate conditions of temperatureand photosynthetic flux density (PFD) (26°C and 700µmolquanta m^–2s^–1 similar to growth conditions) photosynthesisin the flag leaf of rice during heading and grain filling saturatedat near ambient levels of CO₂, with a concomitant loss of O₂sensitivity, when a high stomatal conductance was maintainedby high humidity (low vapor pressure deficit). Under 18°Cthere was near complete loss of O₂ sensitivity of photosynthesisat normal ambient levels of CO₂. This is in contrast to thelarge enhancement of photosynthesis by supra-atmospheric levelsof CO₂ and sub-atmospheric levels of O₂ by suppression of photorespirationwhen there is no limitation on utilizing the initial productof CO₂ assimilation (triose-P) as predicted from Ribulose-l,5-bisphosphatecarboxylase/oxygenase (Rubisco) kinetic properties. Thus, lossof sensitivity to CO₂ and O₂ has been previously explained asa limitation on utilization of triose-P to synthesize carbohydrates.Under high PFD at 25°C, the rate of photosynthesis in ricedeclined over a period of hours around midday, while the intercellularlevels of CO₂ remained constant suggesting a limitation on utilizationof photosynthate. Short-term fluctuations in climatic factorsincluding temperature, light and humidity could result in afeedback limitation on photosynthesis in rice which may be exacerbatedby rising CO₂. (Received March 12, 1998; Accepted May 14, 1998)     

Chlorophyll Metabolism in Higher Plants VI. Involvement of Peroxidase in Chlorophyll Degradation

The following phenolics were found to be essential for peroxidase-dependentchlorophyll bleaching: 2,4-dichlorophenol (DCP), p-coumaricacid (HCA), phenol, p-hydroxyphenylacetic acid, p-hydroxybenzoicacid, p-hydroxyacetophenone, resorcinol and umbelliferone. Mostof them are monophenols with electron-attracting groups at thep-position. The short-lived radicals generated by horseradishperoxidase (HRP)-phenolics-H₂O₂ reaction might be involved inthis reaction. Tobacco leaf enzyme preparation with peroxidaseactivity for guaiacol could also degrade chlorophyll with suchphenolics. In addition, tobacco leaf methanol extract couldsubstitute for chlorophyll bleaching as an electron donor inthe absence of phenolics. In place of free H₂O₂, the glycolate-glycolateoxidase (GOX) system could degrade chlorophyll in [peroxidase$phenolics]-dependentbleaching. This chlorophyll bleaching system was inhibited by peroxidaseinhibitors, radical scavengers, reducing reagents, and carotenoids.Ascorbate and glutathione stopped chlorophyll bleaching withGSSG reductase and NADPH. The role of ascorbate and glutathionein peroxidase activity for controlling the chlorophyll degradationrate is discussed. (Received January 28, 1985; Accepted July 23, 1985)     

Biosynthesis of Anthraquinone by Cells of Galium mollugo L. Grown in a Chemostat with Limiting Sucrose or Phosphate

Growth and anthraquinone biosynthesis by Galium cells were examinedin steady-state substrate-limited conditions using a chemostatcontinuous culture technique. Steady-state growth was obtainedin both sucrose- and phosphate-limiting conditions for periodsup to 60 d. In sucrose-limiting conditions three growth rateswere investigated with doubling times (t_d) of 25 h, 35 h and40 h, and phosphate-limited growth was obtained at t_d= 35 h.The kinetics of the growth response to a change in limitingsubstrate concentration in sucrose-limiting conditions was examinedand found to follow closely that predicted by the applicationof Monod's (1950) model obtained for micro-organisms. The anthraquinone content of cells grown in phosphate and sucroselimitation was uniformly similar and at a relatively low level(0.68 mg g^–1 dry wt.). When the substrate limitation wasrelieved by the addition of the limiting substrate, either phosphate,or sucrose, anthraquinone synthesis was markedly stimulated.The addition of the anthraquinone precursor, orthosuccinyl benzoicacid (OSB) greatly enhanced anthraquinone synthesis in phosphate-limitingconditions but not in sucrose-limited cells. The results show that growth limitation by phosphate and bysucrose causes a suppression of the rate of synthesis of thesecondary metabolite anthraquinone in Galium cells and suggeststhat the metabolic point of suppression is different in eachcase. Key words: Anthraquinone biosynthesis, Galium, Continuous culture, recursor feeding     

Limitation to Photosynthesis in Water-stressed Leaves: Stomata vs. Metabolism and the Role of ATP

Decreasing relative water content (RWC) of leaves progressivelydecreases stomatal conductance (g_s), slowing CO₂ assimilation(A) which eventually stops, after which CO₂ is evolved. In somestudies, photosynthetic potential (A_pot), measured under saturatingCO₂, is unaffected by a small loss of RWC but becomes progressivelymore inhibited, and less stimulated by elevated CO₂, below athreshold RWC (Type 1 response). In other studies, A_pot andthe stimulation of A by elevated CO₂ decreases progressivelyas RWC falls (Type 2 response). Decreased A_pot is caused byimpaired metabolism. Consequently, as RWC declines, the relativelimitation of A by g_s decreases, and metabolic limitation increases.Causes of decreased A_pot are considered. Limitation of ribulosebisphosphate (RuBP) synthesis is the likely cause of decreasedA_pot at low RWC, not inhibition or loss of photosynthetic carbonreduction cycle enzymes, including RuBP carboxylase/oxygenase(Rubisco). Limitation of RuBP synthesis is probably caused byinhibition of ATP synthesis, due to progressive inactivationor loss of Coupling Factor resulting from increasing ionic (Mg²⁺)concentration, not to reduced capacity for electron or protontransport, or inadequate trans-thylakoid proton gradient (pH).Inhibition of A_pot by accumulation of assimilates or inadequateinorganic phosphate is not considered significant. DecreasedATP content and imbalance with reductant status affect cellmetabolism substantially: possible consequences are discussedwith reference to accumulation of amino acids and alterationsin protein complement under water stress.     

Model for the Relationships betweenCO2-Concentrating Mechanism, CO2 Fixation, and Glycolate Synthesis during Photosynthesis in Chlamydomonas reinhardtii

We constructed a mathematical model for simulating the relationshipsof extracellular concentration of dissolved inorganic carbon(DIC), the rates of photosynthetic CO₂ fixation and glycolatesynthesis, and the concentrations of intrachloroplast CO₂ andO₂ in Chlamydomonas reinhardtii. When we compared the photosyntheticrates of I0W-CO₂ (air)-grown C. reinhardtii measured experimentallyand the rates simulated with the incubation conditions in themodel, the model was found to function well. The calculatedrates for glycolate synthesis also matched the measured ratesbetween 80 to 200 µM extracellular DIC, found in the presenceof 1 mM aminooxyacetate. The conformity of the calculated ratesto the measured ones of the glycolate synthesis encouraged usto estimate the O₂ concentration at the active site of ribulosebisphosphate carboxylase/oxygenase; the results were 0.36 and0.40 mM at 80 and 200 µM extracellular DIC, respectively.These high concentrations of O₂ were due to stimulation of photosyntheticCO₂ fixation and further O₂ evolution by a CO₂- concentratingmechanism in the low-CO₂-grown cells. These cells were calculatedto consume 43% of ATP formed photosynthetically for CO₂ concentrationat 200 µM extracellular DIC. The model modified to simulatethese relationships in high-CO₂ (3 to 5% CO₂)-grown C. reinhardtiipredicted O₂ concentration in chloroplasts to be 0.36 mM ina 1% CO₂ atmosphere. This high concentration of O₂ caused activeglycolate synthesis at the measured rate in the high-CO₂-growncells even in the presence of 1% CO₂. The comparisons of themeasured and simulated rates of photosynthesis in low- and high-CO₂-grownC. reinhardtii indicated that no matter how the CO₂ accumulatedin the chloroplasts, it increased the O₂ concentration in theorganelles, and consequently enhanced glycolate synthesis. ¹This paper is the twenty-first in a series on glycolate metabolismin Euglena gracilis. (Received March 11, 1987; Accepted August 17, 1987)