Effect of Glyoxylate on the Sensitivity of Net Photosynthesis to Oxygen (the Warburg Effect) in Tobacco

The addition of glyoxylate to tobacco (Nicotiana tabacum) leaf discs inhibited glycolate synthesis and photorespiration and increased net photosynthetic ¹⁴CO₂ fixation. This inhibition of photorespiration was investigated further by studying the effect of glyoxylate on the stimulation of photosynthesis that occurs when the atmospheric O₂ level was decreased from 21 to 3% (the Warburg effect). The Warburg effect is usually ascribed to the increased glycolate synthesis and metabolism that occurs at higher O₂ concentrations. Photosynthesis in control discs increased from 59.1 to 94.7 micromoles of CO₂ per gram fresh weight per hour (a 60% increase) when the O₂ level was lowered from 21 to 3%, while the rate for discs floated on 15 millimolar glyoxylate increased only from 82.0 to 99.7 micromoles of CO₂ per gram fresh weight per hour (a 22% increase). The decrease in the O₂ sensitivity of photosynthesis in the presence of glyoxylate was explained by changes in the rate of glycolate synthesis under the same conditions.

The rate of metabolism of the added glyoxylate by tobacco leaf discs was about 1.35 micromoles per gram fresh weight per hour and was not dependent on the O₂ concentration in the atmosphere. This rate of metabolism is about 10% the amount of stimulation in the rate of CO₂ fixation caused by the glyoxylate treatment on a molar carbon basis. Glyoxylate (10 millimolar) had no effect on the carboxylase/oxygenase activity of isolated ribulose diphosphate carboxylase. Although the biochemical mechanism by which glyoxylate inhibits glycolate synthesis and photorespiration and thereby decreases the Warburg effect is still uncertain, these results show that cellular metabolites can regulate the extent of the Warburg effect.

     

Chloroplastic photorespiratory bypass increases photosynthesis and biomass production in Arabidopsis thaliana

We introduced the Escherichia coli glycolate catabolic pathway into Arabidopsis thaliana chloroplasts to reduce the loss of fixed carbon and nitrogen that occurs in C(3) plants when phosphoglycolate, an inevitable by-product of photosynthesis, is recycled by photorespiration. Using step-wise nuclear transformation with five chloroplast-targeted bacterial genes encoding glycolate dehydrogenase, glyoxylate carboligase and tartronic semialdehyde reductase, we generated plants in which chloroplastic glycolate is converted directly to glycerate. This reduces, but does not eliminate, flux of photorespiratory metabolites through peroxisomes and mitochondria. Transgenic plants grew faster, produced more shoot and root biomass, and contained more soluble sugars, reflecting reduced photorespiration and enhanced photosynthesis that correlated with an increased chloroplastic CO(2) concentration in the vicinity of ribulose-1,5-bisphosphate carboxylase/oxygenase. These effects are evident after overexpression of the three subunits of glycolate dehydrogenase, but enhanced by introducing the complete bacterial glycolate catabolic pathway. Diverting chloroplastic glycolate from photorespiration may improve the productivity of crops with C(3) photosynthesis.     

Influence of glycerate on photosynthesis by wheat chloroplasts

Glycerate was found to effect photosynthetic O2 evolution in wheat chloroplasts by its conversion to triose phosphate and by influencing the rate of photosynthesis through the reductive pentose phosphate pathway. In the absence of bicarbonate, the photosynthetic O2 evolution with glycerate was low (10 to 25 mumol mg chlorophyll-1 h-1), and only about 15% of the rate of bicarbonate-dependent O2 evolution under optimum conditions. This corresponds to a rate of glycerate conversion to triose phosphate of 20 to 50 mumol mg chlorophyll-1 h-1, which appears sufficient to accommodate flux through the glycolate pathway in vivo. Pi was required for this glycerate-dependent O2 evolution; rates remained relatively constant between 0.1 and 40 mM Pi, and proceeded with little lag upon illumination (less than 0.5 min). Evidence for O2 evolution due to glycerate conversion to triose phosphate could be conclusively demonstrated by addition of glycolaldehyde, an inhibitor of the regenerative phase of photosynthesis, which prevents CO2 fixation. The effect of glycerate on photosynthesis in the presence of bicarbonate was determined by measuring both photosynthetic O2 evolution and 14CO2 fixation at varying Pi concentrations. Low concentrations of glycerate (micro- to millimolar levels) prevented inhibition of photosynthesis by Pi. With 1 mM bicarbonate and pH 8.2, which is favorable for glycolate synthesis, maximum rates of photosynthesis were obtained at low Pi (25 microM), whereas strong inhibition of photosynthesis occurred at only 0.2 mM Pi. Addition of glycerate relieved the inhibition of photosynthesis by Pi, indicating the possible importance of glycerate metabolism in the chloroplast under photorespiratory conditions. The initiation of photosynthesis by glycerate at inhibitory Pi levels occurred with little reduction in the ratio of CO2 fixed/O2 evolved, and the main effect of glycerate was on carbon assimilation. While the basis for the beneficial effect of glycerate on CO2 assimilation under moderate to high Pi levels is uncertain, it may increase the concentration of 3-phosphoglycerate (PGA) in the chloroplast, and thus make conditions more favorable for induction of photosynthesis and reduction of PGA to triose phosphate.     

High glycolate oxidase activity is required for survival of maize in normal air

A mutant in the maize (Zea mays) Glycolate Oxidase1 (GO1) gene was characterized to investigate the role of photorespiration in C4 photosynthesis. An Activator-induced allele of GO1 conditioned a seedling lethal phenotype when homozygous and had 5% to 10% of wild-type GO activity. Growth of seedlings in high CO2 (1%-5%) was sufficient to rescue the mutant phenotype. Upon transfer to normal air, the go1 mutant became necrotic within 7 d and plants died within 15 d. Providing [1-14C]glycolate to leaf tissue of go1 mutants in darkness confirmed that the substrate is inefficiently converted to 14CO2, but both wild-type and GO-deficient mutant seedlings metabolized [1-14C]glycine similarly to produce [14C]serine and 14CO2 in a 1:1 ratio, suggesting that the photorespiratory pathway is otherwise normal in the mutant. The net CO2 assimilation rate in wild-type leaves was only slightly inhibited in 50% O2 in high light but decreased rapidly and linearly with time in leaves with low GO. When go1 mutants were shifted from high CO2 to air in light, they accumulated glycolate linearly for 6 h to levels 7-fold higher than wild type and 11-fold higher after 25 h. These studies show that C4 photosynthesis in maize is dependent on photorespiration throughout seedling development and support the view that the carbon oxidation pathway evolved to prevent accumulation of toxic glycolate.     

14CO2 fixation and glycolate metabolism in the dark in isolated maize (Zea mays L.) bundle sheath strands

Bundle sheath strands capable of assimilating up to 68 μmoles CO₂ per mg chlorophyll per hr in the dark have been isolated from fully expanded leaves of Zea mays L. This dark CO₂-fixing system is dependent on exogenous ribose-5-phosphate, ADP or ATP, and Mg²⁺ for maximum activity. The principal product of dark fixation in this system is 3-phosphoglycerate, indicating that the CO₂-fixing reaction is mediated by ribulose-1,5-bisphosphate carboxylase (EC 4.1.1.39). The rate of dark CO₂ uptake in the strands in the presence of saturating levels of ribose-5-phosphate plus ADP is inhibited by oxygen. The inhibitory effect of oxygen is rapidly and completely reversible, and is relieved by increased levels of CO₂. Glycolate is synthesized in this dark system in the presence of [U-¹⁴C]ribose-5-phosphate, ADP, oxygen, and an inhibitor of glycolate oxidase (EC 1.1.3.1). Glycolate formation is completely abolished by heating the strands, and the rate of glycolate synthesis is markedly reduced by either lowering the oxygen tension or increasing the level of CO₂.These results, obtained with intact cells in the absence of light, indicate that the direct inhibitory effect of oxygen on photosynthesis is associated with photosynthetic carbon metabolism, probably at the level of ribulose-1,5-bisphosphate carboxylase, and not with photophosphorylation or photosynthetic electron transport. Furthermore, the findings indicate that the synthesis of glycolate from exogenous substrate can readily occur in the absence of photosynthetic electron transport, an observation consistent with the ribulose-1, 5-bisphosphate “oxygenase” scheme for glycolate formation during photosynthesis.     

A study of the control of glycolate excretion in chlorella

Chlorella pyrenoidosa cells grown on 5% CO(2) excreted glycolate when incubated in light with 10 mm bicarbonate, but excreted no glycolate under the same conditions when they were maintained on air for 7 hours prior to the assay. Incubation of 5% CO(2)-grown and air-grown cells with 10 mm isonicotinyl hydrazide or 10 mm alpha-hydroxypyridinemethane sulfonate during the assay stimulated the excretion of glycolate by CO(2)-grown cells severalfold that of air-grown cells.Adaptation of CO(2)-grown Chlorella to growth on air did not affect the levels of glycolate dehydrogenase in the cells and did not affect the rate of dark oxidation and metabolism of exogeneous (14)C-glycolate by the cells. These results indicate that the lack of glycolate excretion by air-grown or air-adapted cells of Chlorella cannot be explained by a concomitant change in the level of glycolate dehydrogenase.     

Plasmid construction for genetic modification of dicotyledonous plants with a glycolate oxidizing pathway

There are many kinds of dicotyledonous C(3) plants, which often release CO(2) fixed by photosynthesis and consume energy in photorespiration. In Escherichia coli, glycolate can be metabolized by an oxidation pathway that has some of the same compounds as dicotyledonous photorespiration. With the bacterial glycolate metabolism pathway, photorespiration of dicotyledonous plants is genetically modified for less CO(2) release and more biomass. In this study, two plasmids involved in this modification were constructed for targeting two enzymes of the glycolate oxidizing pathway, glyoxylate carboligase and tartronic semialdehyde reductase, and glycolate dehydrogenase in Arabidopsis thaliana mitochondria in this pathway. All three enzymes are located in chloroplast by transit peptide derived from Pisum sativum small unit of Rubisco. So far, some crops have been transformed by the two plasmids. Through transformation of the two plasmids, photosynthesis of dicotyledonous plants may be promoted more easily and release less CO(2) into the atmosphere.     

光呼吸代谢物乙醇酸、乙醛酸和草酸对烟草叶片硝酸还原的影响

乙醇酸、乙醛酸和草酸能明显促进烟草(Nicotiana rustica)叶片在黑暗中的硝酸还原,光呼吸抑制剂a-羟基吡啶甲烷磺酸能消除前二者的促进作用而不能完全消除草酸的作用。草酸+NAD~+能显著促进离体的硝酸还原。烟叶提取液加入草酸和NAD~+后生成NADH和CO_2认为活体内由乙醛酸氧化生成的草酸是经脱氢生成NADH供硝酸还原之用。未能证明在烟叶内存在乙醇酸脱氨酶,因此排除由乙醇酸直接脱氢以还原硝酸的可能。     

Glycolate metabolism in algal chloroplasts: inhibition by salicylhydroxamic acid (SHAM)

Unicellular green algae such as Chlamydomonas and Dunaliella excrete small amounts of glycolate during active photosynthesis. This phenomenon has been explained by the fact that these algae do not have leaf-type peroxisomes and glycolate oxidase; instead, they have a limited capacity to metabolise glycolate in their mitochondria by a membrane-associated glycolate dehydrogenase. Salicylhydroxamic acid (SHAM), an inhibitor of alternative oxidase in plant and algal mitochondria, stimulates glycolate excretion by the algae or their isolated chloroplasts 5-fold. In the presence of SHAM, cells of Chlamydomonas or Dunaliella grown with high-CO₂ (5% CO₂ in air, v/v) or adapted with air levels of CO₂ excreted glycolate at a rate of about 14 µmol glycolate mg⁻¹ Chl h⁻¹. Aminooxyacetate (AOA), an inhibitor of aminotransferases, also increases glycolate excretion by the algal cells or chloroplasts but at a lower rate (about 50%) than SHAM. The algal, light dependent, SHAM-sensitive glycolate oxidizing system in the chloroplasts appears to be the primary site for glycolate oxidation, and it is different and more active then the minor mitochondrial glycolate dehydrogenase.     

Effect of glycidate on glycolate formation and photosynthesis in isolated spinach chloroplasts

Glycidate (2,3-epoxypropionate) increased CO₂ photoassimilation in intact spinach (Spinacia oleracea L.) chloroplasts in the presence of various inhibitors of photosynthesis, including O₂, arsenite, azide, iodo-acetamide, and carbonylcyanide 3-chlorophenylhydrazone. Although the mechanism by which glycidate enhances photosynthesis is obscure, the stimulatory effect cannot be ascribed to either an inhibition of glycolate formation, a specific interaction with the O₂ inhibition of photosynthesis, or a direct effect on the ribulose 1,5-bisphosphate carboxylase (EC 4.1.1.39) reaction. The lack of a differential effect of glycidate on photosynthesis and glycolate formation in the isolated chloroplast was confirmed in whole leaf studies by the CO₂ compensation concentration assay. These results are at variance with the report that glycidate stimulates net photosynthesis in tobacco leaf disks by irreversibly inhibiting glycolate formation and thus photorespiration (Zelitch, I., 1974, Arch. Biochem. Biophys. 163: 367-377).     

The relationship between photosynthetic electron transport and photorespiratory 14CO2 release after DCMU treatment in the duckweed, Lemna gibba

The photosynthetic rate of Lemna gibba was measured as ¹⁴CO₂ uptake at the beginning of and after 1 h DCMU treatment during the separate excitation of PS I (703 nm), mainly PS II (662 nm) and the combined excitation of both photosystems (662 + 703 nm) in 2 and 21% oxygen. The results show the Warburg effect. Photosynthesis was significantly reduced by DCMU whenever PS II was excited, at 662 nm and 662 + 703 nm. Photosynthetic enhancement was greater in 21 than in 2% oxygen in both the treated and untreated plants.
Photorespiratory ¹⁴CO₂ release was only affected by DCMU treatment at 662 + 703 nm. It was significantly decreased in 21% O₂ and significantly increased in 2% O₂ as compared to the controls without DCMU. The ¹⁴C-glycolate remaining in the plant after photosynthesis/photorespiration measurements was reduced whenever the electron supply to PS I was low.
These data support the hypothesis that a relationship exists between glycolate metabolism and photosynthesis via the electron transport chain where electrons from the oxidation of glycolate are donated to PS I when the electron supply from water is low.     

CO2-Fixation, Glycolate Formation, and Enzyme Activities of Photorespiration and Photosynthesis during Greening and Senescence of Sunflower Cotyledons

Time-courses of ¹⁴CO₂-fixation and of enzyme activities involvedin photorespiration and photosynthesis were determined duringthe life span of cotyledons from sunflower seedlings (Helianthusannuus L.). Glycolate formation in vivo was estimated from theresults of combined labelling and inhibitor experiments. NADPH-glyceraldehyde-3-phosphatedehydrogenase, NADPH-glyoxylate reductase and chlorophyll werewell correlated with the time-course of ¹⁴CO₂-fixation (photosynthesis).There was, however, a considerable discrepancy between the developmentalsequence of photosynthesis and that of both ribulose-l,5-bisphosphatecarboxylase and glycolate oxidase. Furthermore, time-coursesof glycolate oxidase activity in vitro and of glycolate formationin vivo differed significantly. Therefore, the use of glycolateoxidase as a marker for the activity of photorespiration ingreening sunflower cotyledons may be questionable. Results from¹⁴CO₂-labelling experiments with cotyledons treated with theglycolate oxidase inhibitor 2-hydroxy butynoic acid suggestthat glycolate formation relative to CO₂-fixation is reducedin senescent cotyledons. Key words: Development, glycolate oxidase, photorespiration, ribulose-l,5-bisphosphate carboxylase, oxygenase     

Reduction of oxygen by the electron transport chain of chloroplasts during assimilation of carbon dioxide.

In photosynthetically competent chloroplasts from spinach the quantum requirements for oxygen evolution during CO2 reduction were higher, by a factor often close to 1.5, than for oxygen evolution during reduction of phosphoglycerate. Mass spectrometer experiments performed under rate-limiting light indicated that an oxygen-reducing photoreaction was responsible for the consumption of extra quanta during carbon dioxide assimilation. Uptake of 18O2 during reduction of CO2 was considerably higher than could be accounted for by oxygen consumption during glycolate formation and by the Mehler reaction of broken chloroplasts which were present in the preparations of intact chloroplasts. The oxygen reducing reaction occurring during CO2 assimilation resulted in the formation of H2O2. This was indicated by a large stimulation of CO2 reduction by catalase, but not of phosphoglycerate reduction. Catalase could be replaced as a stimulant of photosynthesis by dithiothreitol or ascorbate, compounds known to react with superoxide radicals. There was no effect of dithiothreitol and ascorbate on phosphoglycerate reduction. A main effect of superoxide radicals and/or H2O2 was shown to be at the level of phosphoglycerate formation. Evidence for electron transport of oxygen was also obtained from 14CO2 experiments. The oxidation of dihydroxyacetonephosphate during a dark period or after addition of carbonyl cyanide p-trifluoromethoxyphenyl-hydrazone in the light was studied. The results indicated a link between the chloroplast pyridine nucleotide system and oxygen. Oxygen reduction during photosynthesis under conditions where light is rate limiting is seen as important in supplying the ATP which is needed for CO2 reduction but is not provided during electron transport to NADP. A mechanism is discussed which would permit proper distribution of electrons between CO2 and oxygen during photosynthesis.     

Identification of genes required for recycling reducing power during photosynthetic growth

Photosynthetic organisms have the unique ability to transform light energy into reducing power. We study the requirements for photosynthesis in the alpha-proteobacterium Rhodobacter sphaeroides. Global gene expression analysis found that approximately 50 uncharacterized genes were regulated by changes in light intensity and O\2 tension, similar to the expression of genes known to be required for photosynthetic growth of this bacterium. These uncharacterized genes included RSP4157 to -4159, which appeared to be cotranscribed and map to plasmid P004. A mutant containing a polar insertion in RSP4157, CT01, was able to grow via photosynthesis under autotrophic conditions using H2 as an electron donor and CO2 as a carbon source. However, CT01 was unable to grow photoheterotrophically in a succinate-based medium unless compounds that could be used to recycle reducing power (the external electron acceptor dimethyl sulfoxide (DMSO) or CO2 were provided. This suggests that the insertion in RSP4157 caused a defect in recycling reducing power during photosynthetic growth when a fixed carbon source was present. CT01 had decreased levels of RNA for genes encoding putative glycolate degradation functions. We found that exogenous glycolate also rescued photoheterotrophic growth of CT01, leading us to propose that CO2 produced from glycolate metabolism can be used by the Calvin cycle to recycle reducing power generated in the photosynthetic apparatus. The ability of glycolate, CO2, or DMSO to support photoheterotrophic growth of CT01 suggests that one or more products of RSP4157 to -4159 serve a previously unknown role in recycling reducing power under photosynthetic conditions.     

Rates of synthesis and source of glycolate in intact chloroplasts

Summary Intact chloroplasts capable of high rates of CO₂ assimilation completely oxidized 3-phosphoglycerate and dihydroxyacetone phosphate to glycolate when CO₂ concentrations were low. Bicarbonate was converted first into products of the Calvin cycle and then into glycolate. Under high oxygen and at high pH values CO₂ fixation and glycolate formation ceased before bicarbonate was exhausted. This is interpreted as the consequence of a depletion of ribulose diphosphate (RuDP) at the oxygen compensation point, where oxygen consumption by glycolate formation and oxygen evolution by phosphoglycerate reduction balance each other. Depletion of RuDP by glycolate formation is proposed to play a role in the Warburg effect. The maximum rate of glycolate synthesis observed with dihydroxyacetone phosphate as substrate was 35 mol mg^-1 chlorophyll h^-1 at 20°C. This may not reflect the maximum capacity of chloroplasts for glycolate synthesis. Dithiothreitol and catalase, which prevent accumulation of oxygen radicals or H₂O₂ during carbon assimilation, increased glycolate formation. H₂O₂ was inhibitory. Other inhibitors of glycolate formation were glyceraldehyde and carbonylcyanide p-trifluoro-methoxphenylhydrazone. From the sensitivity of glycolate synthesis to uncoupling and the ATP requirement of RuDP formation it is concluded that glycolate originated from RuDP. Different induction periods of carbon fixation and glycolyte formation suggested that glycolate synthesis is not only regulated by the ratio of oxygen to CO₂ but also by another factor.     

The stoichiometry of photorespiration during C3-photosynthesis is not fixed: evidence from combined physical and stereochemical methods

The stoichiometry of photorespiration, S, is defined as the fraction of glycolate carbon photorespired. It is postulated that under steady-state conditions there are two determinants of the ratio of photorespiration to net photosynthesis: the partitioning of ribulose bisphosphate between oxidation and carboxylation, and the partitioning of glycolate between reactions leading to complete oxidation to CO2 (S = 100%) and those yielding CO2 plus serine (S = 25%). S may be calculated using two independent probes of the system. The physical probe, using an infrared gas analyzer, measured photorespiration and net photosynthesis, and hence their ratio PR/NPS = pn(phys). The metabolic probe employed tracer (3R)-D-[3-3H1,3-14C]glyceric acid to determine r, the fraction of 3H retained in the triose phosphates leaving the chloroplasts. It is deduced from the postulated model that S = pn(phys) . r/(1 - r). Experiments have been performed with illuminated tobacco leaf discs (inverted) under varying concentrations of O2 and CO2. Increasing O2 at constant CO2 increased pn(phys) and decreased r, whereas increasing CO2 at constant O2 had the opposite effect. S more than doubled at 32 degrees C on going from 16 to 40% O2 (340 microliters CO2/liter) and decreased 40% on going from 200 to 700 microliters CO2/liter (21% O2). For discs in normal air S was somewhat greater than 27%. It is suggested that net photosynthesis, and therefore crop yields, could be increased by selecting for crop plants with reduced photorespiration stoichiometry.     

Effects of aminoacetonitrile on net photosynthesis, ribulose-1,5-bisphosphate levels, and glycolate pathway intermediates

The effects of aminoacetonitrile (a competitive inhibitor of glycine oxidation) on net photosynthesis, glycolate pathway intermediates, and ribulose-1,5-bisphosphate (RuBP) levels have been investigated at different O₂ and CO₂ concentrations with soybean (Glycine max)[L] Merr. cv Pioneer 1677) leaf discs floated on 25 millimolar aminoacetonitrile (AAN) for 50 minutes prior to assay.

At 2% O₂ and 200 or 330 microliters per liter CO₂, the inhibitor had no effect on the rate of net photosynthesis and RuBP levels when compared with the control levels. At 11% to 60% O₂, AAN caused a decrease in net photosynthesis in addition to the inhibition by O₂. This extra inhibition ranged from 22% to 59% depending on the O₂ and CO₂ concentrations. The levels of RuBP, however, were 1.3 to 2.7 times higher than in the control plants at the same O₂ concentrations. At 40% O₂ and 200 microliters per liter CO₂, the inhibitor caused a 6-fold increase in glycine and more than 2-fold increase in glyoxylate levels, whereas those of glycolate decreased by approximately one-half.

The decrease in net photosynthesis observed with AAN is not the result of the depletion of the RuBP pool due to the lack of recycling of carbon from the glycolate pathway to the Calvin cycle. The higher levels of RuBP caused by AAN in photorespiratory conditions, suggest that RuBP carboxylase was inhibited. Glyoxylate could be a possible candidate for the inhibition of the enzyme but what is known so far about its inhibitory properties in vitro may not fit the existing in vivo conditions. An alternative explanation for the inhibition is proposed.

     

Enzymic formation of glycolate in Chromatium. Role of superoxide radical in a transketolase-type mechanism.

Chromatophores prepared from Chromatium exhibit a light-dependent O2 uptake in the presence of reduced 2,6-dichlorophenolindophenol, the maximum rate observed being 10.8 micronmol (mg of Bchl)-1 h-1 (air-saturated condition). As it was found that the uptake of O2 was markedly inhibited by superoxide dismutase, it is suggested that molecular oxygen is subject to light-dependent monovalent reduction, resulting in the formation of the superoxide anion radical (O2-). By coupling baker's yeast transketolase with illuminated chromatophore preparations, it was demonstrated that [U-14C]-fructose 6-phosphate (6-P) is oxidatively split to produce glycolate, and that the reaction was markedly inhibited by superoxide dismutase and less strongly by catalase. A coupled system containing yeast transketolase and xanthine plus xanthine oxidase showed a similar oxidative formation of glycolate from [U-14C] fructose 6-P. It is thus suggested that photogenerated O2- serves as an oxidant in the transketolase-catalyzed formation of glycolate from the alpha, beta-dihydroxyethyl (C2) thiamine pyrophosphate complex, whereas H2O2 is not an efficient oxidant. The rate of glycolate formation in vitro utilizing O2- does not account for the in vivo rate of glycolate photosynthesis in Chromatium cells exposed to an O2 atmosphere (10 micronmol (mg of Bchl)-1 h-1). However, the enhancement of glycolate formation by the autoxidizable electron acceptor methyl viologen in Chromatium cells in O2, as well as the strong suppression by 1,2-dihydroxybenzene-3,5-disulfonic acid (Tiron), an O2- scavenger, suggest that O2- is involved in the light-dependent formation of glycolate in vivo.     

Chemical inhibition of the glycolate pathway in soybean leaf cells

Isolated soybean (Glycine max [L.] Merr.) leaf cells were treated with three inhibitors of the glycolate pathway in order to evaluate the potential of such inhibitors for increasing photosynthetic efficiency. Preincubation of cells under acid conditions in α-hydroxypyridinemethanesulfonic acid increased ¹⁴CO₂ incorporation into glycolate, but severely inhibited photosynthesis. Isonicotinic acid hydrazide (INH) increased the incorporation of ¹⁴CO₂ into glycine and reduced label in serine, glycerate, and starch. Butyl 2-hydroxy-3-butynoate (BHB) completely and irreversibly inhibited glycolate oxidase and increased the accumulation of ¹⁴C into glycolate. Concomitant with glycolate accumulation was the reduction of label in serine, glycerate, and starch, and the elimination of label in glycine. The inhibitors INH and BHB did not eliminate serine synthesis, suggesting that some serine is synthesized by an alternate pathway. The per cent incorporation of ¹⁴CO₂ into glycolate by BHB-treated cells or glycine by INH-treated cells was determined by the O₂/CO₂ ratio present during assay. Photosynthesis rate was not affected by INH or BHB in the absence of O₂, but these compounds increased the O₂ inhibition of photosynthesis. This finding suggests that the function of the photorespiratory pathway is to recycle glycolate carbon back into the Calvin cycle, so if glycolate metabolism is inhibited, Calvin cycle intermediates become depleted and photosynthesis is decreased. Thus, chemicals which inhibit glycolate metabolism do not reduce photorespiration and increase photosynthetic efficiency, but rather exacerbate the problem of photorespiration.     

The Effect of DCMU (3-(3,4-dichlorophenyl)-1,1-dimethylurea) on Photosynthesis, Glycolate Excretion ('Photorespiration') and Amino Acid Metabolism in the Blue-Green Alga Anacystis

When photosynthesis of the blue-green alga Anacystis nidulans was measured as ¹⁴CO₂-fixation, the inhibitory effect of DCMU at low concentrations was greatest when mainly Photosystem 1 (PS 1) (excitation at 446 or 687 nm) was operative. At concentrations above 10-⁶M the inhibition on ¹⁴CO₂-fixation was greatest when mainly Photosystem 2 (PS 2) was operative (excitation at 619). During excitation of PS 1, the excretion of glycolate was stimulated at low concentrations of DCMU (5 × 10^-8M and lower), while higher concentrations inhibited excretion. All concentrations of DCMU inhibited glycolate excretion when mainly PS 2 was excited. The curves showing the relative effect of DCMU on the two photosystems, measured as PS 1/PS 2, had opposite shapes for ¹⁴CO₂-fixation and glycolate excretion. An increase in ¹⁴CO₂-fixation coincided with a decrease in glycolate excretion and vice versa. It appears that the increased rate of photosynthesis when mainly PS 1 was operative relative to that when mainly PS 2 was excited, increases the consumption of glycolate in an oxidation process associated with the excitation of PS 1, resulting in less excretion of glycolate to the medium. The influence of DCMU inhibition on labelled amino acid pools connected to the glycolate pathway (glycine-serine) is quite similar to that for ¹⁴CO₂-fixation. At concentrations below 10^-6M DCMU, inhibition of ¹⁴CO₂- incorporation into the amino acids was greatest when PS 1 was excited, while at the higher concentrations tested, inhibition was greater when PS 2 was excited. We conclude that the metabolism of glycine and serine is closely connected to the rate of photosynthesis.