Effects of glycine hydroxamate, carbon dioxide, and oxygen on photorespiratory carbon and nitrogen metabolism in spinach mesophyll cells

The effects of added glycine hydroxamate on the photosynthetic incorporation of ¹⁴CO₂ into metabolites by isolated mesophyll cells of spinach (Spinacia oleracea L.) was investigated under conditions favorable to photorespiratory (PR) metabolism (0.04% CO₂ and 20% O₂) and under conditions leading to nonphotorespiratory (NPR) metabolism (0.2% CO₂ and 2.7% O₂). Glycine hydroxamate (GH) is a competitive inhibitor of the photorespiratory conversion of glycine to serine, CO₂ and NH₄⁺. During PR fixation, addition of the inhibitor increased glycine and decreased glutamine labeling. In contrast, labeling of glycine decreased under NPR conditions. This suggests that when the rate of glycolate synthesis is slow, the primary route of glycine synthesis is through serine rather than from glycolate. GH addition increased serine labeling under PR conditions but not under NPR conditions. This increase in serine labeling at a time when glycine to serine conversion is partially blocked by the inhibitor may be due to serine accumulation via the “reverse” flow of photorespiration from 3-P-glycerate to hydroxypyruvate when glycine levels are high. GH increased glyoxylate and decreased glycolate labeling. These observations are discussed with respect to possible glyoxylate feedback inhibition of photorespiration.     

Incorporation of Oxygen into Glycolate, Glycine, and Serine during Photorespiration in Maize Leaves

Glycolate, glycine, and serine extracted from excised Zea mays L. leaves which had been allowed to photosynthesize in the presence of ¹⁸O₂ were analyzed by gas chromatography-mass spectrometry. In each case, only one of the oxygen atoms of the carboxyl group had become labeled. The maximum enrichment observed in glycine and serine was attained after 5 minutes and 15 minutes of exposure to ¹⁸O₂ at the CO₂ compensation point; the labeling was very high, reaching 70 to 73% of that in the applied O₂. Thus, it appears that all or nearly all of the glycine and serine are synthesized in maize leaves via fixation of O₂. In the presence of CO₂ (380 or 800 microliters per liter), ¹⁸O-labeling was markedly slower.

Glycolate enrichment was variable and much lower than that in glycine and serine. It is possible that there are additional pathways of glycolate synthesis which do not result in the incorporation of ¹⁸O from molecular oxygen. An estimation of the metabolic flow of O₂ through the photorespiratory cycle was made. It appeared that less than 75% of the O₂ taken up by maize leaves is involved in this pathway. Therefore, other processes of O₂ metabolism must occur in the light.

     

Impairment of Photorespiratory Carbon Flow into Rubber by the Inhibition of the Glycolate Pathway in Guayule (Parthenium argentatum Gray)

Cut shoots of guayule (Parthenium argentatum Gray) were treated with four inhibitors of the glycolate pathway (α-hydroxypyridinemethanesulfonic acid; isonicotinic acid hydrazide, glycine hydroxamate, and amino-oxyacetate, AOA) in order to evaluate the role of photorespiratory intermediates in providing precursors for the biosynthesis of rubber. Photorespiratory CO₂ evolution in guayule leaves was severely inhibited by AOA. Application of each of the four inhibitors has resulted in a significantly decreased incorporation of ¹⁴C into rubber fractions suggesting that the glycolate pathway is involved in the biosynthesis of rubber in guayule. However, the application of each of the glycolate pathway inhibitors showed no significant effect on photosynthetic CO₂ fixation in the leaves. The inhibitors individually also reduced the incorporation of labeled glycolate, glyoxylate, and glycine into rubber, while the incorporation of serine and pyruvate was not affected. The effective inhibition of incorporation of glycolate pathway intermediates in the presence of AOA was due to an inhibition of glycine decarboxylase and serine hydroxymethyltransferase. It is concluded that serine is a putative photorespiratory intermediate in the biosynthesis of rubber via pyruvate and acetyl coenzyme A.     

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.     

Two photosynthetic mechanisms mediating the low photorespiratory state in submersed aquatic angiosperms

The submersed angiosperms Myriophyllum spicatum L. and Hydrilla verticillata (L.f.) Royal exhibited different photosynthetic pulse-chase labeling patterns. In Hydrilla, over 50% of the ¹⁴C was initially in malate and aspartate, but the fate of the malate depended upon the photorespiratory state of the plant. In low photorespiration Hydrilla, malate label decreased rapidly during an unlabeled chase, whereas labeling of sucrose and starch increased. In contrast, for high photorespiration Hydrilla, malate labeling continued to increase during a 2-hour chase. Thus, malate formation occurs in both photorespiratory states, but reduced photorespiration results when this malate is utilized in the light. Unlike Hydrilla, in low photorespiration Myriophyllum, ¹⁴C incorporation was via the Calvin cycle, and less than 10% was in C₄ acids.

Ethoxyzolamide, a carbonic anhydrase inhibitor and a repressor of the low photorespiratory state, increased the label in glycolate, glycine, and serine of Myriophyllum. Isonicotinic acid hydrazide increased glycine labeling of low photorespiration Myriophyllum from 14 to 25%, and from 12 to 48% with high photorespiration plants. Similar trends were observed with Hydrilla. Increasing O₂ increased the per cent [¹⁴C]glycine and the O₂ inhibition of photosynthesis in Myriophyllum. In low photorespiration Myriophyllum, glycine labeling and O₂ inhibition of photosynthesis were independent of the CO₂ level, but in high photorespiration plants the O₂ inhibition was competitively decreased by CO₂. Thus, in low but not high photorespiration plants, glycine labeling and O₂ inhibition appeared to be uncoupled from the external [O₂]/[CO₂] ratio.

These data indicate that the low photorespiratory states of Hydrilla and Myriophyllum are mediated by different mechanisms, the former being C₄-like, while the latter resembles that of low CO₂-grown algae. Both may require carbonic anhydrase to enhance the use of inorganic carbon for reducing photorespiration.

     

Photorespiration-deficient Mutants of Arabidopsis thaliana Lacking Mitochondrial Serine Transhydroxymethylase Activity

Three allelic mutants of Arabidopsis thaliana which lack mitochondrial serine transhydroxymethylase activity due to a recessive nuclear mutation have been characterized. The mutants were shown to be deficient both in glycine decarboxylation and in the conversion of glycine to serine. Glycine accumulated as an end product of photosynthesis in the mutants, largely at the expense of serine, starch, and sucrose formation. The mutants photorespired CO₂ at low rates in the light, but this evolution of photorespiratory CO₂ was abolished by provision of exogenous NH₃. Exogenous NH₃ was required by the mutants for continued synthesis of glycine under photorespiratory conditions. These and related results with wild-type Arabidopsis suggested that glycine decarboxylation is the sole site of photorespiratory CO₂ release in wild-type plants but that depletion of the amino donors required for glyoxylate amination may lead to CO₂ release from direct decarboxylation of glyoxylate. Photosynthetic CO₂ fixation was inhibited in the mutants under atmospheric conditions which promote photorespiration but could be partially restored by exogenous NH₃. The magnitude of the NH₃ stimulation of photosynthesis indicated that the increase was due to the suppression of glyoxylate decarboxylation. The normal growth of the mutants under nonphotorespiratory atmospheric conditions indicates that mitochondrial serine transhydroxymethylase is not required in C₃ plants for any function unrelated to photorespiration.     

Steady-state photosynthesis in alfalfa leaflets: effects of carbon dioxide concentration

When the CO₂ concentration to which Medicago sativa L. var. El Unico leaflets were exposed was increased from half-saturation to saturation (doubled rate of photosynthesis), glycolate and glycine production apparently decreased due to inhibition of a portion of the glycolate pathway. Serine and glycerate production was not inhibited. We conclude that serine and glycerate were made from 3-phosphoglycerate and not from glycolate and that the conversion of glycine to serine may not be the major source of photorespiratory CO₂ in alfalfa. In investigations of glycolate and photorespiratory metabolism, separate labeling data should be obtained for glycine and serine as those two amino acids may be produced from different precursors and respond differently to environmental perturbations. The increased photosynthetic rate (at saturating CO₂) resulted in greater labeling of both soluble and insoluble products. Sucrose labeling increased sharply, but there was no major shift of tracer carbon flow into sucrose relative to other metabolites. The flow of carbon from the reductive pentose phosphate cycle into the production of tricarboxylic acid cycle intermediates and amino acids increased. Only small absolute increases occurred in steady-state pool sizes of metabolites of the reductive pentose phosphate cycle at elevated CO₂, providing further evidence that the cycle is well regulated.     

A possible role for abscisic Acid in regulation of photosynthetic and photorespiratory carbon metabolism in barley leaves

The influence of abscisic acid (ABA) on carbon metabolism, rate of photorespiration, and the activity of the photorespiratory enzymes ribulose bisphosphate oxygenase and glycolate oxidase in 7-day-old barley seedlings (Hordeum vulgare L. var. Alfa) was investigated. Plants treated with ABA had enhanced incorporation of labeled carbon from ¹⁴CO₂ into glycolic acid, glycine, and serine, while ¹⁴C incorporation into 3-phosphoglyceric acid and sugarphosphate esters was depressed. Parallel with this effect, treated plants showed a rise in activity of RuBP oxygenase and glycolic acid oxidase. The rate of photorespiration was increased twofold by ABA treatment at IO⁻⁶ molar while the CO₂-compensation point increased 46% and stomatal resistance increased more than twofold over control plants.     

Photorespiratory rates in wheat and maize as determined by o-labeling

A method was devised to quantify short-term photorespiratory rates in terrestrial plants using ¹⁸O-intermediates of the glycolate pathway, specifically glycolate, glycine, and serine. The pathway intermediates were isolated and analyzed on a GC/MS to determine molecular percent ¹⁸O-enrichment. Rates of glycolate synthesis were determined from ¹⁸O-labeling kinetics of the intermediates, derived rate equations, and nonlinear regression techniques. Glycolate synthesis in wheat (Triticum aestivum L.), a C₃ plant, and maize (Zea mays L.), a C₄ plant, was stimulated by high O₂ concentrations and inhibited by high CO₂ concentrations. The synthesis rates were 7.3, 2.1, and 0.7 micromoles per square decimeter per minute under a 21% O₂ and 0.035% CO₂ atmosphere for leaf tissue of wheat, maize seedlings, and 3-month-old maize, respectively. Photorespiratory CO₂ evolution rates were estimated to be 27, 6, and 2%, respectively, of net photosynthesis for the three groups of plants under the above atmosphere. The results from maize tissue support the hypothesis that C₄ plants photorespire, albeit at a reduced rate in comparison to C₃ plants, and that the CO₂/O₂ ratio in the bundle sheath of maize is higher in mature tissue than in seedling tissue. The pool size of the three photorespiratory intermediates remained constant and were unaffected by changes in either CO₂ or O₂ concentrations throughout the 10-minute labeling period. This suggests that photorespiratory metabolism is regulated by other mechanism besides phosphoglycolate synthesis by ribulose-1,5-bisphosphate carboxylase/oxygenase, at least under short-term conditions. Other mechanisms could be alternate modes of synthesis of the intermediates, regulation of some of the enzymes of the photorespiratory pathway, or regulation of carbon flow between organelles involved in photorespiration. The glycolate pool became nearly 100% ¹⁸O-labeled under an atmosphere of 40% O₂. This pool failed to become 100% ¹⁸O-enriched under lower O₂ concentrations.     

Role of asparagine in the photorespiratory nitrogen metabolism of pea leaves

In pea leaves, much of the metabolism of imported asparagine is by transamination. This activity was previously shown to be localized in the peroxisomes, suggesting a possible connection between asparagine and photorespiratory nitrogen metabolism. This was investigated by examination of the transfer of ¹⁵N from the amino group of asparagine, supplied via the transpiration stream, in fully expanded pea leaves. Label was transferred to aspartate, glutamate, alanine, glycine, serine, ammonia, and glutamine (amide group). Under low oxygen (1.8%), or in the presence of α-hydroxy-2-pyridine methanesulfonic acid (an inhibitor of glycolate oxidase, a step in the photorespiratory formation of glyoxylate), there was a substantial (60-80%) decrease in transfer of label to glycine, serine, ammonia, and glutamine. Addition of isonicotinyl hydrazide (an inhibitor of formation of serine from glycine) caused a 70% decrease in transfer of asparagine amino nitrogen to serine, ammonia, and glutamine, while a 4-fold increase in labeling of glycine was observed. The results demonstrate the involvement of asparagine in photorespiration, and show that photorespiratory nitrogen metabolism is not a closed cyclic process.     

Glycolate Metabolism in Low and High CO(2)-Grown Chlorella pyrenoidosa and Pavlova lutheri as Determined by O-Labeling

Photorespiration in Chlorella pyrenoidosa Chick. was assayed by measuring ¹⁸O-labeled intermediates of the glycolate pathway. Glycolate, glycine, serine, and excreted glycolate were isolated and analyzed on a gas chromatograph/mass spectrometer to determine isotopic enrichment. Rates of glycolate synthesis were determined from ¹⁸O-labeling kinetics of the intermediates, pool sizes, derived rate equations, and nonlinear regression techniques. Glycolate synthesis was higher in high CO₂-grown cells than in air-grown cells when both were assayed under the same O₂ and CO₂ concentrations. Synthesis of glycolate, for both types of cells, was stimulated by high O₂ levels and inhibited by high CO₂ levels. Glycolate synthesis in 1.5% CO₂-grown Chlorella, when exposed to a 0.035% CO₂ atmosphere, increased from about 41 to 86 nanomoles per milligram chlorophyll per minute when the O₂ concentration was increased from 21% to 40%. Glycolate synthesis in air-grown cells increased from 2 to 6 nanomoles per milligram chlorophyll per minute under the same gas levels. Synthesis was undetectable when either the O₂ concentration was lowered to 2% or the CO₂ concentration was raised to 1.5%. Glycolate excretion was also sensitive to O₂ and CO₂ concentrations in 1.5% CO₂-grown cells and the glycolate that was excreted was ¹⁸O-labeled. Air-grown cells did not excrete glycolate under any experimental condition. Indirect evidence indicated that glycolate may be excreted as a lactone in Chlorella. Photorespiratory ¹⁸O-labeling kinetics were determined for Pavlova lutheri, which unlike Chlorella and higher plants did not directly synthesize glycine and serine from glycolate. This alga did excrete a significant proportion of newly synthesized glycolate into the media.     

Inhibition of glycine decarboxylation and serine formation in tobacco by glycine hydroxamate and its effect on photorespiratory carbon flow

Glycine hydroxamate is a competitive inhibitor of glycine decarboxylation and serine formation (referred to as glycine decarboxylase activity) in particulate preparations obtained from both callus and leaf tissue of tobacco. In preparations from tobacco callus tissues, the K_i for glycine hydroxamate was 0.24 ± 0.03 millimolar and the K_m for glycine was 5.0 ± 0.5 millimolar. The inhibitor was chemically stable during assays of glycine decarboxylase activity, but reacted strongly when incubated with glyoxylate. Glycine hydroxamate blocked the conversion of glycine to serine and CO₂in vivo when callus tissue incorporated and metabolized [1-¹⁴C]glycine, [1-¹⁴C]glycolate, or [1-¹⁴C]glyoxylate. The hydroxamate had no effect on glyoxylate aminotransferase activities in vivo, and the nonenzymic reaction between glycine hydroxamate and glyoxylate did not affect the flow of carbon in the glycolate pathway in vivo. Glycine hydroxamate is the first known reversible inhibitor of the photorespiratory conversion of glycine to serine and CO₂.     

Photorespiration-induced reduction of ribulose bisphosphate carboxylase activation level

Leaf photosynthesis and ribulose bisphosphate carboxylase activation level were inhibited in several mutants of the C₃ crucifer Arabidopsis thaliana which possess lesions in the photorespiratory pathway. This inhibition occurred when leaves were illuminated under a photorespiratory atmosphere (50% O₂, 350 microliters per liter CO₂, balance N₂), but not in nonphotorespiratory conditions (2% O₂, 350 microliters per liter CO₂, balance N₂). Inhibition of carboxylase activation level was observed in strains with deficient glycine decarboxylase, serine transhydroxymethylase, serine-glyoxylate aminotransferase, glutamate synthase, and chloroplast dicarboxylate transport activities, but inhibition did not occur in a glycolate-P phosphatase-deficient strain. Also, the photorespiration inhibitor aminoacetonitrile produced a decline in leaf and protoplast ribulose bisphosphate carboxylase activation level, but was without effect on intact chloroplasts. Fructose bisphosphatase, a light-activated enzyme which is strongly dependent on stromal pH and Mg²⁺ for regulation, was unaffected by conditions which caused inhibition of ribulose bisphosphate carboxylase. Thus, the mechanism of inhibition does not appear to involve changes in stromal Mg²⁺ and pH but rather is associated with metabolite flux through the photorespiratory pathway.     

An evaluation of the recycling in measurements of photorespiration

All measurements of photorespiration and gross photosynthesis in leaves, whether using isotopes or not, are underestimated because of the recycling of O₂ or CO₂. On the basis of a simple diffusion model, we propose a method for the calculation of the recycling and the corresponding underestimation of the measurements. This procedure can be applied when the stomatal resistance is known, and allows for a correction of certain results in the literature. It is found that measurements of the photorespiratory CO₂ release are usually underestimated by 20 to 100%, which sets the estimated rate of CO₂ photorespired at 30 to 50% of the net photosynthesis in C3 plants under normal conditions. In water stress studies, the correction of the photorespiration is still more important (1.5-3.3) because the stomata are closed more. Analysis of the diffusion of O₂ shows that its recycling is low and that the underestimation of photorespiration with ¹⁸O₂ is negligible.     

Erratum

Glycolate synthesis was inhibited 40–50% in illuminated tobacco leaf disks, which have rapid rates of photorespiration, when floated on 20 mm potassium glycidate (2,3-epoxypropionate), an epoxide similar in structure to glycolate. The inhibitor also decreased the release of photorespiratory CO₂ about 40%, and the specificity of glycidate was demonstrated by the 40–50% increase in rate of photosynthetic CO₂ uptake observed in its presence. The importance of glycolate synthesis and metabolism in the production of photorespiratory CO₂ and the role of glycolate in diminishing net photosynthesis in species with rapid rates of photorespiration was thus further confirmed. L-(or 2S)-Glycidate was slightly more active than DL-glycidate, but glycidate was more effective as a specific inhibitor in leaf tissue than several other epoxide analogs of glycolate examined. The products of photosynthetic ¹⁴O₂ fixation after 3 or 4 min of uptake were proportionately altered in the presence of glycidate, and the specific radioactivity of the [¹⁴C]glycolate produced was closer to that of the ¹⁴CO₂ supplied. Glycidate inhibited glycolate synthesis in tobacco leaf disks irreversibly, since the degree of inhibition was the same for at least 2 hr after the inhibitor solution was removed. Glycidate also blocked glycolate synthesis in maize leaf disks, tissue with low rates of photorespiration, but large increases in net photosynthesis were not observed in maize with glycidate, because glycolate synthesis is normally only about 10% as rapid in maize as in tobacco. The demonstration of increases in net photosynthesis of 40–50% when glycolate synthesis (and photorespiration) is blocked with glycidate indicates in an independent manner that the biochemical or genetic control of photorespiration should permit large increases in plant productivity in plant species possessing rapid rates of photorespiration.     

Photosynthetic/Photorespiratory Carbon Metabolism in the C(3)-C(4) Intermediate Species, Moricandia arvensis and Panicum milioides

The distribution of ¹⁴C in photosynthetic metabolites of two naturally occurring higher plants with reduced photorespiration, Moricandia arvensis and Panicum milioides, in pulse and pulse-chase ¹⁴CO₂ incorporation experiments was similar to that for the C₃ species, M. foetida and Glycine max. After 6 seconds of ¹⁴CO₂ incorporation, only about 6% of the total ¹⁴C fixed was in malate and aspartate in both M. arvensis and P. milioides. The apparent turnover of the C₄ acids was very slow, and malate accumulated during the day in M. arvensis. Thus, C₄ acid metabolism by M. arvensis and P. milioides had no significant role in photosynthetic carbon assimilation under the conditions of our experiments (310 microliters CO₂ per liter, 21% O₂, 1100 or 1900 micromoles photon per square meter per second, 27°C).

After a 36-second chase period in air containing 270 microliters CO₂ per liter, about 20% of the total ¹⁴C fixed was in glycine with M. arvensis, as compared to 15% with M. foetida, 14% with P. milioides, and 9% with G. max. After a 36-second chase period in 100 microliters CO₂ per liter, the percentage in glycine was about twice that at 270 microliters CO₂ per liter in the C₃ species and P. milioides, but only 20% more ¹⁴C was in glycine in M. arvensis. These data suggest that either the photorespiratory glycine pool in M. arvensis is larger than in the other species examined or the apparent turnover rate of glycine and the flow of carbon into glycine during photorespiration are less in M. arvensis. An unusual glycine metabolism in M. arvensis may be linked to the mechanism of photorespiratory reduction in this crucifer.

     

Aminotransfer from Alanine and Glutamate to Glycine and Serine during Photorespiration in Oat Leaves

¹⁵N-Labeled glutamate and alanine were used to examine the photorespiratory nitrogen metabolism in oat (Avena sativa L.) leaf slices. Glutamate and alanine supply amino groups for glycine formation during photorespiration. The nitrogen flux from alanine to glycine was estimated to be 3 times higher than that from glutamate. It is concluded from these results that alanine is a direct and important amino donor for photorespiratory glycine formation in oat leaves. The ¹⁵N labeling of serine was almost as high as that of glycine during the initial period of the labeling experiments. Thereafter, the ratio of ¹⁵N label in serine to ¹⁵N label in glycine declined substantially.     

Effect of Aminoacetonitrile on the CO2 Exchange Rate in Rice Leaves

Aminoacetonitrile (AAN), a specific inhibitor of glycine oxidation in the photorespiratory glycolate pathway, did not inhibit photosynthetic CO₂ fixation, but inhibited the apparent photosynthesis of rice leaves under high photosynthetic conditions. However, under such low photosynthetic conditions as low light intensity or senescent leaves, the apparent photosynthesis was not inhibited by AAN. The application of AAN to the leaves led to a greater accumulation of glycine under a high photosynthetic condition like strong light intensity.

From these results, it can be postulated that the inhibition of apparent photosynthesis by AAN was due to the accumulation of intermediate metabolites in the photorespiratory glycolate pathway which was induced by AAN treatment.     

Effect of Oxygen Concentration on C-Photoassimilate Transport from Leaves of Salvia splendens L

Partitioning and transport of recently fixed photosynthate was examined following ¹⁴CO₂ pulse-labeling of intact, attached leaves of Salvia splendens L. maintained in an atmosphere of 300 microliters per liter CO₂ and 20, 210, or 500 milliliters per liter O₂. Under conditions of increasing O₂ (210, 500 milliliters per liter), a smaller percentage of the recently fixed ¹⁴C in the leaf was allocated to starch, whereas a greater percentage of the fixed ¹⁴C appeared in amino acids, particularly serine. The increase in ¹⁴C in amino acids was reflected in material exported from source leaves. A higher percentage of ¹⁴C in serine, glycine, and glutamate was recovered in petiole extracts when source leaves were maintained under elevated O₂ levels. Although pool sizes of these amino acids were increased in both the leaves and petioles with increasing photorespiratory activity, no significant changes in either ¹⁴C distribution or concentration of transport sugars (i.e. stachyose, sucrose, verbascose) were observed. The data indicate that, in addition to being recycled intracellularly into Calvin cycle intermediates, amino acids produced during photorespiration may also serve as transport metabolites, allowing the mobilization of both carbon and nitrogen from the leaf under conditions of limited photosynthesis.     

Effect of CO(2) Concentration on Glycine and Serine Formation during Photorespiration

Amount and products of photosynthesis during 10 minutes were measured at different ¹⁴CO₂ concentrations in air. With tobacco (Nicotiana tabacum L. cv. Maryland Mammoth) leaves the percentage of ¹⁴C in glycine plus serine was highest (42%) at 0.005% CO₂, and decreased with increasing CO₂ concentration to 7% of the total at 1% CO₂ in air. However, above 0.03% CO₂ the total amount of ¹⁴C incorporated into the glycine and serine pool was about constant. At 0.005% or 0.03% CO₂ the percentage and amount of ¹⁴C in sucrose was small but increased greatly at higher CO₂ levels as sucrose accumulated as an end product. Relatively similar data were obtained with sugar beet (Beta vulgaris L. cv. US H20) leaves. The results suggest that photorespiration at high CO₂ concentration is not inhibited but that CO₂ loss from it becomes less significant.