Effects of Temperature on Photosynthesis and CO(2) Evolution in Light and Darkness by Green Leaves

Using an open and a closed system of gas analysis, it was found that CO₂ evolution in light and in darkness from plant leaves (sunflower, soybean, watermelon, eggplant, and jackbean) have a different response to temperature. While the rate of CO₂ evolution in light increased with increasing temperature from 17 to 35° and then declined, the rate of CO₂ evolution in darkness increased continuously up to 40°. The rate of CO₂ evolution in light was affected by light intensity. At 1800 ft-c and below 35° the rate of CO₂ evolution in light was greater than in darkness, but above 35° it became lower than in darkness. The Q₁₀ for CO₂ evolution in light was consistently lower than that in darkness.     

Green Light Drives CO2 Fixation Deep within Leaves

Maximal ^l4CO₂-fixation in spinach occurs in the middle of thepalisade mesophyll [Nishio et al. (1993) Plant Cell 5: 953],however, ninety percent of the blue and red light is attenuatedin the upper twenty percent of a spinach leaf [Cui et al. (1991)Plant Cell Environ. 14: 493]. In this report, we showed thatgreen light drives ¹⁴CO₂-fixation deep within spinach leavescompared to red and blue light. Blue light caused fixation mainlyin the palisade mesophyll of the leaf, whereas red light drovefixation slightly deeper into the leaf than did blue light.¹⁴CO₂-fixation measured under green light resulted in less fixationin the upper epidermal layer (guard cells) and upper most palisademesophyll compared to red and blue light, but led to more fixationdeeper in the leaf than that caused by either red or blue light.Saturating white, red, or green light resulted in similar maximal¹⁴CO₂-fixation rates, whereas under the highest irradiance ofblue light given, carbon fixation was not saturated, but itasymptotically approached the maximal ¹⁴CO₂-fixation rates attainedunder the other types of light. The importance of green lightin photosynthesis is discussed. ¹Supported in part by grants from Competitive Research GrantsOffice, U.S. Department of Agriculture (Nos. 91-37100-6672 and93-37100-8855).     

Changes in the CO2 Evolution Rate in Cattleya Roots during Alternating Light and Dark Periods as Related to Changes in the CO2 Absorption Rate of Cattleya Leaves

The CO₂ absorption rate of the leaves and the CO₂ evolutionrate of the roots of Cattleya were determined simultaneouslyduring alternate light and dark periods. The CO₂ evolution rateof the roots decreased as the CO₂ absorption rate of leavesincreased in the dark period and increased as the absorptionrate of the leaves decreased in the light period. Severing theleaves in the dark increased the CO₂ evolution rate in rootsto the value found in the light. (Received April 16, 1984; Accepted September 7, 1984)     

Photoinhibition of CO(2)-Dependent O(2) Evolution by Intact Chloroplasts Isolated from Spinach Leaves

Intact spinach (Spinacia oleracea L.) chloroplasts, when pre-illuminated at 4 millimoles quanta per square meter per second for 8 minutes in a CO₂-free buffer at 21% O₂, showed a decrease (30-70%) in CO₂-dependent O₂ evolution and ¹⁴CO₂ uptake. This photoinhibition was observed only when the O₂ concentration and the quantum fluence rate were higher than 4% and 1 millimole per square meter per second, respectively. There was only a small decrease in the extent of photoinhibition when the CO₂ concentration was increased from 0 to 25 micromolar during the treatment, but photoinhibition was abolished when the CO₂ concentration was increased to 30 micromolar. Addition of small quantities of P-glycerate (40-200 micromolar) or glycerate (160 micromolar) was found to prevent photoinhibition. Other intermediates of the Calvin cycle (fructose-6-P, fructose-1,6-P, ribose-5-P, ribulose-5-P) also prevented photoinhibition to various extents. Oxaloacetate was not effective in preventing photoinhibition in these chloroplasts. The amount of O₂ evolved during treatments with 3-P-glycerate or glycerate was no more than 65% of that measured in the presence of low CO₂ concentrations (9-12 micromolar) which did not prevent photoinhibition. In all cases, the extent to which photoinhibition was prevented by these metabolites was not correlated to the amount of O₂ evolved during the photoinhibitory treatment. It is concluded that in these chloroplasts the prevention of the O₂-dependent photoinhibition of light saturated CO₂ fixation capacity is not linked to the dissipation of excitation energy via the photosynthetic electron transport nor to ATP utilization. The requirement of O₂ for photoinhibition of CO₂ fixation capacity in isolated chloroplasts may be explained by an effect of O₂ in allowing metabolic depletion of Calvin cycle intermediates.     

Effects of Metabolic Inhibitors on the Rates of CO(2) Evolution in Light and in Darkness by Detached Spruce Twigs, Wheat, and Soybean Leaves

Detached spruce twigs, wheat and soybean leaves were infiltrated with various metabolic inhibitors, placed in a closed system in CO₂-free air and the amounts of CO₂ evolved in either light or darkness were determined with an infra-red CO₂ analyzer. In light, metabolic inhibitors always greatly suppressed evolution of CO₂, the magnitude of suppression varying between 50 to 80% of that without an inhibitor. This depressing effect became less pronounced with increasing oxygen. In darkness, metabolic inhibitors sometimes suppressed and sometimes stimulated CO₂ evolution. These observations have been taken as further support for a conclusion made earlier, that evolution of CO₂ in light and darkness is not the same process.     

Effects of O(2) Tension and Temperature during Light Uptake of CO(2) on the Dark Release of CO(2) by Excised C(3) and C(4) Leaves

A study was conducted on a C₄ (Panicum maximum) and a C₃ (Panicum bisulcatum) species to determine the nature of the dark release of ¹⁴CO₂ with respect to its responses to changes in temperature and O₂ tension during light CO₂ uptake of ¹⁴CO₂.     

Effects of Powdery Mildew Infection on the Efficiency of CO(2) Fixation and Light Utilization by Sugar Beet Leaves

Sugar beet leaves (Beta vulgaris L.) infected with powdery mildew (Erysiphe polygoni D.C.) show declining rates of net photosynthesis as the disease develops; relative to healthy controls, reductions of 35, 70, and 75% were observed at 9, 16, and 22 days after inoculation, respectively. A leaf gas exchange procedure in which an air stream flowed through the leaf showed that mesophyll conductance declined in parallel with photosynthesis in mildew-infected leaves. Viscous flow conductance of diseased leaves also declined over the same period suggesting that stomatal aperture was reduced. From the magnitude and time course of disease effects on stomatal aperture and mesophyll conductance, it appears that the effects at the mesophyll level were primarily responsible for mediating the decline in net photosynthesis. Changes in mesophyll conductance were closely correlated with reduced activity of ribulose-1,5-bisphosphate carboxylase on a leaf area basis. This decrease could be attributed to a reduction in the concentration of the enzyme, a reduction which was greater than the reduction in total soluble protein. The quantum efficiency of light use was also decreased by the disease. Mildew-infected leaves had quantum yields that were reduced, relative to healthy leaves, by 17 and 22% at 14 and 18 days after inoculation, respectively.     

Active CO(2) Transport by the Green Alga Chlamydomonas reinhardtii

Mass spectrometric measurements of dissolved free ¹³CO₂ were used to monitor CO₂ uptake by air grown (low CO₂) cells and protoplasts from the green alga Chlamydomonas reinhardtii. In the presence of 50 micromolar dissolved inorganic carbon and light, protoplasts which had been washed free of external carbonic anhydrase reduced the ¹³CO₂ concentration in the medium to close to zero. Similar results were obtained with low CO₂ cells treated with 50 micromolar acetazolamide. Addition of carbonic anhydrase to protoplasts after the period of rapid CO₂ uptake revealed that the removal of CO₂ from the medium in the light was due to selective and active CO₂ transport rather than uptake of total dissolved inorganic carbon. In the light, low CO₂ cells and protoplasts incubated with carbonic anhydrase took up CO₂ at an apparently low rate which reflected the uptake of total dissolved inorganic carbon. No net CO₂ uptake occurred in the dark. Measurement of chlorophyll a fluorescence yield with low CO₂ cells and washed protoplasts showed that variable fluorescence was mainly influenced by energy quenching which was reciprocally related to photosynthetic activity with its highest value at the CO₂ compensation point. During the linear uptake of CO₂, low CO₂ cells and protoplasts incubated with carbonic anhydrase showed similar rates of net O₂ evolution (102 and 108 micromoles per milligram of chlorophyll per hour, respectively). The rate of net O₂ evolution (83 micromoles per milligram of chlorophyll per hour) with washed protoplasts was 20 to 30% lower during the period of rapid CO₂ uptake and decreased to a still lower value of 46 micromoles per milligram of chlorophyll per hour when most of the free CO₂ had been removed from the medium. The addition of carbonic anhydrase at this point resulted in more than a doubling of the rate of O₂ evolution. These results show low CO₂ cells of Chlamydomonas are able to transport both CO₂ and HCO₃⁻ but CO₂ is preferentially removed from the medium. The external carbonic anhydrase is important in the supply to the cells of free CO₂ from the dehydration of HCO₃⁻.     

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.     

Light and CO(2) Response of Ribulose-1,5-Bisphosphate Carboxylase/Oxygenase Activation in Arabidopsis Leaves

The requirements for activation of ribulose 1,5-bisphosphate carboxylase/oxygenase (rubisco) were investigated in leaves of Arabidopsis wild-type and a mutant incapable of light activating rubisco in vivo. Upon illumination with saturating light intensities, the activation state of rubisco increased 2-fold in the wild-type and decreased in the mutant. Activation of fructose 1,6-bisphosphate phosphatase was unaffected by the mutation. Under low light, rubisco deactivated in both the wild-type and the mutant. Deactivation of rubisco in the mutant under high and low light led to the accumulation of high concentrations of ribulose 1,5-bisphosphate. Inhibiting photosynthesis with methyl viologen prevented ribulose 1,5-bisphosphate accumulation but was ineffective in restoring rubisco activation to the mutant. Net photosynthesis and the rubisco activation level were closely correlated and saturated at a lower light intensity in the mutant than in wild-type. At CO₂ concentrations between 100 and 2000 microliters per liter, the activation state was a function of the CO₂ concentration in the dark but was independent of CO₂ concentration in the light. High CO₂ concentration (1%) suppressed activation in the wild-type and deactivation in the mutant. These results support the concept that rubisco activation in vivo is not a spontaneous process but is catalyzed by a specific protein. The absence of this protein, rubisco activase, is responsible for the altered characteristics of rubisco activation in the mutant.     

Low CO(2) Prevents Nitrate Reduction in Leaves

The correlation between CO₂ assimilation and nitrate reduction in detached spinach (Spinacia oleracea L.) leaves was examined by measuring light-dependent changes in leaf nitrate levels in response to mild water stress and to artificially imposed CO₂ deficiency. The level of extractable nitrate reductase (NR) activity was also measured. The results are: (a) In the light, detached turgid spinach leaves reduced nitrate stored in the vacuoles of mesophyll cells at rates between 3 and 10 micromoles per milligram of chlorophyll per hour. Nitrate fed through the petiole was reduced at similar rates as storage nitrate. Nitrate reduction was accompanied by malate accumulation. (b) Under mild water stress which caused stomatal closure, nitrate reduction was prevented. The inhibition of nitrate reduction observed in water stressed leaves was reversed by external CO₂ concentrations (10-15%) high enough to overcome stomatal resistance. (c) Nitrate reduction was also inhibited when turgid leaves were kept in CO₂-free air or at the CO₂-compensation point or in nitrogen. (d) When leaves were illuminated in CO₂-free air, activity of NR decreased rapidly. It increased again, when CO₂ was added back to the system. The half-time for a 50% change in activity was about 30 min. It thus appears that there is a rapid inactivation/activation mechanism of NR in leaves which couples nitrate reductase to net photosynthesis.     

野生与栽培黄花蒿净光合速率对光强和CO2浓度的响应

比较了相同种源的野生和栽培黄花蒿(Artemisia annua L.)净光合速率对光强和CO2浓度的响应特性。结果表明,野生和栽培黄花蒿的光饱和点(LSP)分别为1 183和1 564μmol m-2s-1,光补偿点(LCP)为17和18μmol m-2s-1,最大净光合速率(Pmax)为18.78和22.38μmol m-2s-1,表观量子效率(AQY)为0.08和0.075μmol m-2s-1,表明黄花蒿的光合能力强,能够利用很高的光强,且对弱光的适应性也较强。栽培黄花蒿的Pmax、LSP和最大羧化速率(Vcmax)显著高于野生黄花蒿,两者的LCP、不包括光下呼吸的CO2补偿点、AQY、光下呼吸速率和最大电子传递速率(Jmax)差异不显著。强光下栽培黄花蒿主要通过提高Vcmax和Jmax等来增强光合能力,强的光合能力有利于黄花蒿的生长,因此在人工栽培黄花蒿的过程中应选择阳光充足的开阔生境。     

Net CO(2) Assimilation Rate of Grapevine Leaves in Response to Trunk Girdling and Gibberellic Acid Application

Net CO₂ assimilation rate (A), stomatal conductance (g_s), and weight per unit leaf area (W) were determined on Thompson Seedless grapevines grown in the field. Treatments included fruit set applications of gibberellic acid (40 milligrams gibberellic acid (GA₃) per liter) to vines, shoots and clusters, alone and in combination with trunk girdling. Leaf A and g_s were measured prior to and 3, 6, and 13 days after fruit set. Weight per unit leaf area was determined on leaves collected subsequent to gas exchange measurements. Leaf A of girdled vines was reduced approximately 30% when compared to the control 13 days after treatment. The reduction in A due to girdling was not as great when vines were sprayed with GA₃. GA₃ sprays alone had no significant effect on A. Stomatal conductance was reduced by girdling 13 days after treatment. Weight per unit leaf area was 17% greater for trunk girdled vines when compared to the controls. Results indicate GA₃ affected net CO₂ assimilation rate only on girdled vines, a treatment which increased weight per unit leaf area.     

Regulation of Catalase Activity in Leaves of Nicotiana sylvestris by High CO(2)

The effect of high CO₂ (1% CO₂/21% O₂) on the activity of specific forms of catalase (CAT-1, -2, and -3) (EA Havir, NA McHale [1987] Plant Physiol 84: 450-455) in seedling leaves of tobacco (Nicotiana sylvestris, Nicotlana tabacum) was examined. In high CO₂, total catalase activity decreased by 50% in the first 2 days, followed by a more gradual decline in the next 4 days. The loss of total activity resulted primarily from a decrease in CAT-1 catalase. In contrast, the activity of CAT-3 catalase, a form with enhanced peroxidatic activity, increased 3-fold in high CO₂ relative to air controls after 4 days. Short-term exposure to high CO₂ indicated that the 50% loss of total activity occurs in the first 12 hours. Catalase levels increased to normal within 12 hours after seedlings were returned to air. When seedlings were transferred to air after prolonged exposure to high CO₂ (13 days), the levels of CAT-1 catalase were partially restored while CAT-3 remained at its elevated level. Levels of superoxide dismutase activity and those of several peroxisomal enzymes were not affected by high CO₂. Total catalase levels did not decline when seedlings were exposed to atmospheres of 0.04% CO₂/5% O₂ or 0.04% CO₂/1% O₂, indicating that regulation of catalase in high CO₂ is not related directly to suppression of photorespiration. Antibodies prepared against CAT-1 catalase from N. tabacum reacted strongly against CAT-1 catalase from both N. sylvestris and N. tabacum but not against CAT-3 catalase from either species. This observation, along with the rapid changes in CAT-1 and the much slower changes in CAT-3 suggest that one form is not directly derived from the other.     

Catabolism of 5-Aminolevulinic Acid to CO(2) by Etiolated Barley Leaves

The in vivo oxidation of the C₄ and C₅ of 5-aminolevulinic acid (ALA) to CO₂ has been studied in etiolated barley (Hordeum vulgare L. var. Larker) leaves in darkness. The rate of ¹⁴CO₂ evolution from leaves fed [4-¹⁴C]ALA is strongly inhibited by aminooxyacetate, anaerobiosis, and malonate. The rate of ¹⁴CO₂ evolution from leaves fed [5-¹⁴C]ALA is also inhibited by these treatments but to a lesser extent. These results suggest that (a) one step in ALA catabolism is a transamination reaction and (b) the C₄ is oxidized to CO₂ via the tricarboxylic acid cycle to a greater extent than is the C₅.     

Carbon Dioxide Exchanges in Leaves. I. Discrimination Between CO(2) and CO(2) in Photosynthesis

In order to measure CO₂ exchange reactions by leaves using isotopes of CO₂, it is necessary to know precisely the discrimination against ¹⁴CO₂ by leaves. Earlier determinations of discrimination are at variance, and may be inaccurate because of assumptions made about the rate of photorespiration. Maize leaves evolve little or no CO₂ in light, and so provide suitable material for this measurement. Discrimination against ¹⁴CO₂ in photosynthesis by maize leaves is almost precisely the same as in CO₂ absorption by NaOH solution, amounting to 2.1 and 2.0% respectively. The agreement between these values and their close approximation to the relative rates of diffusion of ¹²CO₂ and ¹⁴CO₂, calculated from Graham's law, shows that diffusion into the leaf is primarily responsible for discrimination against ¹⁴CO₂ in photosynthesis.