Photosynthesis and nitrogen relationships in leaves of C3 plants

Summary The photosynthetic capacity of leaves is related to the nitrogen content primarily bacause the proteins of the Calvin cycle and thylakoids represent the majority of leaf nitrogen. To a first approximation, thylakoid nitrogen is proportional to the chlorophyll content (50 mol thylakoid N mol^-1 Chl). Within species there are strong linear relationships between nitrogen and both RuBP carboxylase and chlorophyll. With increasing nitrogen per unit leaf area, the proportion of total leaf nitrogen in the thylakoids remains the same while the proportion in soluble protein increases. In many species, growth under lower irradiance greatly increases the partitioning of nitrogen into chlorophyll and the thylakoids, while the electron transport capacity per unit of chlorophyll declines. If growth irradiance influences the relationship between photosynthetic capacity and nitrogen content, predicting nitrogen distribution between leaves in a canopy becomes more complicated. When both photosynthetic capacity and leaf nitrogen content are expressed on the basis of leaf area, considerable variation in the photosynthetic capacity for a given leaf nitrogen content is found between species. The variation reflects different strategies of nitrogen partitioning, the electron transport capacity per unit of chlorophyll and the specific activity of RuBP carboxylase. Survival in certain environments clearly does not require maximising photosynthetic capacity for a given leaf nitrogen content. Species that flourish in the shade partition relatively more nitrogen into the thylakoids, although this is associated with lower photosynthetic capacity per unit of nitrogen.     

Photosynthesis in leaves,fruits, stem and petioles of greenhouse-grown tomato plants

Gross photosynthetic capacity (P _G ) of greenhouse-grown tomato plants (Lycopersicon esculentum Mill.) decreased as the leaf aged. The P _G of the 10th, 15th and 18th leaves from the top was only 76, 37, and 18 % of P _G of the 5th leaf, respectively. Quantum yield (Y _Q ) and dark respiration rate (R _D ) were also lower in older leaves than in the younger ones. Net photosynthetic rate (P _G ) was apparent in young fruits (about 10 g FM) or young petioles but no P _N was found in large fruits (40 g or more FM) and stems because of high R _D . Both P _G and R _D were lower in older fruits and petioles or in lower parts of the stem compared to the younger ones or upper parts of stem. A sharp decrease in chlorophyll (Chl) content was only measured in the senescing 18th leaf. The Chl content in petioles, stems and fruits was proportional to P _G . Decreases in P _G of older leaves were attributed to decreases in content rather than activity of ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBPCO) since soluble protein content was lower in older leaves than in the younger ones but the specific activity (activity per unit of protein) of RuBPCO was not so. The estimated values of P _N of the 10th, 15th and 18th leaves inside the canopy were only 50, 21, and 7 % of that in the 5th leaf. Therefore, leaves below the 18th can be removed in order to ensure a good air circulation and prevent diseases. The significance of photosynthesis in fruit, stem and petioles is not negligible because photosynthesis re-fixes the respired CO₂. This revised version was published online in September 2006 with corrections to the Cover Date.     

Drought-inhibition of photosynthesis in C3 plants: stomatal and non-stomatal limitations revisited

There is a long-standing controversy as to whether drought limits photosynthetic CO2 assimilation through stomatal closure or by metabolic impairment in C3 plants. Comparing results from different studies is difficult due to interspecific differences in the response of photosynthesis to leaf water potential and/or relative water content (RWC), the most commonly used parameters to assess the severity of drought. Therefore, we have used stomatal conductance (g) as a basis for comparison of metabolic processes in different studies. The logic is that, as there is a strong link between g and photosynthesis (perhaps co-regulation between them), so different relationships between RWC or water potential and photosynthetic rate and changes in metabolism in different species and studies may be 'normalized' by relating them to g. Re-analysing data from the literature using light-saturated g as a parameter indicative of water deficits in plants shows that there is good correspondence between the onset of drought-induced inhibition of different photosynthetic sub-processes and g. Contents of ribulose bisphosphate (RuBP) and adenosine triphosphate (ATP) decrease early in drought development, at still relatively high g (higher than 150 mmol H20 m(-2) s(-1)). This suggests that RuBP regeneration and ATP synthesis are impaired. Decreased photochemistry and Rubisco activity typically occur at lower g (<100 mmol H20 m(-2) s(-1)), whereas permanent photoinhibition is only occasional, occurring at very low g (<50 mmol H20 m(-2) s(-1)). Sub-stomatal CO2 concentration decreases as g becomes smaller, but increases again at small g. The analysis suggests that stomatal closure is the earliest response to drought and the dominant limitation to photosynthesis at mild to moderate drought. However, in parallel, progressive down-regulation or inhibition of metabolic processes leads to decreased RuBP content, which becomes the dominant limitation at severe drought, and thereby inhibits photosynthetic CO2 assimilation.     

You're so vein: bundle sheath physiology,phylogeny and evolution in C3 and C4 plants

Bundle sheath (BS) anatomy is found in most C4 lineages, associated with low inter‐veinal distances (IVD) and high BS:mesophyll ratio (BS:MC). The origins, function and selective advantages of the BS in C3 lineages are relevant for understanding the environmental, molecular and phylogenetic determinants of C4 evolution. Suggested functions for BS have included structural support, hydraulic isolation, storage for water, ions, and carbohydrates, and photorespiratory carbon metabolism; we propose a central role for cavitation repair, consistent with the BS as a control centre on regulating stem and leaf hydraulic continuity. An analysis of BS traits in the phylogenetic lineages giving rise to C4 grasses (the ‘PACMAD’ clade) shows an initial enhancement in BS:MC ratio in C3 lineages, although IVD is similar to the Pooideae sister group. Using a global database, a well‐developed BS in the C3 PACMAD lineages was associated with higher precipitation and temperatures in the habitat of origin on an annual basis, with the C3 to C4 progression defined by the aridity index (AI). Maintaining leaf hydraulic conductance and cavitation repair are consistent with increased evaporative demand and more seasonal precipitation as drivers, first for the C3 BS, and then C4 diversification, under declining CO₂ concentrations in the Palaeogene and Neogene.     

Light-dependent pH changes in leaves of C3 plants

Illumination of leaves of C₃ plants caused cytosolic alkalization and vacuolar acidification in the mesophyll cells. Both phenomena were particularly pronounced when CO₂ was absent, were suppressed by CO₂, and were related to the activation state of the photosynthetic apparatus. The cytosolic alkalization reaction has at least two major components. Trivalent cytosolic phosphoglycerate must be protonated before it can be transferred into the chloroplasts for reduction. Pumping of protons from the cytosol into the vacuole also contributes to cytosolic alkalization. The dependence of light scattering by chloroplast thylakoids on the energy fluence rate was closely related to that of vacuolar acidification under different conditions for chloroplast energization. This indicates (i) transport of energy from the chloroplasts to the cytosol in the light and (ii) use of this energy for the transport of protons into the vacuoles. The light-dependent vacuolar acidification is interpreted to be caused by the increase in the activity of a proton-translocating enzyme of the tonoplast. The decrease of vacuolar acidification during photosynthetic carbon reduction or photorespiration is indicative of decreased cytosolic energization. In low light, the light-dependent vacuolar acidification was stimulated in the absence of CO₂ when photorespiration was inhibited. The data do not support the view that photorespiration is capable of increasing the cytosolic energy state in the light.This work was supported by the Sonderforschungsbereiche 176 and 251 of the University of Würzburg. Z.-H. Y. acknowledges support by the Leibniz program of the Deutsche Forschungsgemeinschaft and by the Committee for Education of the People's Republic of China.     

Light-dependent pH changes in leaves of C3 plants

Action spectra in the red region of the spectrum for light-dependent cytosolic alkalization in leaves of C₃ plants which also received a low background of blue light differed from the action spectra for light-dependent vacuolar acidification. Light above 680 nm was less effective in supporting the cytosolic alkalization reaction than light below 680 nm. In contrast, in leaves illuminated in CO₂-free air the light-dependent vacuolar acidification exhibited a maximum at or even above 700 nm. When photorespiratory carbohydrate oxidation was suppressed in low oxygen, a substantially changed action spectrum of the acidification reaction resembled in shape that of the cytosolic alkalization with the exception that it was extended towards the far-red. From the presented data and from previously published data (Yin et al., 1990b, Planta 182, 253–261; Yin et al., 1990c, Planta 182, 262–269) it is concluded that in the presence of a weak background of blue light, and in the absence of CO₂ which drains electrons from the electron transport chain, cyclic photophosphorylation induced by far-red light permits increased export of dihydroxyacetone phosphate from the chloroplasts into the cytosol where its oxidation increases the cytosolic energy state giving rise to increased proton transport across the tonoplast. The data do not lend support to the view that export of malate from the chloroplasts and its oxidation in the mitochondria contribute significantly to cytosolic energization in the light.Abbreviations CDCF 5-(and-6)-carboxy-2,7-dichlorofluorescein - DHAP dihydroxyacetone phosphate - OAA oxaloacetate - PGA phosphoglycerate This work was performed within the Sonderforschungsbereiche 176 and 251 of the University of Würzburg. Z.-H. Y. acknowledges support by the Leibniz program of the Deutsche Forschungs-gemeinschaft.     

Glycerate kinase from leaves of C3 plants

D-Glycerate-3-kinase (EC 2.7.1.31) in six C3 species, including dicots (Pisum sativum, Spinacea oleracea, Antirrhinum majus) and monocots (Secale cereale, Hordeum vulgare, Avena sativa), ranged in activity from 44 to 353 mumol X mg chl-1 X h-1. Studies with protoplast extracts of these species indicate that the enzyme is localized in the chloroplasts. Glycerate kinase was partially purified from Secale (rye, 288-fold) and Pisum (pea, 252-fold) chloroplasts by DEAE-cellulose chromatography, sucrose gradient centrifugation, and chromatofocusing. The enzymes from both species showed similar physical (Mr = 41,000, pI = 4.6-4.7) and kinetic (Km ATP = 655 to 692 microM, Km D-glycerate = 180-188 microM) properties. Activity of the enzyme was essentially insensitive to variations in assay pH from 6.4 to 9.0 and to energy charge variations from 0.4 to 1.0. Rye glycerate kinase was able to utilize UTP and GTP but less effectively than ATP. Neither ADP nor pyrophosphate served as an energy source. Mn2+, Co2+, Ca2+, and Sr2+ could function as metal cofactors, although to a lesser extent than Mg2+. Millimolar levels of sulfate were found to significantly inhibit the enzyme while similar concentrations of other anions (Cl-, NO-3, NO-2, and acetate) had little or no effect.     

Localization of superoxide dismutase in leaves of C3 and C4 plants

Chloroplasts, mitochondria and cytoplasm, isolated from pea,wheat, maize and sorghum mesophyll protoplasts, contain distinctforms of superoxide dismutase (SOD). In all species evaluated,chloroplasts exhibited a single cyanide-sensitive SOD. Thischloroplastic enzyme was the most anionic SOD observed in wholeleaf and protoplast extracts and constitutes 50–80% ofthe total soluble SOD. Pea and wheat protoplasts had only onecytoplasmic SOD, a cyanide-sensitive form of intermediate mobility;maize and sorghum had two such cytoplasmic enzymes. A singlecyanide-insensitive SOD was present in extracts from both C₃and C₄ tissues and was associated with mitochondria. Although bundle sheath cells of sorghum and maize are knownto be deficient in Photosystem II, there was no apparent differencein SOD between mesophyll and bundle sheath cells. Mesophyllprotoplasts and bundle sheath strands from these C₄ plants containedthe same forms of SOD. Levels of soluble SOD were similar, ona chlorophyll basis, in the two cell types as was distributionof activity among the various forms of the enzyme. (Received May 19, 1980; )     

Photosynthesis and dark respiration of leaves of terrestrial carnivorous plants

Using CO₂ gasometry, net photosynthetic (P _N) and dark respiration rates (R _D) were measured in leaves or traps of 12 terrestrial carnivorous plant species usually grown in the shade. Generally, mean maximum P _N (60 nmol CO₂ g⁻¹(DM) s⁻¹ or 2.7 μmol m⁻² s⁻¹) was low in comparison with that of vascular non-carnivorous plants but was slightly higher than that reported elsewhere for carnivorous plants. After light saturation, the facultatively heliophytic plants behaved as shade-adapted plants. Mean R _D in leaves and traps of all species reached about 50% of maximum P _N and represents the high photosynthetic (metabolic) cost of carnivory.     

Maintenance and growth components of dark respiration rate in leaves of C3 and C4 plants as affected by leaf temperature

The rates of maintenance and growth components of leaf dark respiration of a C₃ plant (Phaseolus vulgaris L.) and C₄ plant (Zea mays L.) as affected by temperature were studied using the McCree concept. Respiration rates were measured by means of infrared gas analysis in a closed gas exchange system. In both C₃ and C₄ species R_D and R_m increased with temperature in the temperature range (15–62 °C) studied. R_G depended on temperature with an optimum near the temperature optimum of gross photosynthetic rate, P_g. Significant correlation between R_D and R_M and between R_G and P_G was found.     

Antioxidant defense in the leaves of C3 and C4 plants under salinity stress

The effect of salt stress (50, 100 and 150 m M of NaCl) on the activity of superoxide dismutase (SOD, EC. 1.15.1.1), ascorbate peroxidase (APX, EC. 1.11.1.11), glutathione reductase (GR, EC. 1.6.4.2) enzymes and also on the rate of lipid peroxidation in terms of thiobarbituric acid-reactive substances (TBARS) content and photosynthetic capacity in two wheat (C3 plants) and two maize (C4 plants) varieties was studied. In the non-salined control plants, the antioxidant enzymes activities were significantly higher for maize than for wheat. Adding salt to the nutrient solution increased the level of antioxidants in leaves of both maize and wheat. The first substantial response to salinity was found for SOD on the 2nd day, whereas changes occurred for APX on the 4th day and for GR on the 4th/5th day of salt treatment. Although SOD activity increased considerably more in wheat (C3), it never reached as high levels as in maize (C4) grown in the same treatment combinations. The total increase in APX activity was similar for wheat and maize, whereas GR activity was higher in leaves of maize. Lipid peroxidation analyses showed an increase in TBARS contents in both plants' species grown under salinity that corresponded to the damage that occurred in secondary oxidative stress. However, as a result of advanced antioxidant defense in maize, the TBARS quantities did not elevate to as high level as in wheat. Chlorophyll fluorescence measurements revealed a considerable decrease in the efficiency of PS II and electron-transport chain (ETC). Assimilation rate of CO₂ decreased in both plant groups; however, in C4 maize, we observed a much better capacity to preserve the photosynthetic apparatus against overproduction of ROS. Results suggest that efficient antioxidant defense plays an important role in maize, the C₄ plant, resistance to environmental stresses like salinity or drought.     

Roles of the bundle sheath cells in leaves of C3 plants

This review considers aspects of the structure and functions of the parenchymatous bundle sheath that surrounds the veins in the leaves of many C(3) plants. It includes a discussion of bundle sheath structure and its related structures (bundle sheath extensions and the paraveinal mesophyll), its relationship to the mestome sheath in some grasses, and its chloroplast content. Its metabolic roles in photosynthesis, carbohydrate synthesis and storage, the import and export of nitrogen and sulphur, and the metabolism of reactive oxygen species are discussed and are compared with the role of the bundle sheath in leaves of C(4) plants. Its role as an interface between the vasculature and the mesophyll is considered in relation to the movement of water and assimilates during leaf development, export of photosynthates, and senescence.     

Photosynthesis in cold acclimated leaves of plants with various degrees of freezing tolerance

The objective of this study was to compare the photosynthetic changes during cold acclimation in various plant types able to acquire different degrees of freezing tolerance. Four herbaceous and six woody plants were hardened under natural or artificial conditions and – after determination of their frost resistance (LT₅₀) – the net photosynthetic rate at an ambient CO₂ of 33 Pa (P_n33), the dependencies of P_n to light and to CO₂ and the room temperature chlorophyll a fluorescence were recorded under optimal conditions. Herbaceous plants acquired freezing tolerances to temperatures between ?10 and ?15°C when hardened at temperatures around 0°C. Most leaves fully developed prior to frost hardening exhibited typical symptoms of senescence after frost hardening. In non-senescing leaves P_n33 was reduced by 15 to 50% mainly due to a reduced stomatal conductance. After hardening at temperatures around ?10°C Brassica survived down to ?24°C, but P_n33 was almost abolished as a result of disturbances in the chloroplasts. After transferring the plants to 20/15°C P_n33 recovered completely within a few days. Woody plants hardened at temperatures around 0°C tolerated – 15 to ?36°C: P_n33 was reduced by 25 to 60% and hardly recovered at 20/15°C. Hardening at ?10°C induced a tolerance of ?32 to n33 was almost totally blocked, but at 20/15°C it returned to the values of the plants hardened at 0°C within a few days. In woody plants disturbances were invariably localized in the chloroplasts. Thus, conifers, and especially Pinus cembra, can survive much lower temperatures than herbaceous plants and, at the same level of freezing tolerance, exhibit appreciably less restriction in relative P_n33.     

Diffusive and metabolic limitations to photosynthesis under drought and salinity in C(3) plants

Drought and salinity are two widespread environmental conditions leading to low water availability for plants. Low water availability is considered the main environmental factor limiting photosynthesis and, consequently, plant growth and yield worldwide. There has been a long-standing controversy as to whether drought and salt stresses mainly limit photosynthesis through diffusive resistances or by metabolic impairment. Reviewing in vitro and in vivo measurements, it is concluded that salt and drought stress predominantly affect diffusion of CO(2) in the leaves through a decrease of stomatal and mesophyll conductances, but not the biochemical capacity to assimilate CO(2), at mild to rather severe stress levels. The general failure of metabolism observed at more severe stress suggests the occurrence of secondary oxidative stresses, particularly under high-light conditions. Estimates of photosynthetic limitations based on the photosynthetic response to intercellular CO(2) may lead to artefactual conclusions, even if patchy stomatal closure and the relative increase of cuticular conductance are taken into account, as decreasing mesophyll conductance can cause the CO(2) concentration in chloroplasts of stressed leaves to be considerably lower than the intercellular CO(2) concentration. Measurements based on the photosynthetic response to chloroplast CO(2) often confirm that the photosynthetic capacity is preserved but photosynthesis is limited by diffusive resistances in drought and salt-stressed leaves.     

Monosaccharide transporters in plants: structure, function and physiology

Monosaccharide transport across the plant plasma membrane plays an important role both in lower and higher plants. Algae can switch between phototrophic and heterotrophic growth and utilize organic compounds, such as monosaccharides as additional or sole carbon sources. Higher plants represent complex mosaics of phototrophic and heterotrophic cells and tissues and depend on the activity of numerous transporters for the correct partitioning of assimilated carbon between their different organs. The cloning of monosaccharide transporter genes and cDNAs identified closely related integral membrane proteins with 12 transmembrane helices exhibiting significant homology to monosaccharide transporters from yeast, bacteria and mammals. Structural analyses performed with several members of this transporter superfamily identified protein domains or even specific amino acid residues putatively involved in substrate binding and specificity. Expression of plant monosaccharide transporter cDNAs in yeast cells and frog oocytes allowed the characterization of substrate specificities and kinetic parameters. Immunohistochemical studies, in situ hybridization analyses and studies performed with transgenic plants expressing reporter genes under the control of promoters from specific monosaccharide transporter genes allowed the localization of the transport proteins or revealed the sites of gene expression. Higher plants possess large families of monosaccharide transporter genes and each of the encoded proteins seems to have a specific function often confined to a limited number of cells and regulated both developmentally and by environmental stimuli.     

Stimulation of respiration by Pb2+ in detached leaves and mitochondria of C3 and C4 plants

The exposure of detached leaves of C₃ plants (pea, barley) and C₄ plant (maize) to 5 m M Pb (NO₃)₂ for 24 h caused a reduction of their photosynthetic activity by 40–60%, whereas the respiratory rate was stimulated by 20–50%. Mitochondria isolated from Pb²⁺-treated pea leaves oxidized substrates (glycine, succinate, malate) at higher rates than mitochondria from control leaves. The respiratory control (RCR) and the ADP/O ratio were not affected. Pb²⁺ caused an increase in ATP content and the ATP/ADP ratio in pea and maize leaves. Rapid fractionation of barley protoplasts incubated at low and high CO₂ conditions, indicated that the increased ATP/ADP ratio in Pb²⁺-treated leaves resulted mainly from the production of mitochondrial ATP. The measurements of membrane potential of mitochondria with a TPP⁺-sensitive electrode further showed that mitochondria isolated from Pb²⁺-treated leaves had at least as high membrane potential as mitochondria from control leaves. The activity of NAD-malate dehydrogenase in the protoplasts from barley leaves treated with Pb²⁺ was 3-fold higher than in protoplasts from control leaves. The activities of photorespiratory enzymes NADH-hydroxypyruvate reductase and glycolate oxidase as well as of NAD-malic enzyme were not affected. The presented data indicate that stimulation of respiration in leaves treated by lead is in a close relationship with activation of malate dehydrogenase and stimulation of the mitochondrial ATP production. Thus, respiration might fulfil a protective role during heavy metal exposure.     

Dramatic difference in the responses of phosphoenolpyruvate carboxylase to temperature in leaves of C3 and C4 plants

Temperature caused phenomenal modulation of phosphoenolpyruvate carboxylase (PEPC, EC 4.1.1.31) in leaf discs of Amaranthus hypochondriacus (NAD-ME type C(4) species), compared to the pattern in Pisum sativum (a C(3) plant). The optimal incubation temperature for PEPC in A. hypochondriacus (C(4)) was 45 degrees C compared to 30 degrees C in P. sativum (C(3)). A. hypochondriacus (C(4)) lost nearly 70% of PEPC activity on exposure to a low temperature of 15 degrees C, compared to only about a 35% loss in the case of P. sativum (C(3)). Thus, the C(4) enzyme was less sensitive to supra-optimal temperature and more sensitive to sub-optimal temperature than that of the C(3) species. As the temperature was raised from 15 degrees C to 50 degrees C, there was a sharp decrease in malate sensitivity of PEPC. The extent of such a decrease in C(4) plants (45%) was more than that in C(3) species (30%). The maintenance of high enzyme activity at warm temperatures, together with a sharp decrease in the malate sensitivity of PEPC was also noticed in other C(4) plants. The temperature-induced changes in PEPC of both A. hypochondriacus (C(4)) and P. sativum (C(3)) were reversible to a large extent. There was no difference in the extent of phosphorylation of PEPC in leaves of A. hypochondriacus on exposure to varying temperatures, unlike the marked increase in the phosphorylation of enzyme on illumination of the leaves. These results demonstrate that (i) there are marked differences in the temperature sensitivity of PEPC in C(3) and C(4) plants, (ii) the temperature induced changes are reversible, and (iii) these changes are not related to the phosphorylation state of the enzyme. The inclusion of PEG-6000, during the assay, dampened the modulation by temperature of malate sensitivity of PEPC in A. hypochondriacus. It is suggested that the variation in temperature may cause significant conformational changes in C(4)-PEPC.     

Light-induced pH changes in leaves of C4 plants

Light-induced changes in the fluorescence of the pH-indicating dyes pyranine or 5-(and 6-)carboxy-2, 7-dichlorofluorescein (CDCF) which had been fed to leaves were examined to monitor cellular pH changes. After short-term feeding of pyranine (pK 7.3) to leaves of Amaranthus caudatus L., a NAD-malic-enzyme-type C₄ plant, vascular bundles and surrounding cells became fluorescent. Fluorescence emission from mesophyll cells required longer feeding times. In CO₂-free air, pyranine fluorescence increased much more on illumination after mesophyll cells had become fluorescent than when only the vascular bundles and the bundle sheath of Amaranthus leaves had been stained. After short feeding times and in the absence of actinic illumination, CO₂ decreased pyranine fluorescence very slowly in Amaranthus and rapidly in C₃ leaves. After prolonged feeding times, the extent of the light-dependent increase in pyranine fluorescence was several times greater in different C₄ plants than in C₃ species. The kinetics of the fluorescence changes were also remarkably different in C₃ and C₄ plants. Carbon dioxide (500 l · l^–1) suppressed the light-induced increase in pyranine fluorescence more in C₄ than in C₃ leaves. Light-dependent changes in light scattering, which are indicative of chloroplast energization, and in 410-nm transmission, which indicate chloroplast movement, differed kinetically from those of the changes in pyranine fluorescence. Available evidence indicated that light-dependent changes in pyranine fluorescence did not originate from the apoplast of leaf cells. Microscopic observation led to the conclusion that, after prolonged feeding times or prolonged incubation, changes in pyranine fluorescence emitted from C₄ leaves reflect pH changes mainly in the cytosol of mesophyll cells. A transient acidification reaction indicated by quenching of pyranine fluorescence in the dark-light transient and not observed in C₃ species is attributed to the carboxylation of phosphoenolpyruvate. After short feeding times and in the absence of actinic illumination, CO₂ (250 l l^–1) decreased pyranine fluorescence very slowly in Amaranthus and more rapidly in C₃ leaves. After prolonged feeding times, both the rate and the extent of CO₂-dependent quenching of pyranine fluorescence increased, but the increase was insufficient to indicate the presence of highly active carbonic anhydrase in the compartment from which pyranine fluorescence was emitted. In contrast to pyranine, CDCF (pK 4.8) did not increase but rather decreased its fluorescence on illumination of an Amaranthus leaf, indicating acidification of an acidic compartment, most probably the vacuole of green leaf cells. The pattern of the acidification reaction was similar in C₄ and C₃ leaves. The remarkably large extent of the light-dependent increase in pyranine fluorescence from leaves of C₄ species and its slow kinetics are proposed to be caused by an alkalization of the cytosol which in the absence of CO₂ is larger in the mesophyll than in the bundle sheath. It gives rise to deprotonation of dye originally located in the mesophyll and, in addition, of dye which diffuses from the bundle sheath into the mesophyll following a pH gradient. Implications of slow diffusional transport of pyranine and CO₂ between mesophyll and bundle-sheath cells and the fast metabolite transport required in C₄ photosynthesis are discussed.Abbreviations CDCF 5-(and 6-)carboxy-2,7-dichlorofluorescein - DHAP dihydroxyacetone phosphate - PGA 3-phosphoglycerate This work was supported by the Sonderforschungsbereiche 176 and 251 of the University of Würzburg and by the Gottfried-Wilhelm-Leibniz Program of the Deutsche Forschungsgemeinschaft. A.S.R. was the recipient of a fellowship of the Alexander-von-Humboldt Foundation. We are grateful to Mrs. S. Neimanis for cooperation.