Guard cell apoplastic photosynthate accumulation corresponds to a phloem-loading mechanism

Apoplastic phloem loaders have an apoplastic step in the movement of the translocated sugar, prototypically sucrose, from the mesophyll to the companion cell-sieve tube element complex. In these plants, leaf apoplastic sucrose becomes concentrated in the guard cell wall to nominally 150 mM by transpiration during the photoperiod. This concentration of external sucrose is sufficient to diminish stomatal aperture size in an isolated system and to regulate expression of certain genes. In contrast to apoplastic phloem loaders and at the other extreme, strict symplastic phloem loaders lack an apoplastic step in phloem loading and mostly transport raffinose family oligosaccharides (RFOs), which are at low concentrations in the leaf apoplast. Here, the effects of the phloem-loading mechanism and associated phenomena on the immediate environment of guard cells are reported. As a first step, carbohydrate analyses of phloem exudates confirmed basil (Ocimum basilicum L. cv. Minimum) as a symplastic phloem-loading species. Then, aspects of stomatal physiology of basil were characterized to establish this plant as a symplastic phloem-loading model species for guard cell research. [(14)C]Mannitol fed via the cut petiole accumulated around guard cells, indicating a continuous leaf apoplast. The (RFO+sucrose+hexoses) concentrations in the leaf apoplast were low, <0.3 mM. Neither RFOs (<10 mM), sucrose, nor hexoses (all, P >0.2) were detectable in the guard cell wall. Thus, differences in phloem-loading mechanisms predict differences in the in planta regulatory environment of guard cells.     

Transpiration rate. An important factor controlling the sucrose content of the guard cell apoplast of broad bean

Evaporation of water from the guard cell wall concentrates apoplastic solutes. We hypothesize that this phenomenon provides two mechanisms for responding to high transpiration rates. First, apoplastic abscisic acid is concentrated in the guard cell wall. Second, by accumulating in the guard cell wall, apoplastic sucrose (Suc) provides a direct osmotic feedback to guard cells. As a means of testing this second hypothesized mechanism, the guard cell Suc contents at a higher transpiration rate (60% relative humidity [RH]) were compared with those at a lower transpiration rate (90% RH) in broad bean (Vicia faba), an apoplastic phloem loader. In control plants (constant 60% RH), the guard cell apoplast Suc content increased from 97 +/- 81 femtomol (fmol) guard cell pair(-1) to 701 +/- 142 fmol guard cell pair(-1) between daybreak and midday. This increase is equivalent to approximately 150 mM external, which is sufficient to decrease stomatal aperture size. In plants that were shifted to 90% RH before daybreak, the guard cell apoplast Suc content did not increase during the day. In accordance, in plants that were shifted to 90% RH at midday, the guard cell apoplast Suc content declined to the daybreak value. Under all conditions, the guard cell symplast Suc content increased during the photoperiod, but the guard cell symplast Suc content was higher (836 +/- 33 fmol guard cell pair(-1)) in plants that were shifted to 90% RH. These results indicate that a high transpiration rate may result in a high guard cell apoplast Suc concentration, which diminishes stomatal aperture size.     

Accumulation of an apoplastic solute in the guard-cell wall is sufficient to exert a significant effect on transpiration in Vicia faba leaflets

Accumulation of recently photosynthesized sucrose in the guard‐cell wall is the empirical foundation for a hypothesis that links the rates of photosynthesis, translocation, and transpiration (Plant Physiology 114, 109–118). Critical assumptions of this hypothesis were tested by use of Vicia faba, an apoplastic phloem loader. Following measurements of the leaflet‐apoplastic‐water volume (by P–V isotherm analysis) and the guard‐cell wall volume (by 3‐D analysis), intact leaflets were fed dilute solutions of mannitol, an impermeant non‐toxic osmolyte. Even at bulk‐leaflet mannitol concentrations that would have only a negligible osmotic effect on stomata, transpiration at constant temperature, water‐vapour pressure, air movement and irradiance was diminished up to 25%, compared with controls. This effect on transpiration, a manifestation of smaller stomatal aperture size, was explained by accumulation of mannitol, up to 350 mol m ^{? 3}, in the estimated aqueous volume of the guard‐cell wall. The conclusion is that mannitol, a xenobiotic with structural similarity to sucrose, can move throughout the apoplast of a transpiring leaflet and accumulate in an osmotically significant concentration in the guard‐cell wall. These data therefore provide support for a new role for sucrose as a signal metabolite that integrates essential functions of the whole leaf. In addition, the results raise questions about the physiological or experimental accumulation of other guard‐cell‐targeted apoplastic solutes such as plant growth regulators, particularly abscisic acid, and ions.     

A New Mechanism for the Regulation of Stomatal Aperture Size in Intact Leaves (Accumulation of Mesophyll-Derived Sucrose in the Guard-Cell Wall of Vicia faba)

At various times after pulse-labeling broad bean (Vicia faba L.) leaflets with 14CO2, whole-leaf pieces and rinsed epidermal peels were harvested and subsequently processed for histochemical analysis. Cells dissected from whole leaf retained apoplastic contents, whereas those from rinsed peels contained only symplastic contents. Sucrose (Suc)-specific radioactivity peaked (111 GBq mol-1) in palisade cells at 20 min. In contrast, the 14C content and Sucspecific radioactivity were very low in guard cells for 20 min, implying little CO2 incorporation; both then peaked at 40 min. The guard-cell apoplast had a high maximum Suc-specific radioactivity (204 GBq mol-1) and a high Suc influx rate (0.05 pmol stoma-1 min-1). These and other comparisons implied the presence of (a) multiple Suc pools in mesophyll cells, (b) a localized mesophyll-apoplast region that exchanges with phloem and stomata, and (c) mesophyll-derived Suc in guard-cell walls sufficient to diminish stomatal opening by approximately 3 [mu]m. Factors expected to enhance Suc accumulation in guard-cell walls are (a) high transpiration rate, which closes stomata, and (b) high apoplastic Suc concentration, which is elevated when mesophyll Suc efflux exceeds translocation. Therefore, multiple physiological factors are integrated in the attenuation of stomatal aperture size by this previously unrecognized mechanism.     

Changes in stomatal behaviour in the calcicole Leontodon hispidus due to the disruption by ozone of the regulation of apoplastic Ca2+ by trichomes

Regulation of the concentration of Ca2+ in the apoplast of plants is essential in order to allow Ca(2+)-dependent processes, such as Ca(2+)-mediated signal transduction in stomatal guard cells, to function correctly. This is particularly important for plants growing with high levels of Ca2+ in the rhizosphere. Recently, we have shown that in two calcicoles, Leontodon hispidus L. and Centaurea scabiosa L., trichomes play a key role in this regulatory process. Ozone is known to have a marked effect on plant Ca2+ homeostasis. Therefore, we have examined the effect of this pollutant on the regulation by trichomes of apoplastic Ca2+ in the calcicole L. hispidus. Treatment with 100 nl l-1 ozone resulted in a reduction in stomatal conductance of approximately 25% in plants grown with 15 mM Ca2+ in the rhizosphere. Analysis of total Ca2+ levels revealed that these changes in stomatal behaviour reflect a decrease in the ability of trichomes to sequester Ca2+. The amount of Ca2+ present in the trichome tip cell was reduced by approximately 38%. This was accompanied by an increase in the levels of Ca2+ in the guard cells and other tissues of the leaf. These data suggest that ozone has a detrimental effect on the ability of trichomes to regulate the concentration of apoplastic Ca2+ in L. hispidus, resulting in altered stomatal behaviour, and hence gaseous exchange, possibly due to the disruption of guard-cell Ca(2+)-mediated signal transduction. This has important implications for the growth and survival of plants growing in Ca(2+)-rich soils.     

Abscisic acid in apoplastic sap can account for the restriction in leaf conductance of white lupins during moderate soil drying and after rewatering

We studied the effects of drought on leaf conductance (g) and on the concentration of abscisic acid (ABA) in the apoplastic sap of Lupinus albus L. leaves. Withholding watering for 5d resulted in complete stomatal closure and in severe leaf water deficit. Leaf water potential fully recovered immediately after rewatering, but the aftereffect of drought on stomata persisted for 2d. ABA and sucrose were quantified in pressurized leaf xylem extrudates. We assumed that the xylem sucrose concentration is negligible and hence that the presence of sucrose in leaf extrudates indicated that they were contaminated by phloem. To eliminate this interference, the concentration of ABA in leaf apoplast was estimated by extrapolation to zero sucrose concentration, using the regression between ABA and sucrose concentrations. The estimated apoplastic ABA concentration increased by 100-fold with soil drying and did not return to pre-stress values immediately following rewatering. g was closely related to the concentration of ABA in leaf apoplast. Furthermore, the feeding of exogenous ABA to leaves detached from well-watered plants brought about the same degree of depression in g as resulted from the drought-induced increase in ABA concentration. We therefore conclude that the observed changes in the concentration of ABA in leaf apoplast were quantitatively adequate to explain drought-induced stomatal closure and the delay in stomatal reopening following rewatering.     

Modification of leaf apoplastic pH in relation to stomatal sensitivity to root-sourced abscisic acid signals

The confocal microscope was used to determine the pH of the leaf apoplast and the pH of microvolumes of xylem sap. We quantified variation in leaf apoplast and sap pH in relation to changes in edaphic and atmospheric conditions that impacted on stomatal sensitivity to a root-sourced abscisic acid signal. Several plant species showed significant changes in the pH of both xylem sap and the apoplast of the shoot in response to environmental perturbation. Xylem sap leaving the root was generally more acidic than sap in the midrib and the apoplast of the leaf. Increasing the transpiration rate of both intact plants and detached plant parts resulted in more acidic leaf apoplast pHs. Experiments with inhibitors suggested that protons are removed from xylem sap as it moves up the plant, thereby alkalinizing the sap. The more rapid the transpiration rate and the shorter the time that the sap resided in the xylem/apoplastic pathway, the smaller the impact of proton removal on sap pH. Sap pH of sunflower (Helianthus annuus) and Commelina communis did not change significantly as soil dried, while pH of tomato (Lycopersicon esculentum) sap increased as water availability in the soil declined. Increasing the availability of nitrate to roots also significantly alkalinized the xylem sap of tomato plants. This nitrogen treatment had the effect of enhancing the sensitivity of the stomatal response to soil drying. These responses were interpreted as an effect of nitrate addition on sap pH and closure of stomata via an abscisic acid-based mechanism.     

Changes in apoplastic and intracellular leaf sugars induced by the blocking of export in Vicia faba

Sugar export by broadbean ( Vicia faba L. cv. Aguadulce) was blocked by a cold jacket (1 cm-width, 1°C) applied on the petiole of a mature leaf or by heat-girdling the petiole. A time course study was made on the effects of these treatments on apoplastic and intracellular soluble sugars of the leaf in relation to phloem loading and photosynthesis. Blocking of export by heat-girdling induced an inhibition of phloem loading within 10 min, an accumulation of starch within 30 min and a rise in apoplastic sucrose within 60 min. By contrast, apoplastic hexoses and photosynthesis were not affected by this treatment within 8 h and intracellular sugars were not affected within 2 h. The cold jacket also increased the sucrose content of the apoplast. The increase in apoplastic sucrose induced by the cold barrier is reversed upon rewarming and less marked when the sink/source ratio is increased by defoliating all but the leaves studied. The results are discussed in terms of sink/source relationships. They show that the increase in apoplastic sucrose resulting from inhibition of loading is not part of the events leading from blocking of transport to change in carbon partitioning.     

The guard-cell apoplast as a site of abscisic acid accumulation in Vicia faba L.

Abscisic acid (ABA) integrates the water status of a plant and causes stomatal closure. Physiological mechanisms remain poorly understood, however, because guard cells flanking stomata are small and contain only attomol quantities of ABA. Here, pooled extracts of dissected guard cells of Vicia faba L. were immunoassayed for ABA at sub‐fmol sensitivity. A pulse of water stress was imposed by submerging the roots in a solution of PEG. The water potentials of root and leaf declined during 20 min of water stress but recovered after stress relief. During stress, the ABA concentration in the root apoplast increased, but that in the leaf apoplast remained low. The ABA concentration in the guard‐cell apoplast increased during stress, providing evidence for intra‐leaf ABA redistribution and leaf apoplastic heterogeneity. Subsequently, the ABA concentration of the leaf apoplast increased, consistent with ABA import via the xylem. Throughout, the ABA contents of the guard‐cell apoplast, but not the guard‐cell symplast, were convincingly correlated with stomatal aperture size, identifying an external locus for ABA perception under these conditions. Apparently, ABA accumulates in the guard‐cell apoplast by evaporation from the guard‐cell wall, so the ABA signal in the xylem is amplified maximally at high transpiration rates. Thus, stomata will display apparently higher sensitivity to leaf apoplastic ABA if stomata are widely open in a relatively dry atmosphere.     

Energized Uptake of Sugars from the Apoplast of Leaves: A Study of Some Plants Possessing Different Minor Vein Anatomy

Solutions of sucrose, glucose, raffinose, and stachyose were fed via the petiole to detached leaves of plant species known to transfer sugars during photosynthesis into the phloem using either the apoplastic or the symplastic pathway of phloem loading. Symplastic phloem loaders, which translocate raffinose-type oligosaccharides and sucrose in the phloem, and apoplastic plants, translocating exclusively sucrose, were selected for this study. As the sugars arrived with the transpiration stream in the leaf blade within little more than a minute, dark respiration increased. Almost simultaneously, fluorescence of a potential-indicating dye, which had been infiltrated into the leaves, indicated membrane depolarization. Another fluorescent dye used to record the apoplastic pH revealed apoplastic alkalinization that occurred with a slight lag phase after respiration and membrane depolarization responses. Occasionally, alkalinization was preceded by transient apoplastic acidification. Whereas membrane depolarization and apoplastic acidification are interpreted as initial responses of the proton motive force across the plasma membrane to the advent of sugars in the leaf apoplast, the following apoplastic alkalinization showed that sugars were taken up from the apoplast into the symplast in cotransport with protons. This was true not only for glucose and sucrose, but also for raffinose and stachyose. Similar observations were made for sugar uptake not only in leaves of plants known to export sugars by symplastic phloem loading but also of plants using the apoplastic pathway. Increased respiration during sugar uptake revealed tight coupling between respiratory ATP production and ATP consumption by proton-translocating ATPase of the plasma membrane, which exports protons into the apoplast, thereby compensating for the proton loss in the apoplast when protons are transported together with sugars into the symplast. The extent of stimulation of respiration by sugars indicated that sugar uptake was not limited to phloem tissue. Ratios of the extra CO₂ released during sugar uptake to the amounts of sugars taken up were variable, but lowest values were lower than 0.2. When a ratio of 0.2 is taken as a basis to calculate rates of sugar uptake from observed maxima of sugar-dependent increases in respiration, rates of sugar uptake approached 350 nmol/(m² leaf surface s). Sugar uptake rates were half-saturated at sugar concentrations in the feeding solutions of about 10–25 mM indicating a low in vivo affinity of sugar uptake systems for sugars.     

pH regulation in apoplastic and cytoplasmic cell compartments of leaves

 The regulation of pH in the apoplast, cytosol and chloroplasts of intact leaves was studied by means of fluorescent pH indicators and as a response of photosynthesis to acid stress. The apoplastic pH increased under anaerobiosis. Aeration reversed this effect. Apoplastic responses to CO₂, HCl or NH₃ differed considerably. Whereas HCl and ammonia caused rapid acidification or alkalinization, the return to initial pH values was slow after cessation of fumigation. Addition of CO₂ either did not produce the acidification expected on the basis of known apoplastic buffering or even caused some alkalinization. Removal of CO₂ shifted the apoplastic pH into the alkaline range before the pH returned to initial steady-state levels. In the presence of vanadate, the alkaline shift was absent and the apoplastic pH returned slowly to the initial level when CO₂ was removed from the atmosphere. In contrast to the response of the apoplast, anaerobiosis acidified the cytosol or, in some species, had little effect on its pH. Acidification was rapidly reversed upon re-admission of oxygen. The CO₂-dependent pH changes were very fast in the cytosol. Considerable alkalinization was observed after removal of CO₂ under aerobic, but not under anaerobic conditions. Rates of the re-entry of protons into the cytosol during recovery from CO₂ stress increased in the presence of oxygen with the length of previous exposure to high CO₂. Effective pH regulation in the chloroplasts was indicated by the recovery of photosynthesis after the transient inhibition of photosynthetic electron flow when CO₂ was increased from 0.038% to 16% in air. As photosynthesis became inhibited under high CO₂, reduction of the electron transport chain increased transiently. The time required for recovery of photosynthesis from inhibition during persistent CO₂ stress was similar to the time required for establishing steady-state pH values in the cytosol under acid stress. The high capacity of leaf cells for the rapid re-attainment of pH homeostasis in the apoplast and the cytoplasm under acid or alkaline stress suggested the rapid activation or deactivation of membrane-localised proton-transporting enzymes and corresponding ion channel regulation for co-transport of anions or counter-transport of cations together with proton fluxes. Acidification of the cytoplasm appeared to activate energy-dependent proton export primarily into the vacuoles whereas apoplastic alkalinization resulted in the pumping of protons into the apoplast. Proton export rates from the cytosol into the apoplast after anaerobiosis were about 100 nmol (m² leaf area)⁻¹ s⁻¹ or less. Proton export under acid stress into the vacuole was about 1200 nmol m⁻² s⁻¹. The kinetics of pH responses to the addition or withdrawal of CO₂ indicated the presence of carbonic anhydrase in the cytosol, but not in the apoplast. Received: 19 July 1999 / Accepted: 29 December 1999     

Changes in apoplastic pH and membrane potential in leaves in relation to stomatal responses to CO2, malate, abscisic acid or interruption of water supply

Low CO2 concentrations open CO2-sensitive stomata whereas elevated CO2 levels close them. This CO2 response is maintained in the dark. To elucidate mechanisms underlying the dark CO2 response we introduced pH- and potential-sensitive dyes into the apoplast of leaves. After mounting excised leaves in a gas-exchange chamber, changes in extracellular proton concentration and transmembrane potential differences as well as transpiration and respiration were simultaneously monitored. Upon an increase in CO2 concentration transient changes in apoplastic pH (occasionally brief acidification, but always followed by alkalinization) and in membrane potential (brief hyperpolarization followed by depolarization) accompanied stomatal closure. Alkalinization and depolarization were also observed when leaves were challenged with abscisic acid or when water flow was interrupted. During stomatal opening in response to CO2-free air the apoplastic pH increased while the membrane potential initially depolarized before it transiently hyperpolarized. To examine whether changes in apoplastic malate concentrations represent a closing signal for stomata, malate was fed into the transpiration stream. Although malate caused apoplastic alkalinization and membrane depolarization reminiscent of the effects observed with CO2 and abscisic acid, this dicarboxylate closed the stomata only partially and less effectively than CO2. Apoplastic alkalinization was also observed and stomata closed partially when KCl was fed to the leaves. Respiration increased on feeding of malate or KCl, or while abscisic acid closed the stomate. From these results we conclude that CO2 signals modulate the activity of plasma-membrane ion channels and of plasmalemma H+-ATPases during changes in stomatal aperture. Responses to potassium malate and KCl are not restricted to guard cells and neighbouring cells.     

Compartmentation of Assimilate Fluxes in Leaves

Abstract: Sugar levels in the apoplast of assimilate exporting leaves were studied in two groups of plant species with contrasting structures of companion cells in minor veins. These species are termed either "symplastic" (with intermediary cells) or "apoplastic" (with transfer or ordinary cells). Sugars were measured in intercellular washing fluid after extracting the apoplast by an infiltration-centrifugation technique. During the course of a day, sugar contents in the apoplast were, in general, lower in species with intermediary cells than in species with transfer or ordinary cells. In "symplastic" species, apoplastic sucrose concentrations were between 0.3 and 1 mM. In "apoplastic" species with transfer cells, they ranged between 2 and 6 mM. Apoplastic hexose contents were between 0.3 and 1 mM irrespective of presumed transport mode. "Symplastic" and "apoplastic" plants differed markedly in their response to a'translocation block. In "symplastic" plants, inhibition of assimilate export left apoplastic concentrations of sucrose and hexoses unchanged, whereas in "apoplastic" plants sugar levels increased, the maximal increase being observed with sucrose. In these plants, concentrations of sucrose were two to six times higher in the apoplast under export inhibition than in control leaves. The data suggest a different role of the leaf apoplast in the compartmentation and export of assimilates in the two plant groups under study.     

Role of the Apoplast in the Control of Assimilate Transport,Photosynthesis, and Plant Productivity

A concept is suggested, which supposes that assimilates are transferred within the plant downward through phloem sieve tubes and, after entering the stem apoplast, are carried up with the ascending flow of transpiration water. After entering the apoplast of fully expanded leaves, these solutes are reexported through the phloem. Thus, a common pool of assimilates with uniform concentration is formed in the plant apoplast. According to this concept, the mechanism of assimilate demand represents a response of photosynthetic apparatus to changes in the apoplastic level of metabolites consumed by sink organs. The ratios of labeled photoassimilates differ between the apoplast and mesophyll cells. Most of the apoplastic labeled carbon is contained in sucrose, less in amino acids, and even less in hexoses. The ¹⁴C-labeling of amino acids increases and the sucrose/hexose labeling ratio decreased under conditions of enhanced nitrate supply. The well-known effect of relative inhibition of assimilate export from leaves under conditions of enhanced nitrogen supply is explained by an enhanced hydrolysis of apoplast-derived sucrose due to the increase in invertase activity, rather than by diversion of primary photosynthetic products from sucrose synthesis to other pathways required for activated growth processes in leaves. This notion is based on observations that the sucrose/hexose ratio is reduced to a greater extent in the apoplast than in the symplast. The last assumption was supported by data obtained after artificial changes in the apoplastic pH. In these experiments intact plants were placed in the atmosphere of NH₃ or HCl vapors, which induced opposite changes in relative content of labeled assimilates in the apoplast and in the photosynthetic rate.     

High apoplastic solute concentrations in leaves alter water relations of the halophytic shrub, Sarcobatus vermiculatus

Predawn plant water potential (Psi(w)) is used to estimate soil moisture available to plants because plants are expected to equilibrate with the root-zone Psi(w). Although this equilibrium assumption provides the basis for interpreting many physiological and ecological parameters, much work suggests predawn plant Psi(w) is often more negative than root-zone soil Psi(w). For many halophytes even when soils are well-watered and night-time shoot and root water loss eliminated, predawn disequilibrium (PDD) between leaf and soil Psi(w) can exceed 0.5 MPa. A model halophyte, Sarcobatus vermiculatus, was used to test the predictions that low predawn solute potential (Psi(s)) in the leaf apoplast is a major mechanism driving PDD and that low Psi(s) is due to high Na+ and K+ concentrations in the leaf apoplast. Measurements of leaf cell turgor (Psi(p)) and solute potential (Psi(s)) of plants grown under a range of soil salinities demonstrated that predawn symplast Psi(w) was 1.7 to 2.1 MPa more negative than predawn xylem Psi(w), indicating a significant negative apoplastic Psi(s). Measurements on isolated apoplastic fluid indicated that Na+ concentrations in the leaf apoplast ranged from 80 to 230 mM, depending on salinity, while apoplastic K+ remained around 50 mM. The water relations measurements suggest that without a low apoplastic Psi(s), predawn Psi(p) may reach pressures that could cause cell damage. It is proposed that low predawn apoplastic Psi(s) may be an efficient way to regulate Psi(p) in plants that accumulate high concentrations of osmotica or when plants are subject to fluctuating patterns of soil water availability.     

Photosynthetic carbon metabolism in potato leaves under changes in light intensity

Photosynthetic assimilation of ¹⁴CO₂ was examined in leaves of potato (Solanum tuberosum L.) plants that were grown under direct sunlight and then transferred to 50% irradiance for various periods. The rate of ¹⁴CO₂ assimilation correlated with light intensity: the photosynthetic rate reduced by 52% after 5-day shading and by 70% after 30-min shading. In all shaded and shade-adapted plants, the sucrose/hexose ratio decreased by a factor of 3.5–4.1; furthermore, the radioactivity of glycolate cycle metabolites and the serine/glycine ratio were lowered. In plants shaded for 5 days or 30 min, the radioactivity of aspartate and malate was higher than at continuous high irradiance, especially in plants shaded for 30 min, whereas a sudden illumination of the shaded plants reduced the radioactivity of these substances. We suppose that low irradiance averted the reentry of glycolate path carbon into the Calvin cycle and redirected this carbon source for the production of four-carbon acids that acidified the apoplast. This acidification activated the apoplastic invertase, which enhanced sucrose hydrolysis and hindered the sucrose export from the leaf. Hydrolysis of sucrose promoted the increase in osmolarity of the apoplastic solution, this increase being stronger at close distances to the stomatal pores where water is intensely evaporated. The increase in osmolarity of extracellular medium led to closing of stomata and the suppression of photosynthesis.     

Pathway of phloem loading in the C3 tropical orchid hybrid Oncidium Goldiana

The apoplast of mature leaves of the tropical orchid OncidiumGoldiana was perfused with 0.5 mM p-chloromercuribenzenesulphonicacid (PCMBS) via the transpiration stream in order to test themode of phloem loading. The efficacy of introducing PCMBS byperfusion was shown by saffranin O dye movement in the veinsand leaf apoplast in control experiments. Photoassimilate exportas the result of phloem loading was measured by collection of¹⁴CO₂-derived photoassimilates from the basal cut-ends of intactleaves. Phloem loading and translocation of photoassimilates was inhibitedby 89% in leaves perfused with PCMBS for 1 h. The effect ofPCMBS on leaf photosynthesis was minimal. The amount of radiocarbonfixed by PCMBS-treated leaves averaged 89% of control leavesperfused with distilled water. A negative correlation betweenthe total amount of photoassimilate exuded and the calculatedconcentration of PCMBS in the leaf apoplast was also observed.The results indicate that phloem loading in Oncidium Goldianaoccurs via the apoplastic pathway. Key words: Phloem loading, apoplast, PCMBS, tropical orchid     

The Effect of Salinity upon Photosynthesis in Rice (Oryza sativa L.): Gas Exchange by Individual Leaves in relation to their Salt Content

Yeo, A. R., Caporn, S. J. M.and Flowers, T. J. 1985. The effectof salinity upon photosynthesis in rice (Oryza sativa L.): Gasexchange by individual leaves in relation to their salt content.—J.exp. Bot. 36: 1240–1248. The effect of salinity upon net photosynthesis and transpirationby individual leaves of rice has been investigated by gas exchangemeasurements in seedlings at the five to six leaf stage. Salinitydid not, initially, reduce net photosynthesis in the whole plantbut only in the older leaves in which sodium accumulated. Analysisof the course of events in leaf four following salinizationof the medium showed that net photosynthesis was inversely correlatedwith the sodium concentration in the leaf tissue. There wasno evidence of a threshold effect; net photosynthesis declinedlinearly with increasing leaf sodium concentration and was reducedby 50% at only 05 mmol sodium per gram dry weight. The relationshipbetween transpiration rate and leaf sodium concentration closelyparalleled that for photosynthesis; there was no effect of leafsodium concentration on the carbon dioxide concentration inthe intercellular spaces, showing that sodium accumulation inthe leaf affected stomatal aperture and carbon dioxide fixationsimultaneously. Photosynthesis was reduced by half at a sodiumconcentration in the leaf which did not reduce the concentrationof chlorophyll. The nature of the effect of salinity upon leafgas exchange is discussed. Key words: Salinity, rice, Oryza sativa L., photosynthesis, apoplastic salt load     

The fate of apoplastic sucrose in sink and source leaves of Urtica dioica

Experiments were performed with developing and mature leaves of Urtica dioica L. to trace differences which could be interpreted in terms of cell wall-bound acid invertase (EC 3.2.1.26) participating in phloem unloading in a sink leaf. The pH of apoplastic fluid that was collected by gentle centrifugation of entire leaves was identical (7.1) in the two types of leaves; also, fluorometric determination with esculetin showed a neutral apoplastic pH between 7.0 in the source and 7.2 in the sink leaf. To detect whether differences in apoplastic pH occur within limited leaf areas, such as of the tissue surrounding the veins, the metabolic fate of [¹⁴C]–(fructosyl)-sucrose that was administered via the xylem was investigated. In source leaves, there was a large transitory decrease in [¹⁴C]-sucrose followed by a substantial resynthesis of this compound. In sink leaves, resynthesis was less significant and carbon was incorporated mainly in starch, charged soluble compounds and cell walls. However, after correction for resynthesis, the two types of leaves showed an identical capacity for sucrose cleavage. Finally, activation of the apoplastic invertase by administering labelled sucrose in buffered solution of pH 5.0 did not result in an enhanced degradation. By contrast, apoplastic fluid collected from leaves which had been infiltrated with buffer solutions of pH 5.5 and 8.0, respectively, showed a rapid adjustment of the pH close to the natural neutral value by the mesophyll tissue. The results are incompatible with the idea of an active invertase in the sink (and the source) leaves apoplast, and hence do not lend support to the theory of apoplastic cleavage of sucrose being required for phloem unloading in this kind of a utilization sink.