A xylem sap retrieval pathway in rice leaf blades: evidence of a role for endocytosis?

The structure and transport properties of pit membranes at the interface between the metaxylem and xylem parenchyma cells and the possible role of these pit membranes in solute transfer to the phloem were investigated. Electron microscopy revealed a fibrillar, almost tubular matrix within the pit membrane structure between the xylem vessels and xylem parenchyma of leaf blade bundles in rice (Oryza sativa). These pits are involved primarily with regulating water flux to the surrounding xylem parenchyma cells. Vascular parenchyma cells contain large mitochondrial populations, numerous dictyosomes, endomembrane complexes, and vesicles in close proximity to the pit membrane. Taken collectively, this suggests that endocytosis may occur at this interface. A weak solution of 5,6-carboxyfluorescein diacetate (5,6-CFDA) was applied to cut ends of leaves and, after a minimum of 30 min, the distribution of the fluorescent cleavage product, 5,6-carboxyfluorescein (5,6-CF), was observed using confocal microscopy. Cleavage of 5,6-CFDA occurred within the xylem parenchyma cells, and the non-polar 5,6-CF was then symplasmically transported to other parenchyma elements and ultimately, via numerous pore plasmodesmata, to adjacent thick-walled sieve tubes. Application of Lucifer Yellow, and, separately, Texas Red-labelled dextran (10 kDa) to the transpiration stream, confirmed that these membrane-impermeant probes could only have been offloaded from the xylem via the xylem vessel-xylem parenchyma pit membranes, suggesting endocytotic transmembrane transfer of these membrane-impermeant fluorophores. Accumulation within the thick-walled sieve tubes, but not in thin-walled sieve tubes, confirms the presence of a symplasmic phloem loading pathway, via pore plasmodesmata between xylem parenchyma and thick-walled sieve tubes, but not thin-walled sieve tubes.

Reductions of Rubisco activase by antisense RNA in the C4 plant Flaveria bidentis reduces Rubisco carbamylation and leaf photosynthesis.

To function, the catalytic sites of Rubisco (EC 4.1.1.39) need to be activated by the reversible carbamylation of a lysine residue within the sites followed by rapid binding of magnesium. The activation of Rubisco in vivo requires the presence of the regulatory protein Rubisco activase. This enzyme is thought to aid the release of sugar phosphate inhibitors from Rubisco's catalytic sites, thereby influencing carbamylation. In C3 species, Rubisco operates in a low CO2 environment, which is suboptimal for both catalysis and carbamylation. In C4 plants, Rubisco is located in the bundle sheath cells and operates in a high CO2 atmosphere close to saturation. To explore the role of Rubisco activase in C4 photosynthesis, activase levels were reduced in Flaveria bidentis, a C4 dicot, by transformation with an antisense gene directed against the mRNA for Rubisco activase. Four primary transformants with very low activase levels were recovered. These plants and several of their segregating T1 progeny required high CO2 (>1 kPa) for growth. They had very low CO2 assimilation rates at high light and ambient CO2, and only 10% to 15% of Rubisco sites were carbamylated at both ambient and very high CO2. The amount of Rubisco was similar to that of wild-type plants. Experiments with the T1 progeny of these four primary transformants showed that CO2 assimilation rate and Rubisco carbamylation were severely reduced in plants with less than 30% of wild-type levels of activase. We conclude that activase activity is essential for the operation of the C4 photosynthetic pathway.

Expression and localisation analysis of the wheat sucrose transporter TaSUT1 in vegetative tissues.

Previously we reported the isolation of three sucrose transporter genes, TaSUT1A, 1B and 1D, all expressed at high levels in the developing grains of hexaploid wheat ( Triticum aestivum L.), but also in a variety of other tissues. In order to further characterise the expression of the TaSUT1 genes in wheat plants, we have analysed TaSUT1 expression in their vegetative tissues using semi-quantitative reverse transcription-polymerase chain reaction, in situ hybridisation and immunolocalisation. The three TaSUT1 genes, which encode 98% identical SUT proteins, all appeared to be expressed at the same level in leaf blades, leaf sheaths and internodes, as well as developing grains, of hexaploid wheat. In mature leaf blades, TaSUT1 protein localised to the plasma membrane of phloem sieve elements in all classes of veins. In contrast, TaSUT1 mRNA was found to be localised to phloem companion cells. A similar localisation pattern for TaSUT1 protein was observed in veins of leaf sheaths and internodes. These results suggest that the wheat SUT1 has a transport function in enucleate sieve elements, in both veins responsible for loading photoassimilates, and in veins for axial transport. Furthermore, transport of the fluorescent dye carboxyfluorescein was used to investigate symplasmic connectivity between sieve element-companion cell complexes and non-phloem cells. Observations in source leaves indicated that sieve element-companion cell complexes of minor veins were symplasmically restricted, suggesting a role of TaSUT1 in apoplasmic phloem loading. In contrast, the dye was able to move symplasmically out of the phloem in internodes. In these circumstances TaSUT1 may also have a role in retrieving sucrose leaked to the phloem apoplasm.

The control of single-celled cotton fiber elongation by developmentally reversible gating of plasmodesmata and coordinated expression of sucrose and K+ transporters and expansin.

Each cotton fiber is a single cell that elongates to 2.5 to 3.0 cm from the seed coat epidermis within approximately 16 days after anthesis (DAA). To elucidate the mechanisms controlling this rapid elongation, we studied the gating of fiber plasmodesmata and the expression of the cell wall-loosening gene expansin and plasma membrane transporters for sucrose and K(+), the major osmotic solutes imported into fibers. Confocal imaging of the membrane-impermeant fluorescent solute carboxyfluorescein (CF) revealed that the fiber plasmodesmata were initially permeable to CF (0 to 9 DAA), but closed at approximately 10 DAA and re-opened at 16 DAA. A developmental switch from simple to branched plasmodesmata was also observed in fibers at 10 DAA. Coincident with the transient closure of the plasmodesmata, the sucrose and K(+) transporter genes were expressed maximally in fibers at 10 DAA with sucrose transporter proteins predominately localized at the fiber base. Consequently, fiber osmotic and turgor potentials were elevated, driving the rapid phase of elongation. The level of expansin mRNA, however, was high at the early phase of elongation (6 to 8 DAA) and decreased rapidly afterwards. The fiber turgor was similar to the underlying seed coat cells at 6 to 10 DAA and after 16 DAA. These results suggest that fiber elongation is initially achieved largely by cell wall loosening and finally terminated by increased wall rigidity and loss of higher turgor. To our knowledge, this study provides an unprecedented demonstration that the gating of plasmodesmata in a given cell is developmentally reversible and is coordinated with the expression of solute transporters and the cell wall-loosening gene. This integration of plasmodesmatal gating and gene expression appears to control fiber cell elongation.

Cloning and expression of a prokaryotic sucrose-phosphate synthase gene from the cyanobacterium Synechocystis sp. PCC 6803.

Sucrose is one of several low-molecular-weight compounds that cyanobacteria accumulate in response to osmotic stress and which are believed to act as osmoprotectants. The genome of the cyanobacterium Synechocystis sp. PCC 6803 contains a 2163 bp open reading frame (ORF) that shows similarity to genes from higher plants encoding sucrose-phosphate synthase (SPS), the enzyme responsible for sucrose synthesis. The deduced amino acid sequence shows 35-39% identity with known higher-plant SPS sequences. The putative Synechocystis sps gene was cloned from genomic DNA by PCR amplification and expressed as a His6-tagged amino-terminal fusion protein in Escherichia coli. The expressed protein was purified and shown to be a functional SPS enzyme, confirming the identity of the ORF, which is the first sps gene to be cloned from a prokaryotic organism. The Synechocystis SPS has a molecular mass of 81.5 kDa, which is smaller than the typical higher-plant SPS subunit (117-119 kDa), and lacks the phosphorylation site motifs associated with light- and osmotic stress-induced regulation of SPS in higher plants. The enzyme has Km values for UDPG1c and Fru6P of 2.9 mM and 0.22 mM, respectively, with a Vmax of 17 micromol per minute per mg protein and a pH optimum of 8.5. Unlike the higher-plant enzyme, ADPG1c, CDPG1c and GDPG1c can substitute for UDPG1c as the glucosyl donor with Km values of 2.5, 7.2 and 1.8 mM, respectively. The enzyme is activated by Mg2+ but not by G1c6P, and is only weakly inhibited by inorganic phosphate. The purified protein was used to raise a high-titre antiserum, which recognises a low-abundance 81 kDa protein in Synechocystis sp. PCC 6803 extracts. There was no apparent increase in expression of the 81 kDa protein when the cells were exposed to moderate salt stress, and SPS activity was very low in extracts from both unstressed and salt-stressed cells. These results and the lack of evidence for sucrose accumulation in Synechocystis sp. PCC6803 lead to the conclusion that expression of the sps gene plays no obvious role in adaptation to osmotic stress in this species.

Carbohydrate Content and Enzyme Metabolism in Developing Canola Siliques.

Little biochemical information is available on carbohydrate metabolism in developing canola (Brassica napus L.) silique (pod) wall and seed tissues. This research examines the carbohydrate contents and sucrose (Suc) metabolic enzyme activities in different aged silique wall and seed tissues during oil filling. The silique wall partitioned photosynthate into Suc over starch and predominantly accumulated hexose. The silique wall hexose content and soluble acid invertase activity rapidly fell as embryos progressed from the early- to late-cotyledon developmental stages. A similar trend was not evident for alkaline invertase, Suc synthase (SuSy), and Suc-phosphate synthase. Silique wall SuSy activities were much higher than source leaves at all times and may serve to supply the substrate for secondary cell wall thickening. In young seeds starch was the predominant accumulated carbohydrate over the sampled developmental range. Seed hexose levels dropped as embryos developed from the early- to midcotyledon stage. Hexose and starch were localized to the testa or liquid endosperm, whereas Suc was evenly distributed among seed components. With the switch to oil accumulation, seed SuSy activity increased by 3.6-fold and soluble acid invertase activity decreased by 76%. These data provide valuable baseline knowledge for the genetic manipulation of canola seed carbon partitioning.

NADP-Malate Dehydrogenase in the C4 Plant Flaveria bidentis (Cosense Suppression of Activity in Mesophyll and Bundle-Sheath Cells and Consequences for Photosynthesis).

Flaveria bidentis, a C4 dicot, was transformed with sorghum (a monocot) cDNA clones encoding NADP-malate dehydrogenase (NADP-MDH; EC 1.1.1.82) driven by the cauliflower mosaic virus 35S promoter. Although these constructs were designed for over-expression, many transformants contained between 5 and 50% of normal NADP-MDH activity, presumably by cosense suppression of the native gene. The activities of a range of other photosynthetic enzymes were unaffected. Rates of photosynthesis in plants with less than about 10% of normal activity were reduced at high light and at high [CO2], but were unaffected at low light or at [CO2] below about 150 [mu]L L-1. The large decrease in maximum activity of NADP-MDH was accompanied by an increase in the activation state of the enzyme. However, the activation state was unaffected in plants with 50% of normal activity. Metabolic flux control analysis of plants with a range of activities demonstrates that this enzyme is not important in regulating the steady-state flux through C4 photosynthesis in F. bidentis. Cosense suppression of gene expression was similarly effective in both the mesophyll and bundle-sheath cells. Photosynthesis of plants with very low activity of NADP-MDH in the bundle-sheath cells was only slightly inhibited, suggesting that the presence of the enzyme in this compartment is not essential for supporting maximum rates of photosynthesis.

Reduction of Ribulose-1,5-Bisphosphate Carboxylase/Oxygenase by Antisense RNA in the C4 Plant Flaveria bidentis Leads to Reduced Assimilation Rates and Increased Carbon Isotope Discrimination.

Transgenic Flaveria bidentis (a C4 species) plants with an antisense gene directed against the mRNA of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) were used to examine the relationship between the CO2 assimilation rate, Rubisco content, and carbon isotope discrimination. Reduction in the amount of Rubisco in the transgenic plants resulted in reduced CO2 assimilation rates and increased carbon isotope discrimination of leaf dry matter. The H2O exchange was similar in transgenic and wild-type plants, resulting in higher ratios of intercellular to ambient CO2 partial pressures. Carbon isotope discrimination was measured concurrently with CO2 and H2O exchange on leaves of the control plants and T1 progeny with a 40% reduction in Rubisco. From the theory of carbon isotope discrimination in the C4 species, we conclude that the reduction in the Rubisco content in the transgenic plants has led to an increase in bundle-sheath CO2 concentration and CO2 leakage from the bundle sheath; however, some down-regulation of the C4 cycle also occurred.

Localisation of sucrose-phosphate synthase and starch in leaves of C4 plants.

The activity and intercellular distribution of sucrose-phosphate synthase (SPS; EC 2.4.1.14) were determined in fully expanded leaves from a range of C4 plants. In Zea mays L. and Atriplex spongiosa F. Muell., SPS was located almost exclusively in the mesophyll cells. In other species, SPS was found in both cell types, with the activity in the bundle sheath cells ranging from 5% of the total leaf activity in Echinochloa crus-galli (L.) Beauv. to 35% in Sorghum bicolor Moench. At the end of the light period, starch was found only in the bundle sheath cells in all of the species examined. There appears to be little correlation between C4-acid decarboxylation type and the location of sucrose and starch synthesis in the leaves of C4 plants.

Expressing an RbcS Antisense Gene in Transgenic Flaveria bidentis Leads to an Increased Quantum Requirement for CO2 Fixed in Photosystems I and II.

It was previously shown with concurrent measurements of gas exchange and carbon isotope discrimination that the reduction of ribulose-1,5-bisphosphate carboxylase/oxygenase by an antisense gene construct in transgenic Flaveria bidentis (a C4 species) leads to reduced CO2 assimilation rates, increased bundle-sheath CO2 concentration, and leakiness (defined as the ratio of CO2 leakage to the rate of C4 acid decarboxylation; S. von Caemmerer, A. Millegate, G.D. Farquhar, R.T. Furbank [1997] Plant Physiol 113: 469-477). Increased leakiness in the transformants should result in an increased ATP requirement per mole of CO2 fixed and a change in the ATP-to-NADPH demand. To investigate this, we compared measurements of the quantum yield of photosystem I and II ([phi]PSI and [phi]PSII) with the quantum yield of CO2 fixation ([phi]CO2) in control and transgenic F. bidentis plants in various conditions. Both [phi]PSI/[phi]CO2 and [phi]PSII/[phi]CO2 increased with a decrease in ribulose-1,5-bisphosphate carboxylase/oxygenase content, confirming an increase in leakiness. In the wild type the ratio of [phi]PSI to [phi]PSII was constant at different irradiances but increased with irradiance in the transformants, suggesting that cyclic electron transport may be higher in the transformants. To evaluate the relative contribution of cyclic or linear electron transport to extra ATP generation, we developed a model that links leakiness, ATP/NADP requirements, and quantum yields. Despite some uncertainties in the light distribution between photosystem I and II, we conclude from the increase of [phi]PSII/[phi]CO2 in the transformants that cyclic electron transport is not solely responsible for ATP generation without NADPH production.

cDNA cloning and tissue specific expression of a gene for sucrose transporter from rice (Oryza sativa L.).

We describe the cloning and expression analysis of a sucrose transporter cDNA from a monocot (the rice plant, Oryza sativa L.). The cDNA clone (OsSUT1) encoded an open reading frame of 1,611 bp (537 amino acids) and showed 76.8 to 79.7% similarity at the amino acid level to other sucrose transporters of dicot species. The predicted membrane topology of OsSUT1 protein is made up of 12 transmembrane helices which is consistent with most of the mono- and disaccharide transporters previously identified. When OsSUT1 cDNA was introduced into yeast and expressed, the cells rapidly accumulated sucrose demonstrating that OsSUT1 does, in fact, encode a sucrose transporter. From genomic Southern hybridization OsSUT1 appeared to be a single copy gene. OsSUT1 was expressed in source organs such as leaf blade, leaf sheath and germinating seed whereas little or no expression was observed in some sink organs such as the panicles before heading and the roots. Transcript was observed at high levels in panicles after heading, particularly in the portion containing endosperm and embryo. In addition, expression of OsSUT1 was high in etiolated seedlings and decreased during light-induced greening.

Antisense RNA Inhibition of RbcS Gene Expression Reduces Rubisco Level and Photosynthesis in the C4 Plant Flaveria bidentis.

The C4 dicot Flaveria bidentis was genetically transformed with an antisense RNA construct targeted to the nuclear-encoded gene for the small subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco; RbcS). RbcS mRNA levels in leaves of transformants were reduced by as much as 80% compared to wild-type levels, and extractable enzyme activity was reduced by up to 85%. There was no significant effect of transformation with the gene construct on levels of other photosynthetic enzymes. Antisense transformants with reduced Rubisco activity exhibited a stunted phenotype. Rates of photosynthesis were reduced in air at high light and over a range of CO2 concentrations but were unaffected at low light. From these results we conclude that, as is the case in C3 plants, Rubisco activity is a major determinant of photosynthetic flux in C4 plants under high light intensities and air levels of CO2.

Regulation of C4 photosynthesis: modulation of mitochondrial NAD-malic enzyme by adenylates.

Effects of adenylates on the activity of mitochondrial NAD-malic enzyme from NAD-malic-enzyme (NAD-ME)-type and phosphoenolpyruvate-carboxykinase-(PKC)-type C4 plants are examined. At physiological concentrations, ATP, ADP, and AMP all inhibit the enzyme from Atriplex spongiosa and Panicum miliaceum (NAD-ME-type plants), with ATP the most inhibitory species. The degree of inhibition is greater with subsaturating levels of activator, malate, and Mn2+. NAD-malic enzyme from Urochloa panicoides (PCK-type) is activated by ATP (up to 10-fold) and inhibited by ADP and AMP. These effects are discussed in relation to regulation of C4 photosynthesis.

C4 acid decarboxylation and photosynthesis in bundle sheath cells of NAD-malic enzyme-type C4 plants: mechanism and the role of malate and orthophosphate.

The mechanism and possible regulation of C4 acid decarboxylation in NAD-malic enzyme-type C4 plants was studied using isolated bundle sheath cells and mitochondria from Panicum miliaceum. Rates of C4 acid-dependent photosynthetic O2 evolution equalled those observed with saturating NaHCO3; the rates ranged from 3 to 5 mumol min-1 (mg chlorophyll)-1. C4 acid-dependent O2 evolution required the addition of aspartate and 2-oxoglutarate (as a source of oxaloacetate) and also malate and orthophosphate. C4 acid decarboxylation by both isolated cells and mitochondria, measured as pyruvate production, also required all four of these components. The scheme previously proposed to account for aspartate decarboxylation in NAD-malic enzyme-type C4 plants does not envisage a role for externally derived malate. However, the mandatory requirement for malate (with orthophosphate), together with the observation that C4 acid decarboxylation is blocked by an inhibitor of the mitochondrial dicarboxylate transporter, suggests that a net flux of malate from outside the mitochondria is required to sustain this process. Arsenate was found to substitute for orthophosphate favoring a role for orthophosphate in malate transport rather than a metabolic one. The results are discussed in terms of likely mitochondrial metabolite transport mechanisms and regulation of the C4 acid decarboxylation process.

Inorganic Carbon Diffusion between C(4) Mesophyll and Bundle Sheath Cells: Direct Bundle Sheath CO(2) Assimilation in Intact Leaves in the Presence of an Inhibitor of the C(4) Pathway.

Photosynthesis rates of detached Panicum miliaceum leaves were measured, by either CO(2) assimilation or oxygen evolution, over a wide range of CO(2) concentrations before and after supplying the phosphoenolpyruvate (PEP) carboxylase inhibitor, 3,3-dichloro-2-(dihydroxyphosphinoyl-methyl)-propenoate (DCDP). At a concentration of CO(2) near ambient, net photosynthesis was completely inhibited by DCDP, but could be largely restored by elevating the CO(2) concentration to about 0.8% (v/v) and above. Inhibition of isolated PEP carboxylase by DCDP was not competitive with respect to HCO(3) (-), indicating that the recovery was not due to reversal of enzyme inhibition. The kinetics of (14)C-incorporation from (14)CO(2) into early labeled products indicated that photosynthesis in DCDP-treated P. miliaceum leaves at 1% (v/v) CO(2) occurs predominantly by direct CO(2) fixation by ribulose 1,5-bisphosphate carboxylase. From the photosynthesis rates of DCDP-treated leaves at elevated CO(2) concentrations, permeability coefficients for CO(2) flux into bundle sheath cells were determined for a range of C(4) species. These values (6-21 micromoles per minute per milligram chlorophyll per millimolar, or 0.0016-0.0056 centimeter per second) were found to be about 100-fold lower than published values for mesophyll cells of C(3) plants. These results support the concept that a CO(2) permeability barrier exists to allow the development of high CO(2) concentrations in bundle sheath cells during C(4) photosynthesis.

CO(2) Concentrating Mechanism of C(4) Photosynthesis: Permeability of Isolated Bundle Sheath Cells to Inorganic Carbon.

Diffusion of inorganic carbon into isolated bundle sheath cells from a variety of C(4) species was characterized by coupling inward diffusion of CO(2) to photosynthetic carbon assimilation. The average permeability coefficient for CO(2) (P(CO(2) )) for five representatives from the three decarboxylation types was approximately 20 micromoles per minute per milligram chlorophyll per millimolar, on a leaf chlorophyll basis. The average value for the NAD-ME species Panicum miliaceum (10 determinations) was 26 with a standard deviation of 6 micromoles per minute per milligram chlorophyll per millimolar, on a leaf chlorophyll basis. A P(CO(2) ) of at least 500 micromoles per minute per milligram chlorophyll per millimolar was determined for cells isolated from the C(3) plant Xanthium strumarium. It is concluded that bundle sheath cells are one to two orders of magnitude less permeable to CO(2) than C(3) photosynthetic cells. These data also suggest that CO(2) diffusion in bundle sheath cells may be made up of two components, one involving an apoplastic path and the other a symplastic (plasmodesmatal) path, each contributing approximately equally.

Mechanism of c(4) photosynthesis: a model describing the inorganic carbon pool in bundle sheath cells.

A theoretical model of the composition of the inorganic carbon pool generated in C(4) leaves during steady-state photosynthesis was derived. This model gives the concentrations of CO(2) and O(2) in the bundle sheath cells for any given net photosynthesis rate and inorganic carbon pool size. The model predicts a bundle sheath CO(2) concentration of 70 micromolar during steady state photosynthesis in a typical C(4) plant, and that about 13% of the inorganic carbon generated in bundle sheath cells would leak back to the mesophyll cells, predominantly as CO(2). Under these circumstances the flux of carbon through the C(4) acid cycle would have to exceed the net rate of CO(2) assimilation by 15.5%. With the calculated O(2) concentration of 0.44 millimolar, the potential photorespiratory CO(2) loss in bundle sheath cells would be about 3% of CO(2) assimilation. Among the factors having a critical influence on the above values are the permeability of bundle sheath chloroplasts to HCO(3) (-), the activity of carbonic anhydrase within these chloroplasts, the assumed stromal volume, and the permeability coefficients for CO(2) and O(2) diffusion across the interface between bundle sheath and mesophyll cells. The model suggests that as the net photosynthesis rate changes in C(4) plants, the level and distribution of the components of the inorganic carbon pool change in such a way that C(4) acid overcycling is maintained in an approximately constant ratio with respect to the net photosynthesis rate.

Coregulation of electron transport and Benson-Calvin cycle activity in isolated spinach chloroplasts: studies on glycerate 3-phosphate reduction.

Glycerate 3-phosphate-dependent O2 evolution was measured in intact chloroplasts in the absence of CO2. At all concentrations of added glycerate 3-phosphate oxygen evolution ceased before stoichiometric amounts of oxygen were evolved. The inhibition of glycerate 3-phosphate-dependent-O2 evolution increased with increasing concentrations of substrate added. A similar response was observed in chloroplasts treated with KCN which inhibits ribulose-1,5-bisphosphate carboxylase-oxygenase. Oxygen uptake via the oxygenase activity of this enzyme is therefore not the cause of the discrepancy in stoichiometry of oxygen release in this system. The addition of NaHCO3 to chloroplasts in which oxygen evolution was inhibited by glycerate 3-phosphate caused an immediate sustained rate of oxygen evolution in the absence of KCN but not with KCN present. Simultaneous measurements of chlorophyll a fluorescence showed that qQ remained oxidized, although net O2 evolution had ceased. As O2 evolution decreased, qE and delta pH increased. Upon the addition of the NaHCO3, QA became more oxidized while delta pH and qE were decreased, suggesting that the inhibition of electron transport at high glycerate 3-phosphate concentrations was mediated by photosynthetic control via delta pH. However, the levels of ATP, ADP, ribulose 1,5-bisphosphate, and Pi concentrations and ATP/ADP ratio. The stromal glycerate 3-phosphate content declined upon illumination until O2 evolution ceased. At this time a constant stromal glycerate 3-phosphate concentration of 8-10 mM was maintained while net import of glycerate 3-phosphate into the stroma had virtually ceased. The stromal triosephosphate content remained at a constant low level throughout but the glycerate 3-phosphate level increased slightly after addition of NaHCO3. The data provided by the measurements of thylakoid reactions and stromal metabolites suggest that photosynthetic electron transport is tightly coupled to the requirements of the stroma for ATP and NADPH. Glycerate 3-phosphate reduction requires much less ATP than the operation of the complete Benson-Calvin cycle since the stoichiometry of ATP and NADPH utilization is reduced to 1:1. We conclude that thylakoid electron flow is not sufficiently flexible to maintain NADPH and ATP production in the ratio of 1:1. This situation will favor overenergization of the thylakoid membrane, increased leakiness of protons, increased electron drainage to O2, and result in progressive inhibition of noncyclic electron flow.