Observations on the phosphate status and intracellular pH of intact cells, protoplasts and chloroplasts from photosynthetic tissue using phosphorus-31 nuclear magnetic resonance.

Individual pools of intracellular inorganic phosphate (Pi) can be observed in the dark in intact cells, protoplasts and chloroplasts from photosynthetic tissue by using 31P nuclear magnetic resonance (n.m.r.). Estimates for the pH of vacuolar and extravacuolar compartments are reported although it is shown that intracellular pH is determined by the pH of the suspending medium. Mannose treatment of asparagus (Asparagus officinalis) cells and spinach (Spinacia oleracea) protoplasts results in the inhibition of photosynthesis. The mechanism of mannose phosphate sequestration of free Pi is supported by the 31P n.m.r. spectra of mannose-treated tissue. There is a fundamental difference in 31 P n.m.r. spectra of mannose-treated spinach protoplasts and asparagus cells, reflecting a difference in the availability of vacuolar Pi for cellular metabolism in these species. The 31P n.m.r. spectrum of intact spinach chloroplasts is reported.     

Transport and phosphorylation of choline in higher plant cells. Phosphorus-31 nuclear magnetic resonance studies

When sycamore cells were suspended in basal medium containing choline, the latter was taken up by the cells very rapidly. A facilitated diffusion system appertained at low concentrations of choline and exhibited Michaelis-Menten kinetics. At higher choline concentrations simple diffusion appeared to be the principal mode of uptake. Addition of choline to the perfusate of compressed sycamore cells monitored by 31P NMR spectroscopy resulted in a dramatic accumulation of P-choline in the cytoplasmic compartment containing choline kinase and not in the vacuole. The total accumulation of P-choline over a 10-h period exhibited Michaelis-Menten kinetics. During this period, in the absence of Pi in the perfusion medium there was a marked depletion of glucose-6-P, and the cytoplasmic Pi resonance disappeared almost completely. When a threshold of cytoplasmic Pi was attained, the phosphorylation of choline was sustained by the continuous release of Pi from the vacuole although at a much lower rate. However, when 100 microM inorganic phosphate was present in the perfusion medium, externally added Pi was preferentially used to sustain P-choline synthesis. It is clear, therefore, that cytosolic choline kinase associated with a carrier-mediated transport system for choline uptake appeared as effective systems for continuously trapping cytoplasmic Pi including vacuolar Pi entering the cytoplasm.     

Biochemical changes during sucrose deprivation in higher plant cells. Phosphorus-31 nuclear magnetic resonance studies

An experimental arrangement was described that enables nuclear magnetic resonance spectra of compressed plant cells to be recorded while circulating a medium through the sample. The system provided a convenient arrangement for monitoring by 31P NMR the behavior of plant cells over a long period of time under different conditions such as sucrose starvation. Perfusion of compressed sycamore cells with sucrose-free culture medium triggered a progressive decrease in the glucose 6-P and uridine-5'-diphosphate-alpha-D-glucose resonances over 30 h. When almost all the intracellular carbohydrate pool had disappeared the nucleotide triphosphate resonances decline progressively. These changes were accompanied by a Pi accumulation in the vacuole and a phosphorylcholine (P-choline) accumulation in the cytoplasm. The very long lag phase observed for ATP and P-choline evolution was comparable with that observed for the progressive intracellular digestion of cytoplasmic constituents (Journet, E., Bligny, R. and Douce, R. (1986) J. Biol. Chem. 261, 3193-3199). Addition of sucrose in the circulating system after a long period of sucrose starvation led to a disappearance of the cytoplasmic Pi resonance and a marked increase in that of glucose 6-P. Under these conditions the vacuolar Pi pool did not fluctuate to buffer the Pi in the cytoplasm. The results suggest that Pi which has been sequestered in the vacuole during the course of sucrose starvation is not restored to the cytoplasm for rapid metabolic processes. Furthermore, the presence of P-choline in plant cells in large excess should be considered as a good marker of membrane utilization after a long period of sucrose starvation and is very likely related to stress.     

Relationship between the cytoplasm and the vacuole phosphate pool in Acer pseudoplatanus cells

The Pi concentration of Acer pseudoplatanus cells in the two major intracellular compartments, the cytoplasm and the vacuole, has been studied using 31P NMR. For sycamore cells containing approximately 2 mM of total Pi, the cytoplasmic Pi and the vacuolar Pi concentrations were approximately 6 and 1.5 mM, respectively. When the cells were transferred to a phosphate-deficient medium, the vacuolar Pi decreased rapidly while the cytoplasmic Pi decreased slowly during the first 48 h, indicating that Pi in the cytoplasm was maintained at the expense of the vacuolar Pi. When the Pi-starved cells (i.e., those containing less than 0.5 mumol of total Pi/g wet wt) were transferred to a medium containing 300 microM Pi, Pi entered the cells rapidly and accumulated in the cytoplasm. Once the cytoplasmic Pi pool was filled, Pi was taken up in the vacuole until the vacuole Pi pool was filled. On the contrary when the non-Pi-starved cells were transferred to a phosphate-rich medium (i.e., containing 45 mM Pi), Pi entered the cells slowly by diffusion and accumulated in the vacuole but not in the cytoplasm. These results demonstrate that the Pi content of the cytoplasm is maintained at the expense of the vacuolar Pi pool when sycamore cells are transferred to either a phosphate-deficient or a phosphate-rich medium.     

A phosphorus-31 nuclear magnetic resonance study of phosphate uptake and storage in cultured Catharanthus roseus and Daucus carota plant cells

High resolution 31P NMR spectra (103.2 MHz) of oxygenated Catharanthus roseus and Daucus carota cells grown in suspension cultures were obtained using a solenoidal perfusion probe. The spectra showed resonances for various phosphorylated metabolites such as ATP, ADP, NAD(P)(H), nucleoside diphosphoglucose, and sugar phosphates. The relative levels of the phosphorylated metabolites remained constant throughout the growth curve. No resonances for storage compounds such as polyphosphates, pyrophosphate, or phytates were observed. Two resolved resonances for Pi indicated an intracellular pH of 7.3 and 5.7 (or below) for the cytoplasm and vacuoles, respectively. The time course of Pi uptake and storage during growth in fresh culture medium was followed by studying the level of vacuolar Pi with 31P NMR (145.7 MHz). Simultaneously, the level of Pi in the culture medium was followed with radioactive 32P. C. roseus quickly takes up all the Pi from the culture medium (maximum rate 1.7 mumol min-1 g-1 (dry weight of cells]. The Pi is first stored in the vacuoles; subsequently, one part of this pool is used to keep a constant cytoplasmic Pi level while another part is apparently accumulated as an NMR invisible Pi store, probably in another cell organelle. In contrast, D. carota does not accumulate Pi in the vacuoles and consequently it takes up Pi from the medium at a much slower rate (0.05 mumol min-1 g-1 (dry weight of cells].     

Inhibition of the phosphate transporter during isolation of intact chloroplasts from leaves of sunflower

Chloroplasts isolated from spinach leaves by the mechanical method were intact and exhibited high rates of CO₂-dependent oxygen evolution whereas chloroplasts isolated from sunflower leaves by the same technique were also intact but showed only low rates of oxygen evolution. The rate of uptake of orthophosphate (Pi) from the suspending medium with sunflower chloroplasts was less than 20% of that in spinach chloroplasts. The apparent Km for Pi transport was lower in sunflower chloroplasts but uptake was competitively inhibited by 3-phosphoglycerate in chloroplasts from both species. Uptake of malate (via the dicarboxylate transporter) and of ATP (via the adenine nucleotide transporter) was also reduced in sunflower chloroplasts compared to spinach chloroplasts. The endogenous Pi content and total exchangeable phosphate pool of sunflower chloroplasts were less than half that in spinach chloroplasts.Addition of a number of possible protective agents to the grinding medium failed to prevent the loss of photosynthetic activity during mechanical isolation of sunflower chloroplasts. Grinding mixtures of spinach and sunflower leaves together indicated that spinach chloroplasts were not inhibited by the sunflower leaf extract. Chloroplasts isolated from sunflower leaves via protoplasts had high rates of CO₂-dependent oxygen evolution. The Vmax and Km for Pi uptake, endogenous Pi content and total exchangeable phosphate pool of chloroplasts isolated from sunflower protoplasts were all similar to spinach chloroplasts. It is concluded that inner envelope membrane proteins are damaged during mechanical isolation of sunflower chloroplasts. The decrease in activity of the phosphate transporter and loss of endogenous phosphate may contribute to the low rates of photosynthesis observed in chloroplasts isolated by the mechanical method from leaves of sunflower and possibly other species.Abbreviations PGA 3-phosphoglyceric acid     

In VivoP NMR Spectroscopic Studies of Soybean Bradyrhizobium Symbiosis: I. Optimization of Parameters

³¹P NMR spectroscopy was used to study in vivo the symbiotic state established between soybean (Glycine max [L.] Merr. cv Williams) and Bradyrhizobium japonicum (USDA 110 and 138). Different experimental conditions were used to maintain perfused, respiring detached or attached nodules in an NMR magnet. The pH of the perfusion medium affected the cytoplasmic pH and the resolution of the spectra. The internal Pi content and distribution were assessed as a function of nodule age and green-house growth conditions and the rate of glucose and 2-deoxyglucose uptake into nodules in split and intact states. The major metabolites (glucose-6-P, fructose-1,6-diP, P-choline, Pi, NTP, UDP-glc, and NAD) were readily identified from ³¹P NMR spectra of perchloric acid extracts of nodules with the exception of one unknown phosphorus metabolite. Nodules stressed by glucose deprivation demonstrated movement of Pi between the vacuole and cytoplasmic compartments not previously observed in ³¹P NMR studies.     

Simultaneous measurement of changes in red and blue fluorescence in illuminated isolated chloroplasts and leaf pieces: The contribution of NADPH to the blue fluorescence signal

A newly developed nitrogen laser fluorimeter insensitive to actinic illumination was used to follow simultaneously the light induced changes in red and blue fluorescence of intact isolated spinach chloroplasts and leaf pieces. The recorded variable blue fluorescence was linked to a water soluble component of intact isolated chloroplasts, depended on Photosystem I, and was related to changes in carbon metabolism. From the comparison of changes in intact and broken chloroplasts and from fluorescence spectra under different conditions, it was concluded that the variation in NADPH was the major cause for the changes in blue fluorescence. This study opens a path towards continuous and non-destructive monitoring of NADPH redox state in chloroplasts and leaves.Abbreviations Chl chlorophyll - DHAP dihydroxyacetone phosphate - DLGA DL-glyceraldehyde - FNR ferredoxin-NADP reductase - FWHM full width at half maximum - LED light emitting diodes - OAA oxaloacetate - q_N non-photochemical quenching - PGA 3-phosphoglycerate - Pi inorganic orthophosphate - q_P photochemical quenching - PPFD photosynthetic photon flux density - Q_A primary quinone acceptor of Photosystem II Preliminary results of this work were presented at the First Conference on the Physiology and Biochemistry of high Mountain Plants, 2–3 July 1992, Villar d'Arene, France.     

Phosphorus compartmentation in Pinus serotina Michx. (pond pine); observations from in vivo nuclear magnetic resonance spectroscopy

³¹P nuclear magnetic resonance (NMR) spectroscopy was used to estimate the amount of inorganic phosphate (Pi) present in the cytoplasm and vacuole of root tips and subapical root segments of pond pine ( Pinus serotina Michx.). In root tips of seedlings grown with 100 mmol m^–3P (HP) the cytoplasmic Pi content, on a root volume basis, was ≈ 1·5 μ mol cm^–3 and the vacuolar Pi content, on a root volume basis, was ≈ 3·4 μ mol cm^–3. In root tips from Pi starved seedlings the cytoplasmic Pi content, on a root volume basis, was ≈ 0·75 μ mol cm^–3; vacuolar Pi was too low to be reliably estimated. Similar results were obtained with subapical root segments; the Pi concentration in the cytoplasm was maintained at around 2 mol m^–3 while that in the vacuole varied with Pi supply. This work demonstrates for the first time that quantitative measurements of the subcellular compartmentation of Pi can be made in young tissues of a woody species. The results indicate that cytoplasmic Pi levels are maintained across a range of external Pi supplies probably by withdrawing Pi stored in the vacuole.     

Phosphorus-31 nuclear magnetic resonance studies of intracellular pH,phosphate compartmentation and phosphate transport in yeasts

³¹P NMR spectra were obtained from suspensions of Candida utilis, Saccharomyces cerevisiae and Zygosaccharomyces bailii grown aerobically on glucose. Direct introduction of substrate into the cell suspension, without interruption of the measurements, revealed rapid changes in pH upon addition of the energy source. All ³¹P NMR spectra of the yeasts studied indicated the presence of two major intracellular inorganic phosphate pools at different pH environments. The pool at the higher pH was assigned to cytoplasmic phosphate from its response to glucose addition and iodoacetate inhibition of glycolysis. After addition of substrate the pH in the compartment containing the second phosphate pool decreased. A parallel response was observed for a significant fraction of the terminal and penultimate phosphates of the polyphosphate observed by ³¹P NMR. This suggested that the inorganic phosphate fraction at the lower pH and the polyphosphates originated from the same intracellular compartment, most probably the vacuole. In this vacuolar compartment, pH is sensitive to metabolic conditions. In the presence of energy source a pH gradient as large as 0.8 to 1.5 units could be generated across the vacuolar membrane. Under certain conditions net transport of inorganic phosphate across the vacuolar membrane was observed during glycolysis: to the cytoplasm when the cytoplasmic phosphate concentration had become very low due to sugar phosphorylation, and into the vacuole when the former concentration had become high again after glucose exhaustion.Non-Standard Abbreviations NMR nuclear magnetic resonance - ppm parts per million - PP polyphosphate - P_i,c cytoplasmic inorganic phosphate - P_i,v vacuolar inorganic phosphate - pH_in,c cytoplasmic pH - pH_in,v vacuolar pH - FCCP carbonyl p-trifluoromethoxyphenylhydrazone     

Pyruvate,orthophosphate dikinase in leaves and chloroplasts of C(3) plants undergoes light-/dark-induced reversible phosphorylation

Pyruvate,orthophosphate (Pi) dikinase (PPDK) is best recognized as a chloroplastic C(4) cycle enzyme. As one of the key regulatory foci for controlling flux through this photosynthetic pathway, it is strictly and reversibly regulated by light. This light/dark modulation is mediated by reversible phosphorylation of a conserved threonine residue in the active-site domain by the PPDK regulatory protein (RP), a bifunctional protein kinase/phosphatase. PPDK is also present in C(3) plants, although it has no known photosynthetic function. Nevertheless, in this report we show that C(3) PPDK in leaves of several angiosperms and in isolated intact spinach (Spinacia oleracea) chloroplasts undergoes light-/dark-induced changes in phosphorylation state in a manner similar to C(4) dikinase. In addition, the kinetics of this process closely resemble the reversible C(4) process, with light-induced dephosphorylation occurring rapidly (< or =15 min) and dark-induced phosphorylation occurring much more slowly (> or =30-60 min). In intact spinach chloroplasts, light-induced dephosphorylation of C(3) PPDK was shown to be dependent on exogenous Pi and photosystem II activity but independent of electron transfer from photosystem I. These in organello results implicate a role for stromal pools of Pi and adenylates in regulating the reversible phosphorylation of C(3)-PPDK. Last, we used an in vitro RP assay to directly demonstrate ADP-dependent PPDK phosphorylation in desalted leaf extracts of the C(3) plants Vicia faba and rice (Oryza sativa). We conclude that an RP-like activity mediates the light/dark modulation of PPDK phosphorylation state in C(3) leaves and chloroplasts and likely represents the ancestral isoform of this unusual and key C(4) pathway regulatory "converter" enzyme.     

Effect of sulphate on glutamate synthesis by intact spinach (Spinacia oleracea) chloroplasts.

During the course of NH4+ (or NO2-)-plus-alpha-oxoglutarate-dependent O2 evolution in spinach (Spinacia oleracea) chloroplasts, glutamate was continuously excreted out of the chloroplasts. Under these conditions, for each molecule of NO2- or NH4+ which disappeared, one molecule of glutamate accumulated in the medium and the concentration of glutamate in the stroma space was maintained constant. SO4(2-) (or SO3(2-) behave as inhibitors of NH4+ incorporation into glutamate by intact chloroplasts. This considerable inhibition of glutamate synthesis by SO4(2-) was correlated with a rapid decline in the stromal Pi concentration. The reloading of stromal Pi with either external Pi or PPi4- relieved SO4(2-)-induced inhibition of glutamate synthesis by intact chloroplasts. It was concluded that SO4(2-) induced a rapid efflux of stromal Pi out of the chloroplast, leading to a limitation of ATP synthesis and therefore to an arrest of ATP-dependent glutamine synthetase functioning.     

The occurrence of phosphatidyl choline exchange protein in leaves

The transfer of phosphatidyl choline between liposomes was stimulated by the protein fractions from spinach leaves, etiolated and greening leaves of $\text{Avena}$ seedlings. This is confirmed by the transfer of [¹⁴C]phosphatidyl choline or spin-labeled phosphatidyl choline between donor and acceptor liposomes. ESR spectrum changes also indicated that no spin-labeled phosphatidyl choline was released from donor liposomes by spinach leaf protein unless acceptor liposomes were present. [¹⁴C]phospholipids were transferred from liposomes to both spinach chloroplasts and $\text{Avena}$ etiochloroplasts by phosphatidyl choline exchange protein from germinated castor bean endosperms and further from liposomes to spinach chloroplasts by spinach leaf protein. These results support the view that phosphatidyl choline in the plastid is supplied from the synthesis site, the endoplasmic reticulum, by phospholipid exchange protein.     

31P nuclear magnetic resonance study of growth and dimorphic transition in Candida albicans

A 31P NMR study of the fungal pathogen Candida albicans was carried out. Yeast-form cells at different phases of growth, as well as germ tubes and hyphae were examined. In all cases, the NMR spectra showed well separated resonance peaks arising from phosphorus-containing metabolites, the most prominent being attributable to inorganic phosphate (Pi) polyphosphates, sugar phosphates and mononucleotides, NAD, ADP and ATP. Relevant signals were also detected in the phosphodiester region. The intensity of most signals, as measured relative to that of Pi, was clearly modulated both at the different phases of growth and during yeast-to-mycelium conversion, suggesting significant changes in the intracellular concentration of the corresponding metabolites. In particular, the intensity of the polyphosphate signal was high in exponentially growing, yeast-form cells, then progressively declined in the stationary phase, was very low in germ tubes and, finally, undetectable in hyphae. NMR spectral analysis of the Pi region showed that from early-stationary phase, Pi was present in two different cellular compartments, probably corresponding to the cytoplasm and the vacuole. From the chemical shift of Pi, the pH values of these two compartments could be evaluated. The cytoplasmic pH was generally slightly lower than neutrality (6.7-6.8), whereas the vacuolar pH was always markedly more acidic.     

Elucidation of the cytoplasmic and vacuolar components in the inorganic phosphate region in the 31P NMR spectrum of yeast

Subcellular compartments, such as the vacuole in yeast, play important roles in cell metabolism and in cell response to external conditions. Concentrations of inorganic phosphate and pH values of the vacuole and cytoplasm were determined for anaerobic Saccharomyces cerevisiae cells based upon (31)P NMR spectroscopy. A new approach allows the determination of these values for the vacuole in cases when the resonance for inorganic phosphate in the cytoplasm overlaps with the resonance for inorganic phosphate in the vacuole. The intracellular inorganic phosphate resonance was first decomposed into two components by computer analysis. The assignments of the components were determined from in vivo correlations of P(i) chemical shift and the chemical shifts of the cytoplasmic sugar phosphates, and the pH dependency of the resonance of pyrophosphate and the terminal phosphate of poly-phosphate (PP(1)) which reside in the vacuole. An in vivo correlation relating PP(1) and P(i) (vac) chemical shifts was established from numerous evaluations of intracellular compositions for several strains of S. cerevisiae. This correlation will aid future analysis of (31)P NMR spectra of yeast and will extend NMR studies of compartmentation to cellular suspensions in phosphate-containing medium. Application of this method shows that both vacuolar and extracellular P(i) were phosphate reserves during glycolysis in anaerobic S. cerevisiae. Net transport of inorganic phosphate across the vacuolar membrane was not correlated with the pH gradient across the membrane.     

Over-expression of PHO1 in Arabidopsis leaves reveals its role in mediating phosphate efflux

Inorganic phosphate (Pi) homeostasis in multi-cellular eukaryotes depends not only on Pi influx into cells, but also on Pi efflux. Examples in plants for which Pi efflux is crucial are transfer of Pi into the xylem of roots and release of Pi at the peri-arbuscular interface of mycorrhizal roots. Despite its importance, no protein has been identified that specifically mediates phosphate efflux either in animals or plants. The Arabidopsis thaliana PHO1 gene is expressed in roots, and was previously shown to be involved in long-distance transfer of Pi from the root to the shoot. Here we show that PHO1 over-expression in the shoot of A. thaliana led to a two- to threefold increase in shoot Pi content and a severe reduction in shoot growth. (31) P-NMR in vivo showed a normal initial distribution of intracellular Pi between the cytoplasm and the vacuole in leaves over-expressing PHO1, followed by a large efflux of Pi into the infiltration medium, leading to a rapid reduction of the vacuolar Pi pool. Furthermore, the Pi concentration in leaf xylem exudates from intact plants was more than 100-fold higher in PHO1 over-expressing plants compared to wild-type. Together, these results show that PHO1 over-expression in leaves leads to a dramatic efflux of Pi out of cells and into the xylem vessel, revealing a crucial role for PHO1 in Pi efflux.     

光呼吸对光合过程中磷代谢的影响

与光呼吸受抑制的 2％O_2浓度下相比,在 21％O_2浓度下.离体甘薯叶细胞光合作用最适介质无机磷浓度较低.另外,在21％O_2浓度下,降低甘薯叶细胞介质 NaHCO_3浓度,叶细胞光下吸收介质~(32)Pi的量减少;降低完整菠菜叶绿体介质 NaHCO_3浓度,乙醇酸形成相对加强,而介质~(32)Pi掺入到有机磷化合物的量则相对减少.这些结果表明,有利于光呼吸的条件,可降低光合对外界Pi的需求量.     

Characterization of the 31P NMR spectrum of the schistosome vector Biomphalaria glabrata and of the changes following infection by Schistosoma mansoni

The 31P nuclear magnetic resonance (NMR) spectrum of the digestive gland-gonad complex (DGG) of the schistosome vector Biomphalaria glabrata was characterized and the effects of infection by Schistosoma mansoni noted. The in vivo spectrum was comprised of 11 peaks, 5 downfield and 6 upfield of an external 85% phosphoric acid standard. Based on a variety of analytical procedures, the upfield peaks from the standard were demonstrated to be composed of carbamoyl phosphate + a mixture of 3 phosphatides and sphingomyelin, the gamma + beta phosphorus resonances of nucleotide triphosphate (NTP) and nucleotide diphosphate (NDP), respectively, the alpha phosphorus resonances of NTP + NDP, NAD(H) + the phosphorus resonance of uridine phosphate from uridine diphosphoglucose (UDPG), the phosphorus resonance of glucose phosphate from UDPG and, last, the beta phosphorus resonance of NTP. The downfield peaks were assigned as glycerophosphoryl choline, intracellular inorganic phosphate (Pi), sugar phosphates + phosphoryl choline, aminoethyl phosphonate (AEP), and ceramide AEP. T1 values for the in vivo NMR components were determined by inversion recovery. Infection produced distinct alterations in the levels of nonnucleotide components of the in vivo 31P NMR spectrum and the spectra of tissue extracts. Specifically, the levels of phosphonate, phospholipids, and carbamoyl phosphate were markedly reduced, and the relative level of Pi was increased. The potential significance of these changes to the parasite-host relationship was discussed. In contrast, starvation resulted in a decreased level of phosphonate only. The pH of the intact DGG was estimated by titrating the inorganic phosphate component of tissue extracts. The mean pH was 6.9 for both control and infected material.     

Ion Relations of Symplastic and Apoplastic Space in Leaves from Spinacia oleracea L. and Pisum sativum L. under Salinity

Salt tolerant spinach (Spinacia oleracea) and salt sensitive pea (Pisum sativum) plants were exposed to mild salinity under identical growth conditions. In order to compare the ability of the two species for extra- and intracellular solute compartmentation in leaves, various solutes were determined in intercellular washing fluids and in aqueously isolated intact chloroplasts. In pea plants exposed to 100 millimolar NaCl for 14 days, apoplastic salt concentrations in leaflets increased continuously with time up to 204 (Cl⁻) and 87 millimolar (Na⁺), whereas the two ions reached a steady concentration of only 13 and 7 millimolar, respectively, in spinach leaves. In isolated intact chloroplasts from both species, sodium concentrations were not much different, but chloride concentrations were significantly higher in pea than in spinach. Together with data from whole leaf extracts, these measurements permitted an estimation of apoplastic, cytoplasmic, and vacuolar solute concentrations. Sodium and chloride concentration gradients across the tonoplast were rather similar in both species, but spinach was able to maintain much steeper sodium gradients across the plasmamembrane compared with peas. Between day 12 and day 17, concentrations of other inorganic ions in the pea leaf apoplast increased abruptly, indicating the onset of cell disintegration. It is concluded that the differential salt sensitivity of pea and spinach cannot be traced back to a single plant performance. Major differences appear to be the inability of pea to control salt accumulation in the shoot, to maintain steep ion gradients across the leaf cell plasmalemma, and to synthesize compatible solutes. Perhaps less important is a lower selectivity of pea for K⁺/Na⁺ and NO₃⁻/Cl⁻ uptake by roots.     

Foliar flavonoid distribution during Spinacia chloroplast isolation

The flavonoid glycoside accumulation level was compared in class A and in class C spinach chloroplast suspensions. Class A chloroplasts (up to 97% intact) contained about 0.4% of the total flavonoid glycosides present in leaves. Further purification of 97%-intact chloroplast suspensions, through a Percoll gradient, reduced the glycoside level to less than 0.15%. On the other hand, class C chloroplasts (100% broken plastids) contained between 10 to 30 times more flavonoids than intact Percoll purified chloroplasts. These results indicate that chloroplasts could bind vacuolar glycosides during their period of isolation. This hypothesis was confirmed by controlled contamination experiments using a cell-free supernatant as a source of vacuolar glycosides. Furthermore, the level of flavonoids in chloroplasts could be decreased to a level close to that obtained in intact Percoll purified chloroplasts by washing with soluble polyvinylpyrolidone. The results presented in this paper demonstrate the importance of maintaining the physiological integrity of plastids during the course of organelle isolation when investigating flavonic compartmentation in leaves.