Pressure Effects on Membrane Potentials of Mesophyll Cell Protoplasts and Epidermal Cell Protoplasts of Commelina communis L.

Pantoja, O. and Willmer, C. M. 1986. Pressure effects on membranepotentials of mesophyll cell protoplasts and epidermal cellprotoplasts of Commelina communis L.—J. exp. Bot. 37:315–320. Membrane potentials of epidermal cell protoplasts and mesophyllcell protopiasts of Comnelina communis were measured when theprotoplasts were immobilized in a suction micropipette. Whenzero suction was employed, membrane potentials of both protoplasttypes were near to zero. As suction pressure was increased,membrane potentials became increasingly more negative with gradientsof 14·3 mV/kPa and 10·5 mV/kPa for mesophyll cellprotoplasts and epidermal cell protoplasts, respectively. Theplasma membrane is stretched when suction pressure is appliedto protoplasts and it is considered that this simulates cellturgor pressure which is associated with negative membrane potentialsof intact cells. The results help to explain why some investigatorsobtain positive membrane potentials for protoplasts while othersobtain negative values. The results also indicate that considerablecaution is needed in the interpretation of ion flux data whenprotoplasts are used. Key words: Commelina communis, membrane potentials, pressure, protoplasts     

Resting membrane potential and action potential of Nitella expansa protoplasts

Inside negative membrane potentials were observed for protoplastsobtained from Nitella expansa leaf internodal cells in mediacontaining 1 to 100 mM CaCl₂ using the microelectrode technique.The potential values were less negative than the membrane potentialof intact N. expansa leaf internodal cells. In addition, anaction potential consisting of two components—a fast componentand a slow component—was induced by electrical stimulationfor the protoplasts as well as the intact cells. (Received December 18, 1979; )     

The Generation of Non-Spherical Oat Protoplasts Indicates that Hyperpolarization is both Necessary and Sufficient for Stimulating Membrane Incorporation into the Plasma Membrane

We have devised conditions which produced isolated protoplastsof non-spherical shape and which, therefore, affected the mechanismsthat control the exchange of membrane material between the plasmamembrane and an intracellular membrane reservoir. Non-sphericalprotoplasts of Avena sativa were obtained if protoplasts weretreated with hypertonic shock in the presence of 1.0 mol m^–3LaCl₃ at pH 8.3. This indicated that their ability to removeplasma membrane material via endocytotic vesiculation was suppressed.Non-spherical protoplasts were obtained under isotonic conditionsif protoplasts were incubated with 1.0 mol m^-3 LaCl₃ at pH 8.3and the proton carrier CCCP (12 mmol m^–3) was added. Thenon-spherical protoplasts had intact membranes as judged bystaining with fluorescein diacetate. The loss of the sphericalshape was reversible. On addition of EDTA protoplasts resphericulatedimmediately. Incubation in isotonic solution at pH 8.3 containingeither only 1.0 mol m^–3 LaCl₃ or only CCCP did not influencethe protoplast shape. We conclude that the membrane hyperpolarizationinduced by CCCP at high pH acted to stimulate the incorporationof membrane material into the plasma membrane and, subsequently,produced nonspherical protoplasts if the removal of membranematerial was simultaneously suppressed. This demonstrates thatmembrane incorporation and removal are two largely independentprocesses.     

The Membrane Potential of Enzymatically Isolated Nitella expansa Protoplasts as Compared with their Intact Cells

With the enzymatically isolated Nitella protoplasts, sufficientinsertions of micro-electrodes to make a stable measurementof the membrane potential by the conventional method could notbe made because of an ‘elasticity’ of the outermembrane. We developed an effective method in which a micro-electrodecould be inserted after the outer membrane was punctured bypassing an electrical impulse through the micro-electrode. Inthis method, Ca ions play a crucial role in the ‘punching’and ‘healing’ processes of the protoplast membrane. The effects of the cations K⁺, Na⁺, Ca²⁺ and the anions Cl^–,, , on the membrane potentials of Nitella expansa protoplasts were compared with those of intactcells. The membrane potential of protoplasts was less negativethan that of intact cells when concentrations of Na or K, inthe presence of Ca, were below certain levels which increasedwith increasing Ca concentration; and it tended to become identicalto that of intact cells when Na or K concentrations were beyondthose levels. Beyond those levels for K the membrane potentialsof both protoplasts and intact cells typically seemed to bethe Nernst potentials in the presence of 0•1 to 30 molm^–3 Ca²⁺. However, for Na, the difference in potentialsbetween intact cells and protoplasts decreased at much higherconcentrations than for K. Increase of Ca always gave less negativeprotoplast potentials than those in intact cells. Replacementof Ca by Mg did not change the membrane potential of intactcells, although it was deleterious to protoplasts. The cellwall potential of intact cells was also measured by the micro-electrodetechnique and was revealed as a simple Donnan potential, assumingthe fixed negative charge density of 0•8 equivalent perdm³. The membrane potential of intact cells seems to be a significantreflection of the plasmalemma potential which is thought tobe measured directly in their protoplasts in terms of ionicselectivity and concentration dependency of the ion speciesexamined. In addition, increased sensitivity to calcium in protoplastpotentials compared to intact cells is suggested, though themembrane potential of intact cells seems to be largely preservedin their enzymatically isolated protoplasts. Key words: Membrane potential, protoplasts, Nitella expansa, cell wall potential     

Plasma Membrane Redox System in Guard Cell Protoplasts of Pea (Pisum sativum L.)

Guard cell protoplasts (GCP) from leaves of pea (Pisum sativum)were capable of reducing/oxidizing the membrane impermeableelectron carriers, ferricyanide/NADH. The redox activity ofGCP required the presence of both ferricyanide and NADH, althoughsome ferricyanide reduction occurred even in the absence ofNADH. The GCP preferred NADH to NADPH during ferricyanide reductionand the reduction was slow with DCPIP or cytochrome c. A stoichiometryof about 2 existed between moles of ferricyanide reduced andNADH oxidized by GCP. The redox activities of GCP were severaltimes greater than those of mesophyll protoplasts from pea leaves.The ferricyanide reduction or NADH oxidation by GCP was unaffectedby abscisic acid or sodium orthovanadate and fusicoccin indicatingthe non-involvement of plasma membrane ATPase in these redoxreactions.The redox activities were markedly inhibited by chloroquineor 8-hydroxyquinoline. The findings are discussed in relationto the possible regulatory role of a guard cell plasma membraneredox system in stomatal function. Key words: Plasma membrane redox system, mesophyll protoplasts, pea, guard cell protoplasts, stomatal function     

Lactoperoxidase-Catalyzed Iodination of Plasmamembrane Lipids and Proteins in Arabidopsis Protoplasts

Lactoperoxidase-catalyzed iodination was evaluated as a techniqueto identify plasma membrane components in protoplasts isolatedfrom leaf tissue of Arabidopsis thaliana (L.) Heynh. Restrictionof the probe to the plasma membrane was assessed by determiningradioactivity in lipids characteristic of intracellular organellesafter labeling intact versus broken protoplasts. Intact protoplastswere purified on a sucrose-sorbitol gradient and iodinated usingNa[¹²⁵I] with lactoperoxidase and H₂O₂. Lipids as well as proteinswere shown to be iodinated in a lactoperoxidase-catalyzed reaction.Labeling of intracellular lipids was low in the intact protoplastswhich indicated that the iodination reaction was restrictedto the plasma membrane. (Received March 18, 1988; Accepted May 25, 1988)     

Comparative Studies of Leaf Tissue 4: III. EFFECTS OF WALL-DEGRADING ENZYMES AND OSMOTIC STRESS

Commercially available cell wall-degrading enzymes frequentlyused for protoplast isolation inhibited CO₂ fixation and photosyntheticO₂ evolution, and stimulated dark respiration by leaf tissueand isolated mesophyll protoplasts of Nicotiana tabacum L. andAntirrhinum majus L. They also depolarized the membrane potentialof cells of leaf tissue, inhibited uptake of ⁸⁶Rb by tobaccoleaf tissue and isolated mesophyll protoplasts, and stimulated³⁶CI uptake by tobacco leaf tissue. Where studied, these effectswere found to be reversible. The depolarization effect on Antirrhinumleaf cells occurred even when the enzyme preparations had beendenatured, dialysed, or desalted, and the effect was greatestin those fractions of the enzyme preparation which showed thehighest cellulase activity. Plasmolysis of tobacco leaf tissue inhibited photosyntheticO₂ evolution, CO₂ fixation, and ⁸⁶Rb uptake to levels belowthose exhibited by isolated protoplasts in media of the samecomposition and osmolarity. The implications of these resultsfor work with leaf tissue and isolated protoplasts are discussed.     

Surface Charge Density of Hetero-Fused Plant Protoplasts: an Electrophoretic Study

Electrophoretic mobilities of hetero-fused plant protoplasts,which were obtained by electrofusion of barley mesophyll cellprotoplasts and Rauwolfia serpentina cultured cell protoplasts,and those of the unfused parent protoplasts were measured invarious media of different pH values. At pH 5.2, the zeta potentialof the fused protoplasts was intermediate between those of thebarley and R. serpentina protoplasts and the average surfacecharge density of the fused protoplasts was closer to that ofR. serpentina than to that of barley. The distribution of thesurface charge density of fused protoplast obtained at pH 5.2is discussed in terms of the surface charge densities and thesizes of parent protoplasts. These results revealed that thesurface charge density of fused protoplasts was determined bythe surface charge densities and the ratio of the surface areasof the respective parent protoplasts. (Received December 28, 1989; Accepted August 10, 1990)     

Regulation of Amino Acid Uptake into Oat Mesophyll Cells: A Comparison between Protoplasts and Leaf Segments

The uptake of -aminoisobutyric acid (AIB) into protoplasts andinto 1 cm sections of leaves from 7 d old light-grown oats (Avenasativa L. cv. ‘Garry’) was studied. Both protoplastsand leaf sections with cuticle and epidermis removed accumulatedAIB against a concentration gradient although the rate of uptakeinto protoplasts was one-third to one-sixth that into leaf sections.AIB uptake into both protoplasts and leaf cells in situ wasstimulated by ‘aging,’ and low pH, and inhibitedby osmotic shock, respiratory poisons, and KCl concentrationsabove 1 mM. It was concluded that the rate of uptake of AIBand its accumulation ratio could be accounted for by the energyinherent in the proton-motive force, the proton-motive forcebeing the sum of the pH gradient and potential difference acrossthe plasma membrane. The similarities between oat mesophyllprotoplasts and leaf cells in situ suggest that these protoplastsare suitable material for the study of certain membrane-regulatedevents.     

Ferricyanide Reduction by Guard Cell Protoplasts

Guard cell protoplasts of Commelina communis L. reduced exogenousferricyanide at pH values lower than 5?0; upon addition of NADH,reduction of ferricyanide by guard cell protoplasts was stimulatedover the pH range 4?0 to 9?0 with two peaks of activity at pH5?0 and between pH 8?0 and pH 9?0. Calcium chloride (1?0 molm^–3) and MgCl2 (1?0 mol m^–3) increased the NADH-stimulatedreduction of ferricyanide. Superoxide dismutase and cyanidehad little effect on the NADH-stimulated reduction of ferricyanideby guard cell protoplasts, but, salicylhydroxamic acid completelyinhibited this activity. The NADH-stimulated reduction of ferricyanidealso occurred in the cell-free supernatant. Horseradish peroxidasedid not reduce ferricyanide in the absence of NADH over a broadrange of pH (4?0 to 9?0). However, in the presence of NADH,horseradish peroxidase reduced ferricyanide over the pH range5?0 to 9?0 with maximal activity at pH 8?0. The NADH-stimulatedreduction of ferricyanide by horseradish peroxidase showed similarproperties to those observed with guard cell protoplasts. Mannitol,superoxide dismutase, and cyanide did not inhibit the NADH-stimulatedreduction of ferricyanide by horseradish peroxidase; SHAM, however,completely inhibited the reduction of ferricyanide by horseradishperoxidase. Catalase inhibited the NADH-stimulated reductionof ferricyanide by horseradish peroxidase by 20%, while absenceof oxygen in the assay medium stimulated this activity over60%. We propose that the reduction of ferricyanide in the presenceof NADH by guard cell protoplasts, can be explained in termsof peroxidase activity associated with the plasma membrane andsecreted to the extracellular medium. However, the capacityof guard cell protoplasts to reduce ferricyanide at acid pHvalues where little peroxidase activity occurs may indicatethe presence of a plasma membrane redox system in guard cellsof C. communis. Key words: Commelina, guard cell protoplasts, ferricyanide reduction, peroxidase, redox system     

The Permeability of the Guard Cell Plasma Membrane and Tonoplast

Uptake experiments and efflux compartmental analysis of planthormones, osmotica and toxins using ‘isolated’ guardcells of Valerianella locusta and guard cell protoplasts (GCP)of Vicia faba were performed in order to study the permeabilityproperties of guard cell plasma membrane and tonoplast. Theplasma membrane of guard cells exhibits a higher permeabilitythan plasma membranes of mesophyll cells for most solutes investigated.The permeability coefficients (P_s calculated for the guard cellplasma membranes are also significantly higher than the P_s valuesfor the guard cell tonoplast. This applies also for protonatedABA. We suppose that the high permeability for ABAH could bepart of the target cell properties. A Collander analysis demonstratesa linear correlation between P_s, values and the ratio K_r/M_r^1,5for both plasma membrane (r = 0.87) and for the tonoplast (r=0.93). Because of deviations from the observed correlations,the permeation of some solutes (ABA, GA, IAA through the tonoplast;methylamine through the plasma membrane) seems to be facilitatedby an additional transport mechanism. The Collander analysisof the plasma membrane of GCP shows very similar results tothe analysis of the plasma membrane of ‘isolated’guard cells, indicating that isolation of protoplasts does notalter the permeability of the guard cell plasma membrane. Key words: Permeability coefficient, guard cells, plasma membrane, tonoplast     

Topographical Studies on Subunit Polypeptides of the PS I Reaction Center Complex in the Thylakoid Membranes of the Thermophilic Cyanobacterium Synechococcus sp.

The permeability to protein molecules of the outer limitingmembranes and the thylakoid membranes in hypotonically shockedprotoplasts of the thermophilic cyanobacterium Synechococcussp. was studied by examining the effects of NaBr-washing andpronase E-digestion on phycobiliproteins and a 35 kDa proteinwhich are associated with the outer and inner surface of thethylakoid membranes, respectively, and by measuring photooxidationof added cytochrome c. All the results obtained indicate thatthe shocked protoplasts are in essence a homogenous right side-outthylakoid membrane preparation; the outer limiting membranesare leaky to protein molecules, whereas the thylakoid membranesare still impermeable to proteins. The thylakoid membranes becamepermeable to proteins when the protoplasts were mechanicallydisrupted. Following on from these findings, the membrane topology of subunitpolypeptides of the photosystem I reaction center complex wasstudied. Proteolytic digestion of shocked protoplasts with trypsinand pronase E indicated that four of the five subunit polypeptidesof the PS I reaction center complex are exposed at the stromalsurface of thylakoid membranes; two subunits of 14 and 13 kDawere selectively digested by trypsin, whereas two chlorophyll-bindingsubunits of 62 and 60 kDa were preferentially attacked by pronaseE. However, a 10 kDa subunit appears to be strongly resistantto the proteases. Experiments with mechanically disrupted protoplastsfailed to provide evidence for a uniform transmembrane organizationof the PS I subunits. (Received March 31, 1986; Accepted August 18, 1986)     

Molecular Markers for Ion Compartmentation in Cells of Higher Plants: II. LIPID COMPOSITION OF THE TONOPLAST OF THE HALOPHYTE SUAEDA MARITIMA (L.) DUM.

Vacuoles of high purity were isolated from the leaves of thehalophyte Suaeda maritima (L.) Dum. The relative compositionsof phospholipids, phytosterols, and fatty acids in the tonoplastmembrane were determined and membrane fluidity was assessedby electron spin resonance. The characteristics of the tonoplastwere consistent with minimizing passive permeability to NaCI.The phospholipid: protein ratio (1.1: 1.0) was higher than thatrecorded in other membrane preparations, including vacuolesfrom beetroot storage material, commensurate with the low density(1.05 g cm^–3) of the S. maritima tonoplast. The tonoplastfatty acids were highly saturated and dominated by n-hexadecanoicacid and n-octadecanoic acid. Phytosterols identified by gaschromatography were cholesterol, campesterol, stigmasterol,and ß-sitosterol. Cholesterol was a trace percentagein protoplasts, but comprised 30% of the tonoplast sterols.Semi-quantitative analysis by chromatography on silica gel revealedan enrichment in the tonoplast of glycolipid which was not accountedfor as chloroplast contamination. The fluidity of the tonoplast,determined by electron spin resonance, was lower than the protoplasts,consistent with the high degree of saturation of the fatty acidchains. The relevance of the lipid composition of the tonoplastto its central role in ion compartmentation within the halophytecell is discussed. Key words: Ion compartmentation, membrane lipids, salinity, vacuole     

ATP Sulphurylase and O-Acetylserine Sulphydrylase in Isolated Mesophyll Protoplasts and Bundle Sheath Strands of S-deprived Maize Leaves

In Zea mays L. (cv. XL 72 A) leaves sulphur deficiency causedreduction of soluble protein and chlorophyll contents, whereasATP sulphurylase (EC 2.7.7.4 [EC] ) and O-acetylserine sulphydrylase(EC 4.2.95.9 [EC] ) activities increased with the increasing of S-deprivationtime. The two enzymes exhibited the maximum activity after 5d (ATP sulphurylase) and 3 d (O-acetylserine sulphydrylase)from the beginning of deprivation period. The activities weredifferently distributed between mesophyll protoplasts and bundlesheath strands. The results suggest that the activity of thetwo enzymes may be induced sequentially and differently regulatedin the two types of cells. Key words: ATP sulphurylase, Bundle sheath strands, Mesophyll protoplasts, O-acetylserine sulphydrylase, Sulphur deprivation, Zea     

Abscisic Acid-Induced Membrane Potential Changes in Barley Aleurone Protoplasts: a Possible Relevance for the Regulation of rab Gene Expression

The effect of ABA on the membrane potential of barley (Hordeumvulgare cv. Himalaya) aleurone protoplasts was studied by measuringthe distribution of the lipophilic cation tetraphenylphosphonium(TPP⁺). The resting membrane potential (E_m) according to ourmeasurements with TPP⁺ is about –53 mV and is in agreementwith membrane potential values as measured with intracellularmicroelectrodes (about –55 mV). The TPP⁺-measurementscould demonstrate a clear dependence of the resting E_m on theexternal pH (pH_e). Stimulation of the protoplasts with ABA induced a transienthyperpolarization of the membrane to –62 mV as measuredwith TPP⁺. The hyperpolarization was ABA-concentration dependent. Inhibition of the H⁺-ATPases with the specific proton pump inhibitorsdiethylstilbestrol (DES) or Micanozole effectively preventedhyperpolarization. This indicates that the hyperpolarizationis consistent with the activation of plasma membrane H⁺-ATPases.The K⁺-inward rectifier inhibitor BaCl₂ was able to prolongthe hyperpolarization. This result suggests that the hyperpolarizationcauses the opening of K⁺-channels. The ABA-induced proton-pump activation may be involved in ABA-inducedgene-expression, as DES was able to inhibit this gene expression.BaCl₂ did only show a slight inhibitory effect on ABA-inducedgene-expression. (Received January 4, 1994; Accepted April 12, 1994)     

Isolation and Characterization of a Cytokinin Up-Regulated Gene from Tobacco Mesophyll Protoplasts

We have isolated a cytokinin up-regulated cDNA clone, H13, froman early stage of cultured tobacco mesophyll protoplasts bya differential display method. The expression of this gene wasspecifically induced by natural and synthetic cytokinins includingN-(2-chloro-4-pyridyl)-N'-phenylurea (4PU30), a diphenylurea-typecytokinin, although the simultaneous presence of auxin was alsorequired. It seems that the preceding treatment of the tobaccomesophyll protoplasts by auxin is necessary for the gene torespond to cytokinin. The addition of a cytokinin antagonist,compound 182, which suppressed the induction of cell divisionin tobacco mesophyll protoplasts, completely abolished the expressionof this gene. Though the predicted gene product of H13 did notsuggest us any sequences of defined functions, two domains ofthe predicted sequence had significant homology to several reportedsequences in the data base. The gene product of H13 is proposedto have a role in regenerating cell wall in cultured protoplasts,since a cDNA clone E6, from cotton fiber cells, which has themost closely related structure to H13, has been isolated fromcells which showed active cellulose synthesis. This suppositionis supported by the evidence that in the absence of cytokinin,cell wall regeneration was significantly suppressed, resultingin failure of the induction of cell division. Thus, the geneproduct of H13 is supposed to have a role in regenerating cellwalls and facilitating the progression of the cell cycle, resultingin the sustained cell division of tobacco mesophyll protoplasts. ¹These authors are equally contributed to this work.     

Calcium-Dependent and -Independent Phosphoenolpyruvate Carboxylase Kinases in Sorghum Leaves: Further Evidence for the Involvement of the Calcium-Independent Protein Kinase in the in situ Regulatory Phosphorylation of C4 Phosphoenolpyruvate Carboxylase

Calcium-dependent phosphoenolpyruvate carboxylase protein kinasewas copurified with C₄ phosphoenolpyruvate carboxylase (C₄ PEPC)from illuminated Sorghum leaves during purification by variousprocedures. Isolated mesophyll cell protoplasts contained bothcalcium-dependent and -independent protein kinases. The latterwas induced by light and weak bases and was found to be themajor protein kinase phosphorylating C₄ PEPC in the mesophyll. (Received July 29, 1997; Accepted November 28, 1997)     

Carbon Dioxide Fixation by Guard Cell Protoplasts of Commelina communis

Biochemical studies of epidermal tissue may not reflect metabolismof the guard cells which represent less than 5% of the tissuevolume. Pure samples of guard cell protoplasts of Commelinacommunis were therefore used to investigate CO₂ fixation ratesand ¹⁴C-labelling patterns of metabolites in the light and thedark. Qualitatively, results were similar in most respects tothose obtained in a previous study (Schnabl, 1980) for guardcell protoplasts of Vicia faba. CO₂ fixation rates by guardcell protoplasts of C. communis were the same in the light andthe dark but about 50 times lower than the values Schnabl obtainedfor V.faba. The ¹⁴C-labelling pattern of metabolites in C. communiswas also similar in the light and the dark: over 60% of thetotal fixed was in malate with only 1% in sugar phosphates.Label was also detected in starch, aspartate, glutamate andcitrate but not in glycollate as previously recorded in V. fabaguard cell protoplasts. The results confirm the view that the reductive pentose phosphatepathway does not occur in guard cells of C. communis. Key words: CO₂ fixation, Guard cell protoplasts, Stomata     

Callus Induction from Mesophyll and Hypocotyl Protoplasts of Mungbean (Vigna radiata (L))

Mesophyll and hypocotyl protoplasts were isolated from Vignaradiata using a combination of Cellulase Onozuka RIO (1%) andMacerozyme (0·2%). On a modified V-47 medium, 60% ofthe cultured protoplasts divided and developed into colonies.Protoclones differentiated roots on MS medium supplemented withdifferent auxins and cytokinins; however, shoot differentiationwas not obtained. Co-cultivation of protoplasts with wild andshooter mutants of Agrobacterium tumefaciens did not lead todifferentiation of plantlets. Lysopine and nopaline dehydrogenasewere not detected in any of the selected protoclones. Vigna radiata, Mungbean, Agrobacterium tumefaciens, co-cultivation, protoplasts     

Osmocytosis and Vacuolar Fragmentation in Guard Cell Protoplasts: Their Relevance to Osmotically-lnduced Volume Changes in Guard Cells

Guard cell protoplasts were prepared from young leaves of peaplants. Under hypertonic conditions they shrink and large numbersof endocytotic (‘osmocytotic’) vacuoles are formedby invagination of the plasma membrane. In thin section theseare indistinguishable from other small vacuoles (‘mini-vacuoles’)which are formed by fragmentation of the large central vacuole.However, the two types of vacuole can be individually recognizedby labelling the central vacuole with neutral red and by performingthe osmotic shrinkage with fluorochromes such as Lucifer Yellow-CHor Cascade Blue present in the extracellular medium. Osmocytoticvacuoles do not fuse with the plasma membrane nor with the mini-vacuolesduring a subsequent swelling phase. After several hours, osmocytosedLucifer Yellow gradually leaks out of the endocytotic vacuoleswhen protoplasts are returned to hypotonic conditions. Thisleakage is not prevented by probenecid at concentrations (20–50mmol m^–3) which do not give rise to pathological changesin protoplast ultrastructure. In order to determine the relevanceof these observations to the situation in planta, intact guardcells in epidermal strips were first allowed to accumulate neutralred in their vacuoles and then subjected to osmotic shrinkagein the presence of external Lucifer Yellow. Osmocytotic vacuoleswere not formed, although the production of mini-vacuoles wasfrequently observed. Key words: Guard cell protoplasts, fluid phase markers, Pisum sativum, probenecid, osmocytosis, shrinkage-swelling cycles