Dynamics of membrane exchange of the plasma membrane and the lysis of isolated protoplasts during rapid expansions in area

Summary The plasma membrane of protoplasts isolated from rye leaves (Secale cereale L. cv. Puma) can withstand a maximum elastic stretching of about 2%. Larger area expansions involve the incorporation of new material into the membrane. The dynamics of this process during expansion from isotonic solutions and the probable frequency of lysis have been measured as a function of membrane tension in populations of protoplasts isolated from both cold-acclimated and nonacclimated plants. To a first approximation, both increase exponentially with tension. An analytical solution is reported for the membrane tension as a function of time during an arbitrary expansion in area.     

The Mechanics of Injury to Isolated Protoplasts following Osmotic Contraction and Expansion

Micro-osmotic manipulation was used to determine the influence of osmotic contraction on the expansion potential of individual protoplasts isolated from rye (Secale cereale L. cv Puma) leaves. For protoplasts isolated from leaves of nonacclimated plants (NA protoplasts), osmotic contraction in sufficiently hypertonic solutions (>1.53 osmolal) predisposed the protoplasts to lysis during osmotic expansion when they were returned to isotonic conditions (0.53 osmolal). In contrast, for protoplasts isolated from leaves of cold acclimated plants (ACC protoplasts), osmotic contraction in either 2.6 or 4.0 osmolal solutions was readily reversible. Following osmotic contraction, the resting tension (γ_r) of NA protoplasts was similar to that determined for protoplasts in isotonic solutions (i.e. 110 ± 22 micronewtons per meter). In contrast, γ_r of ACC protoplasts decreased from 164 ± 27 micronewtons per meter in isotonic solutions to values close to zero in hypertonic solutions. Following expansion in hypotonic solutions, γ_r's of both NA and ACC protoplasts were similar for area expansions over the range of 1.3 to 1.6. Following osmotic contraction and reexpansion of NA protoplasts, hysteresis was observed in the relationship between γ_r and surface area—with higher values of γ_r at a given surface area. In contrast, no hysteresis was observed in this relationship for ACC protoplasts. Direct measurements of plasma membrane tension (γ) during osmotic expansion of NA protoplasts from hypertonic solutions (1.53 osmolal) revealed that γ increased rapidly after small increments in surface area, and lysis occurred over a range of 1.2 to 8 millinewtons per meter. During osmotic expansion of ACC protoplasts from hypertonic solutions (2.6 osmolal), there was little increase in γ until after the isotonic surface area was exceeded. These results are discussed in relation to the differences in the behavior of the plasma membrane of NA and ACC protoplasts during osmotic contraction (i.e. endocytotic vesiculation versus exocytotic extrusion) and provide a mechanistic interpretation to account for the differential sensitivity of NA and ACC protoplasts to osmotic expansion from hypertonic solutions.     

The influence of cold acclimation on the behavior of the plasma membrane following osmotic contraction of isolated protoplasts

Summary Osmotic contraction of protoplasts isolated from cold acclimated leaves ofSecale cereale L. cv. Puma results in the formation of exocytotic extrusions of the plasma membrane. Numerous knobs or polyps were observed on the surface of the protoplasts with scanning electron microscopy. In thin sections, the extrusions were bounded by the plasma membrane with a densely osmiophilic interior. Cross-fracturing of the extrusions revealed aparticulate bodies within, a further indication that the interior of the extrusions was predominantly lipid material. Freeze-fracture of the plasma membrane suggests a possible source of this lipid material. Following osmotic contraction, the particle density on the plasma membrane protoplasmic face (PFp) increased, being reflected in both a substantial increase in paracrystalline arrays and an increase in the particle density in non-crystalline regions. This increase in particle density indicates that lipid material is preferentially lost from the plasma membrane during contraction. The density on the exoplasmic face (EFp) did not change. Together, these findings suggest that during hypertonic contraction of acclimated protoplasts, lipid material is preferentially subducted from the plasma membrane and sequestered into lipid bodies (the osmiophilic regions). The formation of lipid bodies and extrusions was readily reversible. Following osmotic expansion of acclimated protoplasts, the extrusions were retracted back into the plane of the plasma membrane.Department of Agronomy Series Paper no. 1497.     

Behavior of the Plasma Membrane of Isolated Protoplasts during a Freeze-Thaw Cycle

Cryomicroscopy of protoplasts isolated from nonacclimated (NA) rye leaves (Secale cereale L. cv Puma) revealed that the predominant form of injury following cooling to the minimum temperature for 50% survival (LT₅₀) (−5°C) was expansion-induced lysis of the plasma membrane during warming and thawing of the suspending medium when the decreasing osmolality resulted in osmotic expansion of the protoplasts. When cooled to temperatures below the LT₅₀, the predominant form of injury was loss of osmotic responsiveness following cooling so that the protoplasts were osmotically inactive during warming. Only a low incidence (<10%) of expansion-induced lysis was observed in protoplasts isolated from acclimated (ACC) leaves, and the predominant form of injury following cooling to the LT₅₀ (−25°C) was loss of osmotic responsiveness. The tolerable surface area increment (TSAI) which resulted in lysis of 50% of a population (TSAI₅₀) of NA protoplasts osmotically expanded from isotonic solutions was 1122 ± 172 square micrometers. Similar values were obtained when the protoplasts were osmotically expanded from hypertonic solutions. The TSAI determined from cryomicroscopic measurements of individual NA protoplasts was similar to the TSAI₅₀ values obtained from osmotic manipulation. The TSAI₅₀ of ACC protoplasts expanded from isotonic solutions (2145 ± 235 square micrometers) was approximately double that of NA protoplasts and increased following osmotic contraction. Osmotic contractions were readily reversible upon return to isotonic solutions. During freeze-induced dehydration, endocytotic vesicles formed in NA protoplasts whereas exocytotic extrusions formed on the surface of ACC protoplasts. During osmotic expansion following thawing of the suspending medium, the endocytotic vesicles remained in the cytoplasm of NA protoplasts and the protoplasts lysed before their original volume and surface area were regained. In contrast, the exocytotic extrusions were drawn back into the surface of ACC protoplasts as the protoplasts regained their original volume and surface area.     

Mechanical properties of the plasma membrane of isolated plant protoplasts : mechanism of hyperosmotic and extracellular freezing injury

The volume of isolated protoplasts of rye (Secale cereale L. cv Puma) in a suspending solution at constant concentration is shown to be negligibly changed by tensions in the plasma membrane which approach that tension necessary to lyse them. This allows a detailed investigation of the plasma membrane stress-strain relation by micropipette aspiration.

Over periods less than a second, the membrane behaves as an elastic two-dimensional fluid with an area modulus of elasticity of 230 millinewtons per meter. Over longer periods, the stress-strain relation approaches a surface energy law—the resting tension is independent of area and has a value of the order 100 micronewtons per meter. Over longer periods the untensioned area, which is defined as the area that would be occupied by the molecules in the membrane at any given time if the tension were zero, increases with time under large imposed tensions and decreases under sufficiently small tension. It is proposed that these long term responses are the result of exchange of material between the plane of the membrane and a reservoir of membrane material. The irreversibility of large contractions in area is demonstrated directly, and the behavior of protoplasts during osmotically induced cycles of contraction and expansion is explained in terms of the membrane stress-strain relation.

     

Fusion and fission of plasma-membrane material accommodates for osmotically induced changes in the surface area of guard-cell protoplasts

Stomatal movement requires large and repetitive changes in cell volume and consequently changes in surface area. The patch-clamp technique was used to monitor changes in plasma-membrane surface area of individual guard-cell protoplasts (GCPs) by measuring membrane capacitance (C_m), a parameter proportional to the surface area. The membrane capacitance increased under hypoosmotic conditions and decreased after hypertonic treatment. As the specific capacitance remained constant, this demonstrates that osmotically induced changes in surface area are associated with incorporation and removal of membrane material. Osmotically induced fusion and fission of plasma-membrane material was not affected by removal of extracellular Ca²⁺. Dialysing protoplasts with very low (<2 nM) or high (1 μM) Ca²⁺ had no effect on changes in C_m under hypo- and hyperosmotic conditions. However, the rate of change in surface area was dependent on the size of the difference in osmotic potential applied. The larger the osmotic difference and thus changes in membrane tension caused by water influx or efflux, the faster the change in C_m. The results therefore demonstrate that osmotically induced fusion and fission of plasma-membrane material in GCPs are Ca²⁺-independent and modulated by membrane tension. Received: 10 February 1998 / Accepted: 21 April 1998     

The behavior of the plasma membrane following osmotic contraction of isolated protoplasts: Implications in freezing injury

Summary Following osmotic contraction of isolated rye protoplast (Secale cereale L. cv. Puma) that results in nearly a 50% reduction in volume, the plasma membrane was smooth, with no folding or pleating. Instead, deletion of plasma membrane occurred and numerous cytoplasmic vesicles were observed. As a result, the area of the plasma membrane was reduced by approximately 40%. Thin sections revealed that the cytoplasmic vesicles were membrane bound and not merely voids in the cytoplasm. High resolution video microscopy revealed the extent of vesiculation showing large clusters of cytoplasmic vesicles following osmotic contraction. Labeling the plasma membrane with fluorescein-Con-A prior to hypertonic contraction suggested that the cytoplasmic vesicles were derived from the plasma membrane. Freeze-fracture particle density on both the protoplasmic (PFp) and exoplasmic face (EFp) of the plasma membrane remained unchanged following contraction, which is consistent with a unit-membrane deletion into cytoplasmic vesicles. Upon partial re-expansion of the protoplasts, thin sections showed that the vesicles remained in the cytoplasm. These results using osmotic manipulation confirm earlier observations of isolated protoplasts at the light microscope level. Upon contraction plasma membrane is deleted into cytoplasmic vesicles, which are not readily reincorporated into the plasma membrane upon expansion. Lysis occurs before the original volume and surface area are regained.Department of Agronomy Series Paper no. 1456.     

Osmotically induced fluid-phase uptake of fluorescent markers by protoplasts ofChenopodium album

Summary Protoplasts fromChenopodium album suspension culture show large, up to 5-fold, changes in surface area upon hypertonic or hypotonie treatment. These surface area variations cannot be explained by elastic stretching of the plasmalemma. An exchange of membrane material between the plasmalemma and an internal membrane source takes place. Fluid-phase uptake experiments with the fluorescence dyes 5, 6-carboxyfluorescein and Lucifer yellow CH demonstrated that osmotic shrinkage of protoplasts is accompanied by vesicular uptake of the external medium into protoplast cytoplasm. Confocal laser scanning microscopy, as well as conventional fluorescence microscopy, revealed the number, diameter and distribution of the osmocytotic vesicles at different osmotic levels. The rate of osmocytotic vesicle uptake was higher in the presence of calcium chloride than in the presence of EDTA in the external medium. At 6.9 mM calcium chloride we observed a loss of vesicular fluorescence upon returning protoplasts to 0.4 M from 0.8 M sorbitol.     

Short-term effects of Al3+ on the osmotic behavior of red beet (Beta vulgaris L.) protoplasts

The short-term (less than 10 min) effects of Al³⁺ on the biophysical properties of plasma membranes were investigated by time-series image analysis of osmotically-induced volumetric and morphologic changes of red beet (Beta vulgaris L.) protoplasts. Exposure to Al³⁺ under hypotonic conditions reduced the volumetric expansion of protoplasts and their resultant burst: i.e. lysis of protoplasts in a concentration-dependent manner. Under hypertonic conditions, protoplasts exposed to Al³⁺ underwent an enhanced volumetric contraction in cross-sectional area, while maintaining higher protoplast roundness. The residual effects of Al³⁺ pre-treatment on subsequent osmotic behavior were also examined, and protoplasts pre-treated with Al³⁺ also exhibited less lysis during subsequent exposure to hypotonic conditions and enhanced volumetric contractions and higher roundness under subsequent hypertonic conditions. Under our experimental conditions, Al³⁺ consistently minimized protoplast surface area by inhibiting osmotic expansion or by enhancing osmotic contraction, as well as by maintaining higher protoplast roundness. These results suggested that the electrostatic property of Al³⁺ might have induced the binding and possible cross-linking of negatively-charged sites on the plasma membrane surface. This may be an important factor in understanding the mechanism of Al³⁺ phytotoxicity.     

The isolation of protoplasts from the placental cells ofSolanum nigrum L.

Summary Living protoplasts were isolated from the interplacental regions ofSolanum nigrum berries by the removal of the walls from cells in tissue slices treated for 1–2 hours with 12% pectinase in 0.33 M to 0.38 M sucrose solution. Protoplasts thus isolated, then washed and transferred to microculture chambers for observation, invariably tended to be spherical. Comparative measurements of cell and protoplast volumes revealed that 10% of the isolated structures were subunits of protoplasts. From diameter changes in protoplasts studied in a hypotonic (0.20 M) sucrose solution, the maximum expansion of the plasma membrane was determined. Slightly hypertonic solutions (0.33 M to 0.38 M sucrose) promote stability of isolated protoplasts for several days. The importance to stability of osmotic concentration and ion balance in the medium is here established. Probably of equal importance is the optimal combination of several common constituents of culture media. Further studies on some aspects of specific medium requirements are in progress.This work was supported by a special grant from the Office of Advanced Studies and Research, University of South Carolina.     

Visualization of vacuoplasts in isolated vacuole preparations from mesophyll protoplasts of periwinkle [Catharanthus roseus (L.) G. Don]

A procedure was developed for the rapid detection of vacuoplasts in vacuole preparations isolated from mesophyll protoplasts of Catharanthus roseus (L.) G. Don (periwinkle). The procedure relies on the staining of surface carbohydrates on the plasma membrane surrounding vacuoplasts with fluorescein-labeled lectins. When isolated under conditions of constant osmotic strength, approximately 15–20% of the vacuoles isolated showed surface labeling with FITC-agglutinin from Abrus precatorius. Isolation of vacuoles after an initial osmotic shock showed much lower (<5%) surface labeling. This lower level of surface labeling correlated well with a lower level of other non-vacuolar marker enzyme activities. A thin layer of cytoplasm was visible in a small number of these stained structures, indicating that they were vacuoplasts.Abbreviations FITC fluorescein isothiocyanate     

Osmotically-Induced Surface Area Expansion in Oat Protoplasts Depends on the Transmembrane Potential

The transmembrane potential of mesophyll cell protoplasts fromAvena sativa was altered in two different ways: first by raisingthe external KCI concentration with and without the additionof valinomycin and, secondly, by using the proton carrier CCCPand varying the external pH. The percentage of unlysed protoplastswas determined after decreasing the osmotic pressure from 1.2to 0.7 MPa in order to characterize their ability to enlargetheir surface area. Lysis strongly increased when the KCI concentrationwas raised from 0 to 90 mol m^–3. This effect did not dependon the presence of valinomycin. Using CCCP, lysis increasedsimilarly if the external pH was lowered from 7.2 to 5.5. Inthe presence of CCCP the influence of the external KCI concentrationdisappeared completely. This led to the conclusion that depolarizationinhibited surface area expansion. Since the expansion is thoughtto be based on exocytotic-like membrane incorporation, theseresults suggest that exocytosis is controlled, at least in part,by the transmembrane potential. Key words: Oat protoplasts, osmotic expansion, transmembrane potential     

Mannuronan C-5 epimerase activity in protoplasts of Laminaria digitata

Biosynthesis of alginate in algae may be studied by following the cell wall regeneration of brown seaweed protoplasts in culture. The enzyme mannuronan C-5 epimerase will control the composition of the alginate being synthetized.Freshly isolated protoplasts from the thallus of young Laminaria digitata plants showed only low expression of this enzyme. However, after prolonged periods in culture, this activity increased 15-fold. The synthesis of C-5 epimerase by the protoplasts is probably essential for the formation of a new cell wall.After cellular disruption by osmotic shock and centrifugation, most of the epimerase activity resided in the pellet fraction. This may indicate that the enzyme is membrane associated.     

The hydraulic conductivity as a criterion for the membrane integrity of protoplasts fused by an electric field pulse

The hydraulic conductivity of the membrane, Lp, of fused plant protoplasts was measured and compared to that for unfused cells, in order to identify possible changes in membrane properties resulting from the fusion process. Fusion was achieved by an electric field pulse which induced breakdown in the membranes of protoplasts in close contact. Close membrane contact was established by dielectrophoresis. In some experiments pronase was added during field application; pronase stabilizes protoplasts against high field pulses and long exposure times to the field. The Lp-values were obtained from the shrinking and swelling kinetics in response to osmotic stress. The Lp-values of fused mesophyll cell protoplasts of Avena sativa L. and of mesophyll and guard cell protoplasts of Vicia faba L. were found to be 1.9±0.9·10^-6, 3.2±2.2·10^-6, and 0.8±0.7·10^-6 cm·bar^-1·s^-1, respectively. Within the limits of error, no changes in the Lp-values of fused protoplasts could be detected in comparison to unfused protoplasts. The Lp-values are in the range of those reported for walled cells of higher plants, as revealed by the pressure probe.Abbreviations GCP guard cell protoplast - Lp hydraulic conductivity - MCP mesophyll cell protoplast     

Changes in osmotic pressure and structure at the initial stages of zygote formation inClosterium ehrenbergii

Summary The behavior of gamete cells ofClosterium ehrenbergii in hypertonic solutions was observed and the significance of changes in osmotic pressure of the protoplasts is discussed in relation to zygote formation. The osmotic pressure of fusing gamete protoplasts was calculated to be 0.063 Osm at the original cell volume. The osmotic pressure of immature gamete protoplasts was 0.24 Osm at incipient plasmolysis. This lowering of cell osmotic pressure may serve to protect the rupture of the plasma membrane during migration of protoplasts in the conjugation tube after dissolution of cell walls. During maturation of gamete cells, chloroplasts and dictyosomes differed greatly in their ultrastructure from those of vegetative cells. These structural changes may be induced by changes of the physiological condition including osmotic pressure in the cells.     

The stress-strain relation of the plasma membrane of isolated plant protoplasts

Over periods of up to a few seconds the plasma membrane of isolated rye protoplasts behaves elastically with an area modulus of $\text{230}\text{mN}\text{·}\text{m}{}^{\mathrm{?1}}$. Over longer periods, the area increases with time under large tension and decreases under sufficiently small tension, suggesting that material is incorporated into or depleted from the plane of the membrane.     

Freeze-thaw injury to isolated spinach protoplasts and its simulation at above freezing temperatures

Possibilities to account for the mechanism of freeze-thaw injury to isolated protoplasts of Spinacia oleracea L. cv. Winter Bloomsdale were investigated. A freeze-thaw cycle to −3.9 C resulted in 80% lysis of the protoplasts. At −3.9 C, protoplasts are exposed to the equivalent of a 2.1 osmolal solution. Isolated protoplasts behave as ideal osmometers in the range of concentrations tested (0.35 to 2.75 osmolal), arguing against a minimum critical volume as a mechanism of injury. Average protoplast volume after a freeze-thaw cycle was not greatly different than the volume before freezing, arguing against an irreversible influx of solutes while frozen. A wide variety of sugars and sugar alcohols, none of which was freely permeant, were capable of protecting against injury which occurred when protoplasts were frozen in salt solutions. The extent of injury was also dependent upon the type of monovalent ions present, with Li = Na > K = Rb = Cs and Cl ≥ Br > I, in order of decreasing protoplast survival. Osmotic conditions encountered during a freeze-thaw cycle were established at room temperature by exposing protoplasts to high salt concentrations and then diluting the osmoticum. Injury occurred only after dilution of the osmoticum and was correlated with the expansion of the plasma membrane. Injury observed in frozen-thawed protoplasts was correlated with the increase in surface area the plasma membrane should have undergone during thawing, supporting the contention that contraction of the plasma membrane during freezing and its expansion during thawing are two interacting lesions which cause protoplast lysis during a freezethaw cycle.     

Osmotic Equilibrium and Elastic Properties of Eel Intestinal Vesicles

Changes in volume of intestinal brush border membrane vesicles of the European eel Anguilla anguilla were measured as vesicles were exposed to media with different osmotic pressures. Preparing the vesicles in media of low osmotic pressure allowed the effects of a small hydrostatic pressure to become a significant factor in the osmotic equilibration. By applying LaPlace's law to relate pressure and volume and assuming a linear relation between membrane tension and area expansion, we estimate an initial membrane tension at 4.02 × 10⁻⁵ N cm⁻¹ and an area compressibility elastic modulus at 0.87 × 10⁻³ N cm⁻¹. The elastic modulus estimate falls in the low range of values reported for membranes from other tissues in other species. This lower modulus quantitatively accounts for why eel intestinal vesicles show measurable changes in volume in hypotonic media while rabbit kidney vesicles do not. Received: 28 January 1999/Revised: 15 June 1999     

Correlation between chloroplast motility and elastic properties of tobacco mesophyll protoplasts

Translocations of chloroplasts induced by blue light were investigated in both leaves and protoplasts isolated from leaf mesophyll of Nicotiana tabacum. In the leaf tissue, the responses of chloroplasts were similar to those observed in other, higher and lower plant species. Weak and strong light induced movements of chloroplasts towards cell walls perpendicular and parallel to the light direction, respectively. Treatment with cytochalasin D, an actin-disturbing agent, blocked the movements. This shows that actin is involved in the motile system of chloroplast translocation in tobacco. By monitoring the response of chloroplasts to light in isolated protoplasts, we addressed the question whether the presence of the cell wall is necessary for the translocations of chloroplasts to occur. In control protoplasts (isolated at room temperature from unstressed leaves), no clear light intensity-dependent changes were observed in chloroplast distribution pattern. In contrast, in protoplasts obtained from plants treated with 4 °C for 8 h the chloroplasts maintained their responsiveness to light. Atomic Force Microscopy was used to measure elastic properties of the protoplasts. Young’s modulus, which reflects rigidity of the material, was 10 times higher for protoplasts of the coldstressed plants as compared to those isolated from the control plants. The rigidity of protoplasts isolated from the plants treated with low temperature was reduced four-fold by exposure to cytochalasin D. It appears that the status of protoplast actin is a factor responsible for elasticity of protoplasts. We speculate that unknown, cold stress-induced factors, maintain the orientational movements due to anchorage of the actin cytoskeleton in the plasma membrane despite the cell wall removal.     

An osmotic model of the growing pollen tube

Pollen tube growth is central to the sexual reproduction of plants and is a longstanding model for cellular tip growth. For rapid tip growth, cell wall deposition and hardening must balance the rate of osmotic water uptake, and this involves the control of turgor pressure. Pressure contributes directly to both the driving force for water entry and tip expansion causing thinning of wall material. Understanding tip growth requires an analysis of the coordination of these processes and their regulation. Here we develop a quantitative physiological model which includes water entry by osmosis, the incorporation of cell wall material and the spreading of that material as a film at the tip. Parameters of the model have been determined from the literature and from measurements, by light, confocal and electron microscopy, together with results from experiments made on dye entry and plasmolysis in Lilium longiflorum. The model yields values of variables such as osmotic and turgor pressure, growth rates and wall thickness. The model and its predictive capacity were tested by comparing programmed simulations with experimental observations following perturbations of the growth medium. The model explains the role of turgor pressure and its observed constancy during oscillations; the stability of wall thickness under different conditions, without which the cell would burst; and some surprising properties such as the need for restricting osmotic permeability to a constant area near the tip, which was experimentally confirmed. To achieve both constancy of pressure and wall thickness under the range of conditions observed in steady-state growth the model reveals the need for a sensor that detects the driving potential for water entry and controls the deposition rate of wall material at the tip.