The relationship between cell injury and osmotic volume reduction: III. Freezing injury and frost resistance in winter wheat

In order to distinguish between several possible mechanisms of frost hardening in winter wheat (Triticum aestivum L.) cells from two hardy and two tender cultivars were plasmolyzed in CaCl₂ solution at room temperature and cell volumes estimated by microscopic examination. Analyses of Boyle-van't Hoff plots of these data reveal that all cells from cultivars progressively increase their intracellular solute concentration up to 20 days hardening. This increase, which we had predicted from published calorimetric data to be the sole mechanism of hardening explained less than half of the increase in hardening seen in the most hardy cultivar, Kharkov. Hardening also increased the osmotically inactive volume.At CaCl₂ concentrations greater than 5%, plasmolyzed protoplasts departed further from the Boyle-van't Hoff prediction, remaining larger than expected until some higher concentration of CaCl₂, where protoplast volume again sharply decreased. In all cultivars except hardened Kharkov, the concentration of CaCl₂ producing this abrupt volume decrease had a freezing point corresponding to the killing temperature. If this concentration was exceeded during plasmolysis, then the protoplasts burst during deplasmolysis at some volume less than their original volume.We interpret these data to mean that, in addition to the often described hardening mechanism of increased cell solute and water binding, winter wheat shows a third mechanism, a mechanical resistance to protoplast shrinkage which produces volumes larger than those predicted during osmotic stress. The resisting element appears to be the plasma membrane itself. Shrinkage brings the membrane under compressive stress, developing tangential pressure within it. Cell injury occurs when the cell membrane area has been reduced to the point at which irreversible loss of membrane material is inevitable. Cell death occurs during deplasmolysis when the protoplast bursts because its membrane contains insufficient material to subtend the area of the cell wall.Of the cultivars tested, hardened Kharkov was unique in avoiding injury. Hardened Kharkov was injured only after the volume inflection had been greatly exceeded. Refractile droplets of lipid appeared in the cytoplasm of hardened Kharkov protoplasts during plasmolysis but disappeared during deplasmolysis suggesting that hardy Kharkov was able reversibly to store membrane lipids in cytoplasmic vesicles and return them to the membrane on deplasmolysis.     

The effect of plasmolysis and deplasmolysis on the permeability of plant membranes

The overall washing out of ions, especially⁸⁶Rb⁺ (as the tracer for K⁺), from hypocotyl segments of pumpkin (Cucurbita pepo L.) into distilled water or a CaCl₂ solution was studied, during plasmolysis with a saccharose solution and during deplasmolysis. Compartimental analysis was used to evaluate the⁸⁶Rb⁺ washing out kinetics. During plasmolysis, the washing out of⁸⁶Rb⁺ increases, due to two processes whose half-times are lower than those during washing out into the CaCl₂ solution. During deplasmolysis, the permeability of plasmalemma and tonoplast is substantially descreased, leading to washing out of most⁸⁶Rb⁺ from the cells. Plasmolysis differs from a mere decrease in the turgor pressure in the fact that after exchange for a hypotonic solution the membranes are irreversibly damaged. The aim of this work was to monitor the changes in the cell membrane permeability due to a change in the water potential of the cells, especially during plasmolysis and deplasmolysis.     

Coupling of excitation and cessation of cyclois in Nitella: role of divalent cations

The effect of external divalent cation salt solutions upon the association of an action potential and cessation of cytoplasmic streaming in Nitella was studied. Nitella cells remained excitable when immersed in solutions of CaCl₂, MgCl₂, BaCl₂, and SrCl₂. Cessation of streaming coincident with excitation occurred in solutions of CaCl₂ or SrCl₂ but not in solutions of MgCl₂ or BaCl₂. In cells exposed to solutions containing mixtures of MgCl₂ and CaCl₂, or MgCl₂ and SrCl₂, it was the [Ca]/[Mg] or [Sr]/[Mg] which determined the effect of an action potential upon the rate of streaming, rather than the absolute concentrations Ca⁺⁺ or Sr⁺⁺. The implications of these data are discussed with respect to the structure involved in the generation of cytoplasmic streaming and the relation of streaming to other types of biological motion.     

EFFECT OF SALINITY ON POLLEN I. POLLEN VIABILITY AS ALTERED BY INCREASING OSMOTIC PRESSURE WITH NaCl,MgCl2, and CaCl2

Petunia (Petunia hybrida Vilm. cv. ‘Snowstorm') plants were grown in saline solution (NaCl, MgCl₂, and/or CaCl₂) of 0, 1, 2, and 3 bars osmotic pressures. Pollen viability was tested by tetrazolium chloride staining and by germination (by the hanging drop method, using 15 % sucrose and 0.01 % boric acid as the nutrient medium, at 27 ± 1 C). Pollen viability decreased with increased salinity. Pollen from plants grown in single salt solutions of NaCl, MgCl₂, and CaCl₂ (each at 0, 1, 2, or 3 bars osmotic pressure) was germinated in base culture medium. Pollen viability decreased more with NaCl than with MgCl₂ or CaCl₂. In vitro studies of the effects of three salts, viz., NaCl, MgCl₂, and CaCl₂, on pollen germination and tube growth showed that NaCl inhibited germination and pollen tube growth more than did MgCl₂ or CaCl₂. MgCl₂ was least injurious, and even promoted tube growth at 0.5 and 0.75 bars osmotic pressure. Adding low concentrations of MgCl₂ reduced the toxic effect of NaCl and increased the percentage of germination. CaCl₂ reduced the effect of NaCl less than did MgCl₂. We conclude that specific ion effects were more important than osmotic pressure.     

Regeneration of cells from protoplasts ofClostridium acetobutylicum B643

Summary Conditions that allow regeneration of cells fromClostridium acetobutylicum strain B643 protoplasts were studied. Protoplast formation and stabilization in minimal media with 50 mM CaCl₂, 50 mM MgCl₂ and 0.3 M sucrose were crucial to subsequent regeneration on soft yeast extract agar containing 25 mM CaCl₂ and 25 mM MgCl₂. A regeneration frequency of 8–25% was consistently obtained.     

Vacuolated plant cells as ideal osmometer: reversibility and limits of plasmolysis, and estimation of protoplasm volume in control and water-stress-tolerant cells

Abstract. The osmotic behaviour of vacuolated plant cells (adaxial epidermal cells of Allium cepa bulb scales, and epidermal as well as chloroplast containing subepidermal stem base cells of Pisum sativum) was studied over a wide range of CaCl₂ concentrations. The following results were obtained.

• a. Allium cepa and Pisum sativum plant cells behave as an ideal osmometer as far as plasmolytic contraction of the protoplast is concerned.
• b. The protoplasts of these cells could be plasmolysed to 15–45% of their original volume without the loss of membrane semi-permeability.
• c. Cells plasmolysed in 1.0 kmol m^?3 CaCl₂ could be completely deplasmolysed and upon deplasmolysis the cells resumed protoplasmic streaming.
• d. The above findings (a-c) indicate that during gradual plasmolysis and deplasmolysis membrane semi-permeability is maintained.
• e. At very high plasmolysing concentrations vacuoles covered with the tonoplast separated from the rest of the protoplasm in some cells whereas others showed systrophy. Extruded vacuoles were able to respond to osmotic shrinkage.
• f. The non-solvent space in Allium cells of about 3% also corresponded to the protoplasm volume calculated from the protoplast geometry (mean from results of direct measurement method and subtraction method).
• g. Subepidermal stem base cells of water-stress-tolerant Pisum plants had a 75% greater non-solvent space than the control cells indicating that a water-stress-tolerant cell may contain a larger amount of protoplasm and/or a vacuole with a higher content of colloidal material in the vacuole.
• h. Water-stress-tolerant cells showed greater tolerance to osmotic dehydration (volume reduction) than control cells.

     

MICRURGICAL STUDIES IN CELL PHYSIOLOGY : V. THE ANTAGONISM OF CATIONS IN THEIR ACTIONS ON THE PROTOPLASM OF AM?BA DUBIA.

I. The Plasmalemma. 1. On the plasmalemma of amebæ CaCl₂ antagonizes the toxic action of LiCl better than it does NaCl, and still better than it does KCl. MgCl₂ antagonizes the toxic action of NaCl better than it does LiCl and still better than it does KCl. 2. CaCl₂ antagonizes the toxic action of LiCl and of KCl better than does MgCl₂: MgCl₂ antagonizes NaCl better than does CaCl₂. II. The Internal Protoplasm. 3. The antagonizing efficiency of CaCl₂ and of MgCl₂ are highest against the toxic action of KCl on the internal protoplasm, less against that of NaCl, and least against that of LiCl. 4. CaCl₂ antagonizes the toxic action of LiCl better than does MgCl₂: MgCl₂ antagonizes the toxic action of NaCl and of KCl better than does CaCl₂. 5. LiCl antagonizes the toxic action of MgCl₂ on the internal protoplasm more effectively than do NaCl or KCl, which have an equal antagonizing effect on the MgCl₂ action. III. The Nature of Antagonism. 6. When the concentration of an antagonizing salt is increased to a toxic value, it acts synergistically with a toxic salt. 7. No case was found in which a potentially antagonistic salt abolishes the toxic action of a salt unless it is present at the site (surface or interior) of toxic action. 8. Antagonistic actions of the salts used in these experiments are of differing effectiveness on the internal protoplasm and on the surface membrane.     

Glycerol fomation inDunaliella cells under non-growing conditions with hypertonic lithium or magnesium media

Glycerol formation ofDunaliella cells in non-growing media was investigated.Dunaliella tertiolecta andD. bioculata grew well in a NaCl medium but not at all in a LiCl or a MgCl₂ medium. When the cells originally suspended in a medium containing 0.5 M NaCl were transferred to media which contained one of 1 M NaCl, 1 M LiCl or 0.7 M MgCl₂, the intracellular glycerol content increased.D. tertiolecta cultured in either a 1 M LiCl or a 0.7 M MgCl₂ medium did not multiply, but maintained abilities to evolve O₂ in the light and absorb O₂ in thedark even after about a 5 day culture. From these results, it can be concluded that the halotolerance ofDunaliella to different kinds of salts is not directly related to osmoregulation by the glycerol formation.     

Studies on the permeability of living cells

Summary The penetration of the dye, dahlia, into the sap ofNitella has been determined in the presence of NaCl, KCl, MgCl₂ and CaCl₂ at various concentrations.NaCl is the least effective and MgCl₂ was the most effective in preventing penetration of the dye.It was found that NaCl antagonizes the action of CaCl₂ in certain proportions to a small degree but not sufficiently to permit the dye to penetrate at a normal rate.Published by permission of the Surgeon General.     

An improved method of transformation in Pseudomonads

Summary A protocol for producing competent Pseuclomonas aeruginosa, Pseudomonas putida, and Xanthomonas maltophilia was adapted and modified from existing methods. Cells were incubated on ice for 30 minutes in buffered 100 mM MgCl₂ followed by 30 minutes in buffered 100 mM CaCl₂ prior to addition of DNA. The MgCl₂-CaCl₂ incubation increased transformation efficiency two to three times, compared with protocols which use incubation in either Mg²⁺ or Ca²⁺, but not both.     

THE AGGLUTINATION OF RED BLOOD CELLS

1. Unsensitized sheep cells suspended in sugar solutions are agglutinated by electrolytes whenever the potential is depressed to 6 millivolts or less, except in the case of MgCl₂ or CaCl₂. 2. With these salts no agglutination occurs although there is practically no potential. The presence of these salts prevents acid agglutination. This is presumably due to a decrease in the "cohesion" between the cells. 3. Cells which have been sensitized with specific antibody, ricin, colloidal stannic hydroxide, or paraffin oil, are agglutinated whenever the potential is decreased below about 12 millivolts. 4. The agglutination by electrolytes is therefore primarily due to a decrease in the potential whereas agglutination by immune serum, ricin, etc., is due primarily to an increase in the critical potential.     

THE EFFECT OF CERTAIN ELECTROLYTES AND NON-ELECTROLYTES ON PERMEABILITY OF LIVING CELLS TO WATER

1. Permeability to water in unfertilized eggs of the sea urchin, Arbacia punctulata, is found to be greater in hypotonic solutions of dextrose, saccharose and glycocoll than in sea water of the same osmotic pressure. 2. The addition to dextrose solution of small amounts of CaCl₂ or MgCl₂ restores the permeability approximately to the value obtained in sea water. 3. This effect of CaCl₂ and MgCl₂ is antagonized by the further addition of NaCl or KCl. 4. It is concluded that the NaCl and KCl tend to increase the permeability of the cell to water, CaCl₂ and MgCl₂ to decrease it. 5. The method here employed can be used for quantitative study of salt antagonism.     

Leucine Uptake and Incorporation by Convolvulus Tissue Culture Cells and Protoplasts under Severe Osmotic Stress

The uptake and incorporation of radioactive leucine by Convolvulus arvensis L. suspension culture cells were studied under various osmotic conditions to provide information about the effects of osmotic stress at the cellular level and about the suitability of various osmotica for stabilizing protoplasts. When manitol, sorbitol, sucrose, or a mixture of CaCl₂ and KCl was added to the cells at a concentration normally used to stabilize protoplasts, the uptake of leucine was inhibited by 50 to 60% and incorporation by 37% with no major differences detected among these osmotica. NaNO₃ of a similar osmotic strength exerted considerably more inhibition, an inhibition that was reversed by as little as 10 mM simultaneous CaCl₂. None of the osmotica altered leucine or protein leakage from the tissue. In general, external solute concentrations below 0.36 osmolal slightly enhanced uptake and incorporation. At successively higher concentrations, uptake and incorporation decreased in a linear fashion, with no apparent discontinuity in the rate of decrease as the cells plasmolyzed. Cycloheximide inhibited both the uptake and the incorporation of leucine in all osmotic situations tested, exerting a much stronger inhibition upon the uptake by control tissue than upon that by cells in osmotica. Different cellulase enzyme preparations varied considerably in their effects on subsequent leucine uptake and incorporation.     

A plasmolytic cycle: The fate of cytoskeletal elements

Summary In most plant cells, transfer to hypertonic solutions causes osmotic loss of water from the vacuole and detachment of the living protoplast from the cell wall (plasmolysis). This process is reversible and after removal of the plasmolytic solution, protoplasts can re-expand to their original size (deplasmolysis). We have investigated this phenomenon with special reference to cytoskeletal elements in onion inner epidermal cells. The main processes of plasmolysis seem to be membrane dependent because destabilization of cytoskeletal elements had only minor effects on plasmolysis speed and form. In most cells, the array of cortical microtubules is similar to that found in nonplasmolyzed states except that longitudinal patterns seen in some control cells were never observed in plasmolyzed protoplasts of onion inner epidermis. As soon as deplasmolysis starts, cortical microtubules become disrupted and only slowly regenerate to form an oblique array, similar to most nontreated cells. Actin microfilaments responded rapidly to the plasmolysis-induced deformation of the protoplast and adapted to its new form without marked changes in organization and structure. Both actin microfilaments and microtubules can be present in Hechtian strands, which, in plasmolyzed cells, connect the cell wall to the protoplast. Anticytoskeletal drugs did not affect the formation of Hechtian strands.Abbreviations DIC differential interference contrast - DiOC₆(3) 3,3-dihexyloxacarbocyanine iodide Dedicated to Professor Walter Gustav Url on the occasion of his 70th birthday     

Excretion of peroxidase from horseradish hairy root in combination with ion supplementation

Summary The effect of ion-supplemented medium on peroxidase excretion from horseradish (Armoracia rusticana) hairy roots was studied. Supplementation of mannitol instead of ions revealed that the excretion was stimulated not by osmotic pressure in the medium but by ionic properties. Extracellular peroxidase activity per dry cell was proportionally correlated with the ionic strength of the cations. CaCl₂ or MgCl₂ was found to be the most effective agent for excretion among other combinations. CaCl₂ supplementation at the beginning of the culture caused higher peroxidase production in the medium without a significant loss of final cell mass compared with CaCl₂ addition during the culture. Repeated batch culture with 50 mM CaCl₂ supplementation allowed a continuous retention of cell viability over 149 days and produced a great amount of extracellular peroxidase, 12-fold higher than that achieved in a 40-day-old batch culture with 50 mM CaCl₂ supplementation. Correspondence to: T. Kobayashi     

Acid Metallophosphatase from the Ameba Amoeba proteus

Tartrate-resistant acid phosphatase (TR-AcPh) from the ameba Amoeba proteus is represented by 3 bands (electromorphs) revealed after disk-electrophoresis in PAAG, using 2-naphthylphosphate as substrate. The presence of 50 mmol/l MgCl₂ or CaCl₂ in the incubation mixture increases activities of all electromorphs of TR-AcPh, while of ZnCl₂, of two of them. The activity of the TR-AcPh electromorphs also rose after the 30-min incubation of the gels in MgCl₂, CaCl₂ or ZnCl₂ (10 and 100 mM) before gel staining. However, 1 M ZnCl₂, unlike 1 M CaCl₂ or 1 M MgCl₂, partly inactivated two out of three TR-AcPh electromorphs. The TR-AcPh electromorphs were inhibited by 1,10-phenanthroline (1,10-Ph), EDTA, and EGTA (all at a concentration of 5 mM) faster than by H₂O₂ (10 mM). The inactivation of the TR-AcPh electromorphs by the chelating agents did not depend (EGTA) or nearly did not depend (EDTA, 1,10-Ph) on their concentration (0.05, 0.5, and 5 mM). Out of 5 tested ions (Mg²⁺, Ca²⁺, Fe²⁺, Fe³⁺, and Zn²⁺), only Zn ions reactivated the TR-AcPh electromorphs inactivated by 1,10-Ph, EDTA or EGTA. The TR-AcPh electromorphs were reactivated worse after inactivation by EGTA than by EDTA or 1,10-Ph. It is suggested that the active site of TR-AcPh contains the zinc ion essential for catalytic activity of this enzyme, i.e., TR-AcPh of A. proteus is a metallophosphatase performing the phosphomonoesterase activity in acidic medium.     

Tentacle contraction and ultrastructure inDiscophrya collini: The response to cations

Summary Discophrya collini is a suctorian protozoan with contractile tentacles containing a microtubule-lined canal and microfilaments. The effects of a range of cations on tentacle contraction and ultrastructure have been determined. Treatment with 80 mM CaCl₂ and 95 mM MgCl₂ causes contraction to 28% and 57% of the control length respectively. Re-extension takes over 4 hours in the culture medium, but CaCl₂-treated tentacles are re-extended after a 5 minutes treatment with 10^–2 M EDTA or 5 × 10^–3 M EGTA. CuCl₂ causes a significant contraction at 10^–5 M (to 77%); LaCl₃ at 10^–4 M (to 65%); ZnCl₂ at 10^–2 M (to 65%), but BaCl₂, CoCl₂, MnCl₂, NiCl₂, and SrCl₂ cause significant changes only at 10^–1 M.The cytoplasm of CaCl₂-treated cells contains two forms of membraneous structures when viewed in TEM; that of MgCl₂-treated cells reveals granular areas of medium electron density. None of these features are seen in control cells. The microtubules of the tentacle canal appear to be intact upon its retraction into the cell with no change occurring in the numbers or relative positions of the microtubules. The tentacle cortex is wrinkled. It is suggested from this and previous work that tentacle contraction may be mediated by a microfilament-based mechanism, and that calcium may be involved.     

The site of penetration resistance to water in plant protoplasts

Summary The main purpose of this investigation was to determine the primary site of resistance to the penetration of water in the protoplasm of inner epidermal cells of theAllium cepa bulb scale. Since it is known that the tonoplast has a very high water permeability, it was left to decide whether the mesoplasm and/or the plasmalemma is the main barrier. According to a theory ofHöfler, the mesoplasm is the main barrier. Because it is not possible to isolate the plasmalemma, the influence of the mesoplasm was removed by causing rosette systrophy. In rosette systrophy, almost all of the mesoplasm is collected arround the nucleus and the tonoplast and plasmalemma lie adjacent in the greater part of the protoplast.Cells with and without systrophy are found in the same preparation but show no great difference in water permeability. The systrophied cells have even a lower water permeability constant than the non-systrophied cells. This indicates clearly that the mesoplasm is of no significant importance for water permeability, and that the primary site of penetration resistance to water is the plasmalemma.It was possible to measure the water permeability constants of tonoplasts. While the 2 K_wo values for protoplasts are approximately 6–8×10^–4 cm/sec, those for tonoplasts are about 100 times higher.The water permeability constants found with glucose solutions were essentially the same as those found in solutions of KCl + CaCl₂. Other less inert substances, such as EDTA, give different (higher) values.Using the method of partial deplasmolysis and plasmolysis, it was possible to change the protoplast volume several times, once until the eight time in K-Ca solutions and until the fifth time in glucose solutions.The water permeability constants do not change appreciably, neither in the sequential plasmolysis steps nor between deplasmolysis and plasmolysis. Yet there is a small but significant difference between deplasmolysis and plasmolysis values. The deplasmolysis values are slightly higher.In the K-Ca solutions the tonoplasts which were formed showed a linear expansion which indicates ion permeability. Permeability constants are 0.003–0.006×10^–4 cm/sec, about in the same range as those of moderate anelectrolyte permeability.     

Halophilic and salts tolerant protoplast cultures of mangrove plants, Sonneratia alba and Avicennia alba

The effects of sea salts, NaCl, KCl, MgCl₂, MgSO₄, and CaCl₂, on the growth of protoplast cultures of two mangrove species, Sonneratia alba and Avicennia alba, were investigated using 96-well culture plates. Plants of these two species naturally grow at the seaward side of a mangrove forest. Cotyledon protoplasts of S. alba showed halophilic nature to NaCl, KCl, and MgCl₂ at low concentrations (10–50 mM) when cultured in Murashige and Skoog’s (MS) medium containing 0.6 M mannitol. CaCl₂ at a concentration higher than 25 mM was inhibitory to cell growth. On the other hand, in protoplast culture of A. alba suspension cells, which were induced from cotyledon tissues, in the modified amino acid (mAA) medium containing 1.2 M sorbitol, tolerance to NaCl, MgCl₂ and MgSO₄ were observed at a wide range of concentrations up to 400 mM. CaCl₂ was always inhibitory for cell divisions in A. alba, but stimulatory for spherical enlargement of cells. However, no difference in cell enlargement was observed among other salts. Similarity and difference in reactivity to salts between protoplasts and suspension cells from our previous studies were discussed in relation to the site of salt tolerance or halophilic adaptation within mangrove cells. For protoplast cultures, the site(s) for response of S. alba and A. alba are located in the cytoplasm and/or the cell membrane.     

Plasmolysis shape in relation to freeze-hardening of cabbage plants and to the effect of penetrating solutes*

Abstract In conformity with earlier results, low-temperature hardening of cabbage seedlings lowered the osmotic potential and increased the permeability to thiourea of the petiole cells. It also decreased the time required for rounding-up of the protoplasts in cells plasmolysed in 1. 5 × isotonic (or higher) glucose or CaCl₂ solutions. Solutions of dimethylsulphoxide (DMSO), thiourea, urea, and glycerol each accelerated the rate of rounding-up of protoplasts in plasmolysed cells, compared to the rate in glucose solution of the same hypertonicity. Each also penetrated the cell membranes as indicated by deplasmolysis. Only in the case of DMSO, in which there was very rapid deplasmolysis (5–6 min), was this rounding-up due to protoplast expansion. In the case of thiourea (deplasmolysis within 30–60 min) rounding-up occurred almost immediately (less than 2 min), before protoplast expansion was sufficient to induce it. It was concluded that the accelerated rounding-up was due to a rapid osmotic adjustment in the protoplasm by the penetrating solution, which increased its water content and decreased its viscosity.