Functional characterization of a novel aquaporin from Dictyostelium discoideum amoebae implies a unique gating mechanism

The social amoeba Dictyostelium discoideum is a widely used model organism for studying basic functions of protozoan and metazoan cells, such as osmoregulation and cell motility. There is evidence from other species that cellular water channels, aquaporins (AQP), are central to both processes. Yet, data on D. discoideum AQPs is almost absent. Despite cloning of two putative D. discoideum AQPs, WacA, and AqpA, water permeability has not been shown. Further, WacA and AqpA are expressed at the late multicellular stage and in spores but not in amoebae. We cloned a novel AQP, AqpB, from amoeboidal D. discoideum cells. Wild-type AqpB was impermeable to water, glycerol, and urea when expressed in Xenopus laevis oocytes. Neither stepwise truncation of the N terminus nor selected point mutations activated the water channel. However, mutational truncation by 12 amino acids of an extraordinary long intracellular loop induced water permeability of AqpB, hinting at a novel gating mechanism. This AqpB mutant was inhibited by mercuric chloride, confirming the presence of a cysteine residue in the selectivity filter as predicted by our structure model. We detected AqpB by Western blot analysis in a glycosylated and a non-glycosylated form throughout all developmental stages. When expressed in D. discoideum amoebae, AqpB-GFP fusion constructs localized to vacuolar structures, to the plasma membrane, and to lamellipodia-like membrane protrusions. We conclude that the localization pattern in conjunction with channel gating may be indicative of AqpB functions in osmoregulation as well as cell motility of D. discoideum.     

Quantification of DNA uptake by Dictyostelium discoideum amoebae and the stability of the DNA during growth and development

We have developed a simple and accurate method to determine the amount of intact plasmid DNA taken up and retained by Dictyostelium discoideum amoebae during various transformation protocols. We have used this method to compare the efficiency of three different methods for introducing foreign DNA into D. discoideum amoebae. Both a calcium phosphate and a spheroplast fusion procedure gave good uptake, but no intracellular plasmid DNA was detectable after calcium chloride treatment. The exogenous DNA was rapidly lost after transformation but was 20-fold more stable during starvation rather than growth conditions, suggesting a possible approach to improving transformation efficiency. No transient expression of neomycin phosphotransferase activity of any of the heterologous animal or plant promoters used could be detected using a sensitive gel assay procedure.     

A study of passive potassium efflux from human red blood cells using ion-specific electrodes

Summary Using ion-specific electrodes, the potassium leakage induced by ouabain in human erythrocytes can be measured continuously and precisely near physiological conditions. Upon small additions of isotonic sucrose solution to a suspension of red cells in physiological saline the passive potassium efflux increases proportionally to the chloride ratio. The same result is obtained upon addition of hypertonic sucrose solution, suggesting that neither osmolarity nor intracellular concentrations have any influence on the passive potassium efflux. The independence of the potassium efflux and osmolarity can be verified by addition of a penetrating substance like glucose to the cell suspension. Adding water or hypertonic sodium chloride solution shows that the potassium efflux increases slightly in more concentrated salt solutions. Inasmuch as it can be interpreted as a pure ionic strength effect, this result supports the hypothesis of independence of potassium efflux and intracellular concentrations. The results of this investigation together with other studies show that the passive permeability of the human red blood cell to potassium depends uniquely on the membrane potential near physiological conditions, while it depends on parameters such as pH or concentrations for large membrane potentials. This suggests that two different mechanisms of transport might be involved: one would control the permeability under normal conditions; the other would represent a leak through the route normally used by anions and become important only under extreme conditions.     

Solute-dependent activation of cell motility in strongly hypertonic solutions in <Emphasis Type="Italic">Dictyostelium discoideum</Emphasis>, human melanoma HTB-140 cells and walker 256 carcinosarcoma cells

Published data concerning the effects of hypertonicity on cell motility have often been controversial. The interpretation of results often rests on the premise that cell responses result from cell dehydration, i.e. osmotic effects. The results of induced hypertonicity on cell movement of Dictyostelium discoideum amoebae and human melanoma HTB-140 cells reported here show that: i) hypertonic solutions of identical osmolarity will either inhibit or stimulate cell movement depending on specific solutes (Na⁺ or K⁺, sorbitol or saccharose); ii) inhibition of cell motility by hypertonic solutions containing Na⁺ ions or carbohydrates can be reversed by the addition of calcium ions; iii) various cell types react differently to the same solutions, and iv) cells can adapt to hypertonic solutions. Various hypertonic solutions are now broadly used in medicine and to study modulation of gene expression. The observations reported suggest the need to examine whether the other responses of cells to hypertonicity can also be based on the solute-dependent cell responses besides cell dehydration due to the osmotic effects.     

Hemolysis of human red blood cells by freezing and thawing in solutions containing polyvinylpyrrolidone: relationship with postthypertonic hemolysis and solute movements

An investigation was made into the effects of the presence of polyvinylpyrrolidone (PVP) on changes in human red blood cells suspended in hypertonic solutions, on posthypertonic hemolysis, and on freezing at temperatures down to ?12 °C.PVP is very effective at reducing hemolysis when the red blood cells are frozen at temperatures down to ?12 °C. However, the membranes of the cells recovered on thawing have become very permeable to sodium and potassium ions and there is a much increased hemolysis if the cells are resuspended in an isotonic solution of sodium chloride.The presence of PVP does not affect the dehydration of the cells or the development of a change in membrane permeability when the cells are shrunken in hypertonic solutions at 0 °C. Neither does its presence in the hypertonic solution reduce the extent of posthypertonic hemolysis at 4 °C (as measured by the hemolysis on resuspension in an isotonic solution of sodium chloride), but it is more effective than sucrose at reducing hemolysis when present in the resuspension solution. It is concluded that the PVP is able to prevent swelling and hemolysis of cells which are very permeable to cations by opposing the colloid osmotic pressure due to the hemoglobin. However, this does not explain how PVP is able to protect cells against freezing damage at high cooling rates, and a mechanism by which it might do this is discussed.     

Inhibition of multicellular development switches cell death of Dictyostelium discoideum towards mammalian-like unicellular apoptosis

The multicellular development of the single celled eukaryote Dictyostelium discoideum is induced by starvation and consists of initial aggregation of the isolated amoebae, followed by their differentiation into viable spores and dead stalk cells. These stalk cells retain their structural integrity inside a stalk tube that support the spores in the fruiting body. Terminal differentiation into stalk cells has been shown to share several features with programmed cell death (Cornillon et al. (1994), J. Cell Sci. 107, 2691-2704). Here we report that, in the absence of aggregation and differentiation, D. discoideum can undergo another form of programmed cell death that closely resembles apoptosis of most mammalian cells, involves loss of mitochondrial transmembrane potential, phosphatidylserine surface exposure, and engulfment of dying cells by neighboring D. discoideum cells. This death has been studied by various techniques (light microscopy and scanning or transmission electron microscopy, flow cytometry, DNA electrophoresis), in two different conditions inhibiting D. discoideum multicellular development. The first one, corresponding to an induced unicellular cell death, was obtained by starving the cells in a "conditioned" cell-free buffer, prepared by previous starvation of another D. discoideum cell population in potassium phosphate buffer (pH 6.8). The second one, corresponding to death of D. discoideum after axenic growth in suspension, was obtained by keeping stationary cells in their culture medium. In both cases of these unicellular-specific cell deaths, microscopy revealed morphological features known as hallmarks of apoptosis for higher eukaryotic cells and apoptosis was further corroborated by flow cytometry. The occurrence in D. discoideum of programmed cell death with two different phenotypes, depending on its multicellular or unicellular status, is further discussed.     

Ouabain-insensitive salt and water movements in duck red cells. I. Kinetics of cation transport under hypertonic conditions

Duck red cells in hypertonic media experience rapid osmotic shrinkage followed by gradual reswelling back toward their original volume. This uptake of salt and water is self limiting and demands a specific ionic composition of the external solution. Although ouabain (10(-4)M) alters the pattern of cation accumulation from predominantly potassium to sodium, it does not affect the rate of the reaction, or the total amount of salt or water taken up. To study the response without the complications of active Na-K transport, ouabain was added to most incubations. All water accumulated by the cells can be accounted for by net salt uptake. Specific external cation requirements for reswelling include: sufficient sodium (more than 23 mM), and elevated potassium (more than 7 mM). In the absence of external potassium cells lose potassium without gaining sodium and continue to shrink instead of reswelling. Adding rubidium to the potassium- free solution promotes an even greater loss of cell potassium, yet causes swelling due to a net uptake of sodium and rubidium followed by chloride. The diuretic furosemide (10(-3)M) inhibits net sodium uptake which depends on potassium (or rubidium), as well as inhibits net sodium uptake which depends on sodium. As a result, cell volume is stabilized in the presence of this drug by inhibition of shrinkage, at low, and of swelling at high external potassium. The response has a high apparent energy of activation (15-20 kcal/mol). We propose that net salt and water movements in hypertonic solutions containing ouabain are mediated by direct coupling or cis-interaction, between sodium and potassium so that the uphill movement of one is driven by the downhill movement of the other in the same direction.     

Effects of cooling rate on thermal shock hemolysis

The increase in thermal shock hemolysis in hypertonic sodium chloride with increasing cooling rate was confirmed. Thermal shock damage was also induced by hypertonic solutions of sucrose but it decreased with increasing cooling rate. The effect of cooling rate on thermal shock hemolysis appears to be due to the time that the cells are in the hypertonic solutions. The extent of the stress of the temperature reduction was independent of the cooling rate. In hypertonic sodium chloride susceptibility to thermal shock damage increased with increasing time of exposure at +25 °C (0–5 min) before decreasing with time (5–50 min). In contrast, with hypertonic sucrose, thermal shock damage increased gradually with time of exposure. The protective effects of sucrose on thermal shock hemolysis at a given osmolality can be explained by the different solution properties (e.g., ionic strength) of hypertonic sodium chloride and sucrose. These results suggest that the role of thermal shock damage during slow freezing should be reexamined.     

Diverse chemotactic responses of Dictyostelium discoideum amoebae in the developing (temporal) and stationary (spatial) concentration gradients of folic acid,cAMP, Ca(2+) and Mg(2+)

The responses of Dictyostelium discoideum amoebae to developing (temporal) and stationary (spatial) gradients of folic acid, cAMP, Ca(2+), and Mg(2+) were studied using the methods of computer-aided image analysis. The results presented demonstrate that the new type of experimental chambers used for the observation of single cells moving within the investigated gradients of chemoattractants permit time lapse recording of single amoebae and determination of the trajectories of moving cells. It was found that, besides folic acid and cAMP (natural chemoattractants for Dictyostelium discoideum amoebae), also extracellular Ca(2+) and Mg(2+) are potent inducers of these cells' chemotaxis, and the amoebae of D. discoideum can respond to various chemoattractants differently. In the positively developing gradients of folic acid, cAMP, Ca(2+), and Mg(2+) oriented locomotion of amoebae directed towards the higher concentration of the tested chemoattractants was observed. However, in the negatively developing (temporal) and stationary linear (spatial) gradients, the univocal chemotaxis of amoebae was recorded only in the case of the Mg(2+) concentration gradient. This demonstrates that amoebae can respond to both developing and stationary gradients, depending upon the nature of the chemoattractant. We also investigated the effects of chosen inhibitors of signalling pathways upon chemotaxis of D. discoideum amoebae in the positively developing (temporal) gradients of tested chemoattractants. Verapamil was found to abolish the chemotaxis of amoebae only in the Ca(2+) gradients. Pertussis toxin suppressed the chemotactic response of cells in the gradients of folic acid and cAMP but did not prevent chemotaxis in those of Ca(2+) and Mg(2+), while quinacrine inhibited chemotaxis in the gradients of folic acid, cAMP, and Ca(2+) but only slightly affected chemotaxis in the Mg(2+) gradient. None of the tested inhibitors causes inhibition of cell random movement, when applied in isotropic solution. Also EDTA and EGTA up to 50 mM concentration did not inhibit locomotion of amoebae in control isotropic solutions.     

Effects of chemoattractant pteridines upon speed of D. discoideum vegetative amoebae

Movements of D. discoideum vegetative amoebae responding to pteridine chemoattractants, folate acid and pterin, were recorded. A vector analysis of these images was performed to partition the speed and orientation components of these motility patterns. This study demonstrates that in addition to orientation (chemotaxis), stimulated speed (chemokinesis) is an important component of the directed migration of these amoebae. Furthermore, the primary difference in their response to folate versus pterin is in speed rather than orientation. The data support a model of directed migration of these cells in which there are (1) separate signal translation pathways consequent from folate versus pterin reception and (2) specific pathways leading to increase in orientation versus speed.     

Regeneration fragmentierter,nackter Protoplasten in Hefezellen

Summary The organism used wasSaccharomyces ellipsoideus. Exposure of yeast cells to a hypertonic strontium chloride generally does not establish typical plasmolysed cells. Rather, during a short period of exposure to plain hypertonic strontium chloride solution or to a hypertonic medium supplemented with high content of strontium chloride, the cell walls ruptured and subsequently the formation of spherical osmotically fragile bodies observed. Being associated with large droplet of protoplast together with the plasmolysed cells in the medium, abundantly small and numerous particles imperfectly for reliable counts to be made appear.About other kinds of salts, the protoplast of the yeast cell used separated from the wall smoothly when plasmolysed with sodium chloride or potassium chloride. But calcium chloride increasingly produced the cell rupture. However subsequent successive growth of small particles of protoplast could not be observed in the medium containing calcium chloride. Despite similar results using manganese chloride or magnesium chloride, it seems to cause the damage of the sub cellular structure during prolonged incubation. Similar result was obtained, when the cells were treated in polyethyleneglycol solution.After incubation into liquid strontium medium containing 2 mol strontium chloride, subcellular particles were isolated by the peculiar method (Fig. 6) and were incubated further. Such particles multiplicated, they being designated as K-fragment, and enlarged in size, and became K-body. The size of K-body was threefold as large as that of K-fragment. After further prolonged incubation K-body also enlarged in size, calling it K-cell. The protoplasm of K-cell was less well organized, but the early stage of the formation of daughter K-cell as revealed by microscopical observation beared resemblance to the budding found in mother yeast cell.The findings considered in conjunction with our cytochemical studies of the action of solutions of RNase or DNase, or the stain with some basic dyes, have led us to the conclusion that macromolecular fragment and nuclear substance present in the K-fragment, K-body and K-cell, respectively. Regeneration will result in the most miniature feature of the yeas cell.

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Herrn Prof. Dr. Karl Höfler zu seinem 70. Geburtstag in Verehrung gewidmet.     

Hemolysis of human red blood cells by freezing and thawing in solutions containing sucrose: relationship with posthypertonic hemolysis and solute movements

Human red blood cells were frozen at temperatures down to ?9 °C in solutions containing sucrose, and the hemolysis on thawing was measured. This was compared with the hemolysis caused by exposing the cells to high concentrations of sucrose and then resuspending them in more dilute solutions at 4 °C. The effects of the hypertonic solutions of sucrose on potassium, sodium, and sucrose movements were also investigated. It was found that sucrose does not prevent damage to the cells by very hypertonic solutions (whether during freezing and thawing or at 4 °C) but it does reduce hemolysis of cells previously exposed to these solutions if present in the resuspension (or thawing) solution. Evidence is presented that the damaging effects of the hypertonic solutions of sucrose occurring during freezing are associated with changes in cell membrane permeability but that posthypertonic hemolysis is not primarily associated with a “loading” of the cells with extracellular solutes in the hypertonic phase. It is concluded that sucrose may reduce hemolysis of red blood cells by slow freezing and thawing by reducing colloid osmotic swelling of cells with abnormally permeable membranes.     

An analysis of discoidin I binding sites in Dictyostelium discoideum (NC4).

Vegetative wild-type (strain NC4) D. discoideum cells and cells at the 10h stage of development (aggregation) were harvested in the presence of 0.5 M-galactose to remove any endogenous discoidin I already bound to the cell surface, and fixed with glutaraldehyde. Affinity-purified 125I-labelled discoidin I bound to these fixed cells in a specific manner, greater than or equal to 95% of binding being inhibited by 0.5 M-galactose. Binding of 125I-labelled discoidin I was essentially complete in 90 min at 22 degrees C. Based on specific radioactivity measurements, vegetative (0h) D. discoideum (NC4) cells bind approx. 8.4 x 10(5) discoidin I tetramers/cell and aggregated (10h) cells bind 5.1 x 10(5) discoidin I tetramers/cell, each exhibiting apparent positive co-operativity of binding with highest limiting affinity constants (Ka) of approx. 1 x 10(7) and 2 x 10(7) M-1, respectively. Klebsiella aerogenes, the food source used for growth of D. discoideum NC4 amoebae, also binds 125I-labelled discoidin I and this is greater than 99% inhibited by 0.5 M-galactose. However, at the levels of bacterial contamination present, greater than 97% of 125I-labelled discoidin I binding to D. discoideum cell preparations was to the cells themselves. Confirmation of the number of discoidin I tetramers bound per D. discoideum cell was obtained by elution of bound 125I-labelled discoidin I followed by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis and then quantification by scanning of stained discoidin I bands.     

Cell size in Dictyostelium

Cellular slime mold amoebae have become a model system for the study of cell motility and the cytoskeleton. A basic problem which all cells face that involves the cytoskeleton is how to control their size. The varied ways in which cellular slime mold amoebae change their cell size--by changing the size at which division occurs, by cell fusion, and by control over cytokinesis--are reviewed. A model is presented which attempts to explain how the mechanisms affected in certain cytokinesis mutants in Dictyostelium discoideum known as phg mutants could be involved in control of cell size in the predatory slime mold Dictyostelium caveatum.     

Some combined effects of hypertonic solutions and changes in temperature on posthypertonic hemolysis of human red blood cells

The combined effects of hypertonic solutions and temperature changes on the posthypertonic hemolysis of human red blood cells have been investigated. Cells were exposed to hypertonic solutions of sodium chloride and also to hypertonic solutions of the extracellular cryoprotective additive sucrose, such as would occur during the freezing of cells in an isotonic salt solution to which 15% $\text{w}\text{v}$ sucrose had been added. In both cases the extent of posthypertonic hemolysis was increased by temperature reduction per se when the osmolality of the extracellular solution exceeded about 1400 mOsm/kg water. The posthypertonic hemolysis of cells exposed to a hypertonic solution at 0 °C was reduced with the temperature of the resuspension solution up to 35 °C.     

Membrane leakage of solutes after thermal shock or freezing

Washed human erythrocytes were cooled at different rates from +37 °C to 0 °C in hypertonic solutions of either NaCl (1.2 m) or of a mixture of sucrose (40% $\text{w}\text{v}$) with NaCl (2.53% $\text{w}\text{v}$). Thermal shock hemolysis was measured and the surviving cells were examined for their mass and cell water content and also for net movements of sodium, potassium, and ¹⁴C-sucrose. The results were compared with those obtained from cells in sucrose (40% $\text{w}\text{v}$) initially, cooled at different rates to ?196 °C and rapidly thawed.The cells cooled to 0 °C in NaCl (1.2 m) showed maximal hemolysis at the fastest cooling rate studied (39 °C/min). In addition in the surviving cells this cooling rate induced the greatest uptake of ¹⁴C-sucrose and increase in cell water and cell mass and also entry of sodium and loss of cell potassium. A different dependence on cooling rate was seen with the cells cooled from +37 °C to 0 °C in sucrose (40% $\text{w}\text{v}$) with NaCl (2.53% $\text{w}\text{v}$). In this solution, survival decreased both at slow and fast cooling rates correlating with the greatest uptake of cell sucrose and increase in cell water. There was extensive loss of cell potassium and uptake of sodium at all cooling rates, the cation concentrations across the cell membrane approaching unity.The cells frozen to ?196 °C at different cooling rates in sucrose (40% $\text{w}\text{v}$) initially, also showed sucrose and water entry on thawing together with a loss of cell potassium and an uptake of cell sodium. More sucrose entered the cells cooled slowly (1.8 ° C/min) than those cooled rapidly (318 ° C/min).These results show that cooling to 0 °C in hypertonic solutions (thermal shock) and freezing to ?196 °C both induce membrane leaks to sucrose as well as to sodium and potassium. These leaks are not induced by the hypertonic solutions themselves but are due to the effects of the added stress of the temperature reduction on the membranes modified by the hypertonic solutions. The effects of cooling rate are explicable in terms of the different times of exposure to the hypertonic solutions. These results indicate that the damage observed after thermal shock or slow freezing is of a similar nature.     

Further studies on the partial double Donnan. Is isosmotic KCl solution isotonic with cells of respiratory trees of the holothurian Isostichopus badionotus Selenka?

As potassium, chloride and water traverse cell membranes, the cells of stenohaline marine invertebrates should swell if exposed to sea water mixed with an isosmotic KCl solution as they do when exposed to sea water diluted with water. To test this hypothesis respiratory tree fragments of the holothurian Isostichopus badionotus were exposed to five isosmotic media prepared by mixing artificial sodium sea water with isosmotic (611 mmol/l) KCl solution to obtain 100, 83, 71, 60 and 50% sea water, with and without 2 mmol/l ouabain. For comparison, respiratory tree fragments were incubated in sea water diluted to the same concentrations with distilled water, with and without ouabain. Cell water contents and potassium and sodium concentrations were unaffected by KCl-dilution or ouabain in isosmotic KCl-sea water mixtures. In tissues exposed to H(2)O-diluted sea water, cell water increased osmometrically and potassium, sodium and chloride concentrations decreased with dilution; ouabain caused a decrease in potasium and an increase in sodium but no effect on chloride concentrations. The isotonicity of the isosmotic KCl solution cannot be adscribed to impermeability of the cell membrane to KCl as both ions easily traverse the cell membrane. Rather, operationally immobilized extracellular sodium ions, which electrostatically hold back anions and consequently water, together with the lack of a cellward electrochemical gradient for potassium, resulting from membrane depolarization caused by high external potassium concentration, would explain the isotonicity of isosmotic KCl solution. The high external potassium concentration also antagonizes the inhibitory effect of ouabain on the Na(+)/K(+) ATPase responsible for sodium and potassium active transport.     

The effects of lactose on human erythrocytes

Human erythrocytes suspended in isotonic lactose solution lost potassium and continued to lose potassium even when resuspended in isotonic sodium chloride. The same phenomenon was observed when the cells were suspended in an isotonic solution of the sodium salt of glutamate, a nonpenetrating anion. The presence of 5 mEq per liter of sodium chloride in the lactose or sodium glutamate suspensions greatly reduced the initial potassium loss and the potassium loss when the cells were resuspended in sodium chloride solution. Salts of nonpenetrating anions were less or not effective in blocking lactose damage. The results indicate that absence of penetrating anions in the suspending media is the initiating condition of lactose damage. Chloride and consequently potassium are lost from the erythrocyte. Changes in cellular ionic pattern and/or changes in the cell membrane result in a nontransient damage manifested by continued potassium loss by lactose-treated cells resuspended in isotonic NaCl.     

The Relation Between the Late After-Potential and the Size of the Transverse Tubular System of Frog Muscle

This is an investigation of the effects on the late after-potential of immersing frog sartorius muscles in three kinds of modified Ringer's fluid; hypertonic, low chloride, and potassium-free. The late after-potential has been attributed to the depolarizing effect of an accumulation of potassium, during a preceding train of impulses, in the intermediary space of the model of a muscle fiber proposed by Adrian and Freygang. Both the hypertonic and low chloride solutions prolonged the late after-potential reversibly and the potassium-free solution shortened it. The effect of the low potassium solution fitted those data calculated from the model, but the effect of the hypertonic and low chloride solutions required an increase in size of the intermediary space of the model in order to fit the calculated data. An electron microscopic study of the muscles showed that the size of the transverse tubular system changed reversibly in the hypertonic and low chloride solutions in almost the amount necessary to fit the experimental data to the calculated data. This agreement between the change in size of the transverse tubular system and that of the intermediary space indicates that the intermediary space may be the transverse tubular system.     

The salting-in hypothesis of post-hypertonic lysis

The phenomenon of slow cooling cryoinjury has remained one of the primary areas of research in cryobiology since the early 1950s when it was first investigated thoroughly. Lovelock demonstrated that cell death from freezing and thawing was mainly due to exposure to hypertonic solutions and the subsequent dilution back to isotonic conditions. He suggested that the cell became permeable to sodium in hypertonic conditions leading to a loading of sodium during the hypertonic exposure, which caused the cell to swell past its elastic limit during resuspension in isotonic media (post-hypertonic lysis). This idea was pursued by Zade-Oppen, Farrant, and others who were able to show that the membrane became leaky to cations in hypertonic media but they could not provide any mechanism that would cause the cell to load up with sodium (other than an exchange of extracellular sodium for intracellular potassium, leaving the cell with the same cation concentration that it started out with). In the absence of such a mechanism, predicting post-hypertonic lysis from osmotic simulations cannot be done.A simplified model is proposed in which the intracellular milieu is composed of both KCl and a proteinaceous component that normally forms many salt bridges between amino acids with fixed charges. When the intracellular salt concentration increases, the proteins are “salted in” to solution (salt bridges are replaced with ionic interactions) thereby decreasing the intracellular cation concentration. Cation channels in the plasma membrane are opened by exposure to a high salt concentration (either inside or outside the membrane) allowing extracellular sodium to take the place of the intracellular potassium that is interacting with anionic groups on the proteins. Dilution of the external medium (which also occurs during melting) causes water to move into the cells, diluting the cytoplasm. The proteins are then “salted out” of solution and release the salt back to free ions in solution. The cell has an excess of intracellular ions and may swell past its elastic limit due to water influx. A simulation engine is developed based on the model and compared to results in the literature for freeze–thaw injury in human red blood cells.