Ion transport and osmotic adjustment in Escherichia coli in response to ionic and non-ionic osmotica

Bacteria respond to osmotic stress by a substantial increase in the intracellular osmolality, adjusting their cell turgor for altered growth conditions. Using Escherichia coli as a model organism we demonstrate here that bacterial responses to hyperosmotic stress specifically depend on the nature of osmoticum used. We show that increasing acute hyperosmotic NaCl stress above ∼1.0 Os kg⁻¹ causes a dose-dependent K⁺ leak from the cell, resulting in a substantial decrease in cytosolic K⁺ content and a concurrent accumulation of Na⁺ in the cell. At the same time, isotonic sucrose or mannitol treatment (non-ionic osmotica) results in a gradual increase of the net K⁺ uptake. Ion flux data are consistent with growth experiments showing that bacterial growth is impaired by NaCl at the concentration resulting in a switch from net K⁺ uptake to efflux. Microarray experiments reveal that about 40% of upregulated genes shared no similarity in their responses to NaCl and sucrose treatment, further suggesting specificity of osmotic adjustment in E. coli to ionic and non-ionic osmotica. The observed differences are explained by the specificity of the stress-induced changes in the membrane potential of bacterial cells highlighting the importance of voltage-gated K⁺ transporters for bacterial adaptation to hyperosmotic stress.     

Changes in water relation parameters under osmotic and salt stresses in maize and sorghum

A relatively drought tolerant cultivar of maize ( Zea mays L. cv. Pioneer 3950) and a drought tolerant line of sorghum ( Sorghum bicolor [L.] Moench cv. ICSV 112) were grown hydroponically for 11 days. Treatments for non-ionic osmotic and salt stresses were started at the 8th day by addition of polyethylene glycol 6000 and NaCl, respectively, at 200 mOsm equivalent concentrations in the presence or absence of 0. 1 μ M abscisic acid. Relative growth rate was depressed by both stress factors, more severely for maize than sorghum. Abscisic acid increased the growth rate and reverted the negative effect of NaCl in maize, while sorghum was only slightly affected. In general, sorghum had higher levels of K⁺ and lower levels of Na⁺ and the K⁺/Na⁺ ratio was further increased by abscisic acid treatment. From the pressure-volume curves, osmotic potential, the water potential at turgor loss point, bulk elastic modulus and the water saturation deficit at initial turgor loss were estimated. Most significantly, sorghum had a higher elastic modulus than maize and it decreased under osmotic treatment, while in maize it increased under NaCl stress. The results suggest that bulk tissue turgor was not limiting growth under these conditions and underscores the possible implications of changes in the elastic condition of the cell walls in stress responses.     

Water efflux from the surface of field-grown grass roots. Observations by cryo-scanning electron microscopy

The objective of this study was to compare whole plant growth and physiological responses to salt stress of two Acacia nilotica subspecies (ssp. cupressiformis and ssp. tomentosa ). Salt stress was induced by adding NaCl at different concentrations to the nutrient solution: 0, 75, 100 and 200 m M . After one month under such stress, plants were still healthy and actively growing in both subspecies up to 100 m M NaCl. Water potential (Ψ) and osmotic potential (π) decreased with salinity and the lower π enabled the plants to maintain turgor. Höfler diagrams confirmed that osmotic adjustment had occurred under all treatments. Furthermore, the point of zero turgor occurred at a higher relative water content. An increase in the elastic modulus (ɛ) was observed under stress (low elasticity of the cell wall). Both osmotic adjustment and a high ɛ modified the capacity of both subspecies to maintain a positive water balance. Accumulation of ions (Na⁺, K⁺ and Cl⁻) and proline could explain such osmotic adjustment. Acacia nilotica ssp. cupressiformis showed a higher absorption of K⁺ than ssp. tomentosa up to 100 m M NaCl treatment.     

Sodium ion transport in Neurospora crassa

Na⁺ influx and efflux in Neurospora crassa RL21a can be studied separately to calculate net Na⁺ movements. In the absence of external K⁺, Na⁺ influx was independent of the K⁺ content of the cells, but when K⁺ was present, the inhibition of Na⁺ influx by external K⁺ was higher the higher the K⁺ content. Efflux depended on the K⁺ and Na⁺ content, and on the history of the cells. Efflux was higher the higher the Na⁺ and K⁺ contents, and, in low-K⁺ cells, the efflux was also higher in cells grown in the presence of Na⁺ than when Na⁺ was given to cells grown in the absence of Na⁺. Addition of K⁺ to cells in steady state with external Na⁺ resulted in a net Na⁺-loss. In cells grown without Na⁺ this loss was a consequence of the inhibition of Na⁺ influx. In Na⁺-grown cells, addition of K⁺ inhibited Na⁺ influx and increased Na⁺ efflux.     

Physiological effects of Na2SO4 and NaCl on callus cultures of Brassica campestris (Chinese cabbage)

Hypocotyl-derived callus cultures of Brassica campestris L. ssp. pekinensis cv. Kim-jung (Chinese cabbage) were grown on Murashige and Skoog medium containing no additional salt, NaCl or Na₂SO₄. Na₂SO₄ was more than twice as inhibitory in comparison to the same concentration of NaCl when growth and fresh:dry weight ratios of established callus were measured. Levels of protein, starch, sucrose and α-amino nitrogen were not significantly altered in salt-grown callus. Concentrations of reducing sugars and chlorophyll were 2–3 times greater in callus grown on either salt. Proline concentration increased 15–20 fold on the highest levels of salt. Final concentrations (reached in 20–24 days) were closely correlated to the initial Na⁺ concentration of the medium, regardless of salt type. The osmotic potential in callus transferred to NaCl or Na₂SO₄ reached a maximum negative value after 16 days. For both salts, subsequent increases were correlated to increases in fresh:dry weight and growth. On both salts, turgor remained relatively constant (0. 6–0.75 MPa). Changes in Na⁺, K⁺, Mg²⁺ and Ca²⁺ content were correlated to initial Na⁺ concentration in the medium, not salt type. Accumulation of Na⁺ was accompanied by loss of K⁺ and Mg²⁺. Six to seven times less sulfate was measured in callus grown on Na₂SO₄ than chloride in callus grown on similar concentrations of NaCl.     

Salinity response of a freshwater charophyte, Chara vulgaris

Abstract. Chara vulgaris L. growing in an oligohaline lake was adapted to laboratory conditions and subjected to long-term salinity treatments ranging from 0 to 350 mol m ³ NaCl added to the lake water (40–680 mosmol kg ¹). Osmotic potential and concentration of the main osmotically active solutes (K⁺, Na⁺, Mg²⁺, Cl and sucrose) in the vacuolar sap of the central internodal cells were estimated. C. vulgaris did regulate turgor but incompletely. Turgor decreased from 335 mosmol kg ¹ under control conditions to 52–111 mosmol kg ¹ at 350 mol m ³ NaCl. The enhancement of πⁱ was achieved by increase in both ions and sucrose. Sterile and fertile plants differed in their response to osmotic stress. In sterile plants, the ions accounted for about 87% of the vacuolar osmotic potential. The increase of πⁱ under osmotic stress was exclusively due to an accumulation of Na⁺ and Cl^-. In fertile plants, sucrose accounted for about 35% of πⁱ and ions for about 51% Under osmotic stress, sucrose content increased together with the ionic content of Na⁺ and Cl^-.     

Effects of salinity and phosphate on ion distribution in lupin leaflets

Lupin ( Lupinus luteus L. cv. Weiko III) were grown in nutrient solution over a range of inorganic phosphate (P_i) concentrations, with or without 50 m M NaCl. Plants with high P_i (2 m M ) and salt showed progressive leaf necrosis and had higher concentrations of total phosphate than plants grown with high P_i alone. Most of the extra total phosphate in salt treated plants was in the P_i form. P_i supply did not influence Na⁺, K⁺ or Cl⁻ concentrations in epidermal vacuoles or mesophyll cells. However, epidermal vacuoles accumulated more monovalent cations (Na⁺ and K⁺) than Cl⁻, and in vacuoles of plants grown with 0.1 m M P_i additional P_i was accumulated, possibly to maintain charge balance. Plants grown with 2 m M P_i did not accumulate additional P_i in epidermal vacuoles, but showed higher phosphorus levels in cell walls. It is suggested that at moderate phosphorus concentrations P_i plays a role in epidermal osmotic adjustment, possibly explaining the beneficial role of additional phosphorus on salt stressed plants. At high P_i supply with salt, P_i does not contribute to osmotic adjustment and instead accumulates in cell walls. However, the cause of leaf damage under conditions of high phosphorus supply and salinity is still not entirely clear.     

Salt tolerance of the reed plant Phragmites communis

Reed plants ( Phragmites communis Trinius) were grown at NaCl concentrations up to 500 m M and their growth, mineral contents and leaf blade osmotic potential were determined. Addition of NaCl up to 300 m M did not affect growth significantly. Sucrose, Cl^-and Na⁺ concentrations in the shoots increased with the salinity of the medium and the shoot water content decreased. K⁺ always contributed most to the leaf osmotic potential. Even in the presence of 250 m M NaCl in the rooting medium, the leaf blade contained only 50 mM Na⁺, suggesting that the plants have an efficient mechanism for Na⁺ exclusion. ²²Na⁺ uptake experiments suggested that the retranslo-cation of absorbed Na⁺ from shoots to the rooting medium lowered the uptake of Na⁺.     

Elevated Levels of Glucose and L-Fucose Reduce 22Na+ Uptake and Whole Cell Na+ Current in Cultured Neuroblastoma Cells

Abstract: Na⁺ flux was studied in cultured neuroblastoma cells grown in medium containing increased glucose or L - fucose concentrations. Chronic exposure of neuroblastoma cells to 30 m M glucose or 30 m M L-fucose caused a decrease in ouabain-sensitive and veratridine-stimulated ²²Na⁺ uptake compared with cells cultured in unsupplemented medium. The Na⁺ current, determined by using whole-cell configuration of the patch clamp, was also decreased in these cells. Tetrodotoxin (3 μ M ), which blocked whole cell Na⁺ currents, also blocked veratridine-stimulated ²²Na⁺ accumulation. Culturing cells in medium containing 30 m M fructose as an osmotic control had no effect on Na⁺ flux. Specific [³H] saxitoxin binding was not affected by 30 m M glucose or 30 m M L-fucose compared with cells grown in unsupplemented medium, suggesting that the number of Na⁺ channels was not decreased. These studies suggest that exposing cultured neuronal cells to conditions that occur in the diabetic milieu alters Na⁺ transport and Na⁺-channel activity.     

K+ status and ABA affect both exudation rate and hydraulic conductivity in sunflower roots

Twenty‐day‐old sunflower plants ( Helianthus annuus L. cv. Sun‐Gro 380) grown in nutrient solutions with different KCl levels were used to study the effects of K⁺ status of the root and of abcisic acid (ABA) on the exudation rate (J_v), the hydraulic conductivity of the root (L_p), the fluxes of exuded K⁺ and Na⁺ (J_K and J_Na), and the gradient of osmotic pressure between the xylem and the external medium. J_v and L_p increased in direct proportion to the K⁺ starvation of the root. Also addition of ABA (4 µ M ) at the onset of exudation in the external medium made J_v and L_p rise, and this effect also increased with the degree of K⁺ starvation. Similarly, K⁺ starvation and ABA promoted both the flux of exuded Na⁺ and the accumulation of Na⁺ in the root. We suggest that ABA acts as a regulating signal for the radial transport of water across the root, and that potassium may be an effector of this mechanism.     

Changes in sodium and potassium in Nitellopsis cells treated with transient salt stress

Abstract. Nitellopsis cells grown in fresh water have a relatively low cytoplasmic Na⁺ (11 mol m⁻³) and high cytoplasmic K⁺ (90 mol m⁻³) content. A 30-min treatment with 100 mol m⁻³ external NaCl resulted in a high [Na⁺]_c (90 mol m⁻³) and a low [K⁺]_c (33 mol m⁻³), Subsequent addition of external Ca²⁺ (10 mol m⁻³) prevented Na⁺ influx and then [Na⁺]_c decreased slowly. Changes in [K⁺]_c were opposite to [Na⁺]_c. During the recovery time vacuolar Na⁺ increased, while vacuolar K⁺ decreased. Since all these processes proceeded also under ice-cold conditions, the restoration of original cytoplasmic ion compositions is suggested to be a passive nature. The notion that the passive movement of ions across the tonoplast can act as an effective and economic mechanism of salt tolerance under transient or under mild salt stress conditions is discussed.     

Effects of external NaCI, and of changes in turgor pressure and volume, on K+ concentrations in Chlorella emersonii

Summary. Soluble potassium concentrations were determined for the slightly vacuolated, unicellular, walled alga Chlorella emersonii. Sap of cells grown in 1 mol m⁻³ NaCI contained 140 mol m⁻³ K⁺ and sap of cells grown in 125, 200, and 335 mol m⁻³ NaCI contained 160-180 mol m⁻³ K ⁺.
The possible regulation of K ⁺ concentrations by a system of lurgor and volume maintenance was investigated by supplying 3-0-methylglucose. This solute accumulates to 85-230 mol m⁻³ in C. emersonii , but is not metabolized. Accumulation of 3-0-methylglucose increased the volume of cells grown at both low and high NaCI by about 10%. Furthermore, accumulation of 3-0-methylglucose also increased turgor pressures of cells grown in 1 and 125 mol m⁻³ NaCI by 0.3 and 0.2 MPa, respectively. (Similar measurements were not attempted for cells grown in 200 and 335 mol m⁻³ NaCI, because of the insensitivity of available methods to measure turgor pressure of cells exposed to high external osmotic pressures.)
At all NaCI concentrations, the K ⁺ concentrations of cells which had accumulated 3-0-methylglucose were only 10-20 mol m⁻³ lower than K⁺ in cells which had not been supplied with 3-0-methylglucose. In contrast, accumulation of 3-0-methylglucose greatly decreased concentrations of the endogenous osmotic solutes, proline and sucrose, which accumulated in cells grown in 125 mol m⁻³ and higher NaCI concentrations.
It is concluded that K⁺ concentrations in Chlorella emersonii are not controlled by a system of turgor and volume maintenance.     

ɛ-(γ-Glutamyl)lysine cross-links of spore coat proteins and transglutaminase activity in Bacillus subtilis

Abstract The capacity to transport potassium and to discriminate between the different alkali cations has been found to affect sodium tolerance in Saccharomyces cerevisiae . Mutants with a defective capacity to transport K⁺ were more sensitive to high concentrations of Na⁺ because they accumulated more Na⁺ and less K⁺ than wild-type cells which showed high discrimination between K⁺ and Na⁺.     

Cellular mechanisms of potassium transport in plants

Potassium (K⁺) is the most abundant ion in the plant cell and is required for a wide array of functions, ranging from the maintenance of electrical potential gradients across cell membranes, to the generation of turgor, to the activation of numerous enzymes. The majority of these functions depend more or less directly upon the activities and regulation of membrane-bound K⁺ transport proteins, operating over a wide range of K⁺ concentrations. Here, we review the physiological aspects of potassium transport systems in the plasma membrane, re-examining fundamental problems in the field such as the distinctions between high- and low-affinity transport systems, the interactions between K⁺ and other ions such as NH₄⁺ and Na⁺, the regulation of cellular K⁺ pools, the generation of electrical potentials and the problems involved in measurement of unidirectional K⁺ fluxes. We place these discussions in the context of recent discoveries in the molecular biology of K⁺ acquisition and produce an overview of gene families encoding K⁺ transporters.     

An effect of Na+ on K+ uptake in intact seedlings of Zea mays

Models for the regulation of K⁺ uptake in higher plant roots have become more complex as studies have moved from the level of excised low-salt roots to that of intact plants grown under fully autotrophic conditions. In this paper we suggest that some of the differences between the conditions are qualitative, possibly requiring fundamental changes to the model, rather than simply quantitative.
The uptake of K⁺ by low-salt roots of Zea mays L. [(A619 x Oh 43) x A632], was independent of Na⁺ concentration over a wide range. However, independence of Na⁺ was not the case in plants grown on complete nutrient medium in the light: inclusion of Na⁺ in the uptake medium enhanced K⁺ uptake. In the presence of Na⁺, K⁺ uptake rates were similar in whole plants with high root K⁺ contents to rates in excised or intact, low-salt roots.     

Involvement of Na+,K+-ATPase in the Mitogenic Effect of Insulin-Like Growth Factor-I on Cultured Rat Astrocytes

Abstract: We have previously reported that insulin/insulin-like growth factor (IGF)-I induced the α1 isoform of Na⁺,K⁺-ATPase in cultured astrocytes. In this study the effects of insulin/IGF-I on Na⁺,K⁺-ATPase activity and cell proliferation were examined in astrocytes cultured under the various conditions, to test the possible involvement of the enzyme activity in the mitogenic action of IGF-I on astrocytes. Insulin increased Na⁺,K⁺-ATPase activity and stimulated cell proliferation in subconfluent astrocytes (cultured for 7–14 days in vitro). In contrast, these effects were not observed in confluent cells (cultured for 28 days). Furthermore, insulin stimulated neither the enzyme activity nor [³H]thymidine incorporation in astrocytes preincubated in fetal calf serum-free medium for 2 days (quiescent cells) and treated with dibutyryl cyclic AMP (differentiated cells). The increases in Na⁺,K⁺-ATPase activity and expression of the α1 mRNA preceded the mitogenic effect. ¹²⁵I-IGF-I binding experiment showed that all the cells used here had similar binding characteristics. The insulin-induced increase in enzyme activity was not affected by 1-(5-isoquinolinesulfonyl)-2-methylpiperazine (H-7), and it was observed even in Ca²⁺-free medium. The stimulation by IGF-I of [³H]thymidine incorporation was attenuated by ouabain and a low external K⁺ level. These findings suggest that stimulation of Na⁺,K⁺-ATPase activity is involved in the mitogenic action of IGF-I on cultured astrocytes.     

Salinity tolerance of Kosteletzkya virginica. II. Root growth, lipid content, ion and water relations

Abstract. Kosteletzkya virginica (L.) Presl., a dicot halophyte native to brackish tidal marshes, was grown on nutrient solution containing 0. 85, 170 or 255 mol m ³ NaCl, and the effects of external salinity on root growth, ion and water levels, and lipid content were examined in successive harvests. Root growth paralleled shoot growth trends, with some enhancement observed at 85 mol m ³ NaCl and a reduction noted at the higher salinities. Root Na⁺ content increased with increasing external NaCl, but remained constant with time for each treatment. K⁺ content, although lower in salt-grown plants after 14 d salinization, subsequently increased to levels comparable to unsalinized plants. A strong K⁺ affinity was reflected in the increased K⁺/Na⁺ selectivity of salt-grown plants and by their low Na⁺/K⁺ ratios. Cl levels rose in salinized plants and values were double or more those for Na⁺, indicating the possibility of a sodium-excluding mechanism in roots. Root phospholipids and sterols, principal membrane constituents, were maintained or elevated and the free sterol/phospholipids ratio increased in salinized K. virginica plants, suggesting retention of overall membrane structure and decreased permeability. This response, considered in light of root calcium maintenance and high potassium levels, suggests that salinity-induced changes in membrane lipid composition may be important in preventing K⁺ leakage from cells.     

Seasonal changes in ionoregulatory variables of the glass eel Anguilla anguilla following estuarine entry: comparison with resident elvers

In the present study, glass eels Anguilla anguilla in the Minho River estuary (41·5° N, 8·5° W) decreased in size (standard length, L _S and mass, M ) from the beginning (autumn) to the end of the sampling season (summer). On the other hand elvers increased in L _S and M from spring to summer and were significantly larger than glass eels in paired comparisons. Branchial Na⁺/K⁺-ATPase and vacuolar (V-type) proton ATPase ( in vitro activities), two important ion transporting pumps, did not show significant seasonal changes in either glass eels or elvers although in glass eels Na⁺/K⁺-ATPase (activity) expression was significantly higher than in elvers. In a single month comparison Na⁺/K⁺-ATPase branchial mRNA expression was also higher in glass eels as was the protein level expression of both Na⁺/K⁺-ATPase and NKCC (Na⁺:K⁺:2Cl⁻ co-transporter). Immunofluorescence microscopy indicated apical CFTR Cl⁻ channel labelling in Na⁺/K⁺-ATPase positive chloride cell in glass eels which was absent in elvers. Whole body sodium concentration and percentage water did not show significant seasonal differences in either glass eels or elvers although there were significant differences between these two groups during some months.     

Stomatal limitation of photosynthesis and reduced growth of the halophyte, Plantago maritima L., at high salinity

Abstract. Plantago maritima L. was grown at three levels of salinity, 50, 200, 350 mol m⁻³ NaCl, and the effects on growth, ion content and photosynthetic capacity were studied. Shoot and root dry weight, leaf production and leaf length were all substantially reduced in plants grown at high salinity. Total leaf area of plants grown at 350 mol m⁻³ NaCl was only 20% of that in plants at low salinity. Both the Na⁺ and K⁺ content of leaves and roots increased with external salinity. There was no change in the Na⁺/K⁺ ratio of leaves or roots at different salinity levels. Despite the large reductions in growth and high accumulation of Na⁺ ions, leaf photosynthetic rate was only slightly reduced by salinity stress. The reduction in photosynthesis was not caused by reduced biochemical capacity as judged by photosynthetic response to intercellular CO₂ and by ribulose-1,5-bisphosphate carboxylase activity, but was due to reduced leaf conductance and low intercellular CO₂ concentration. The increased stomatal limitation of photosynthesis resulted in higher water-use efficiency of plants grown at high salinity.     

Salinity tolerance of Kosteletzkya virginica. I. Shoot growth, ion and water relations

Abstract. Kosteletzkya virginica (L.) Presl., a dicotyledonous halophyte native to brackish tidal marshes, was grown on nutrient solution containing 0. 85, 170 or 255 mol m^-3 NaCl, and the effects of external salinity on shoot growth and ion content of individual leaves were studied in successive harvests. Growth was stimulated by 85 mol m^-3 NaCl and was progressively reduced at the two higher salinities. Growth suppression at high salinity resulted principally from decreased leaf production and area, not from accelerated leaf death. As is characteristic of halophytic dicots. K. virginica accumulated inorganic ions in its leaves, particularly Na⁺ and K⁺. However, the Na⁺ concentration of individual leaves did not increase with time, but remained constant or even declined, seeming to be well-coordinated with changes in water content. A striking feature of the ion composition of salinized plants was the development of a dramatic gradient in sodium content, with Na⁺ partitioned away from the most actively growing leaves. Salt-treated plants exhibited a strong potassium affinity, with foliar K⁺ levels higher in salinized plants than unsalinized plants after an initial decrease. These results suggest that selective uptake and transport, foliar compartmentation of Na⁺ and K⁺ in opposite directions along the shoot axis, and the regulation of leaf salt loads over time to prevent build-up of toxic concentrations are whole-plant features which enable K. virginica to establish favourable K⁺-Na⁺ relations under saline conditions.