Pressure-adaptive differences in NAD-dependent dehydrogenases of congeneric marine fishes living at different depths

Summary The pressure sensitivities of the apparent Michaelis constant of coenzyme were compared at 5°C for three NAD-dependent dehydrogenases purified from the white muscle of two congeneric fishes living at different depths.Sebastolobus altivelis adults are common between 550 and 1,300 m;S. alascanus adults between 180 and 440 m. Two isozymes of cytoplasmic malate dehydrogenase (MDH, EC 1.1.1.37, NAD⁺:l-malate oxidoreductase) and glyceraldehyde 3-phosphate dehydrogenase (GAPDH, EC 1.2.1.12, NAD⁺:d-glyceraldehyde 3-phosphate oxidoreductase [phosphorylating]) were compared. For these enzymes, the homologues fromS. alascanus were markedly sensitive to moderate hydrostatic pressures (Fig. 1). TheK _m(NADH) ofS. alascanus MDH-1 and theK _m(NAD⁺) ofS. alascanus GAPDG double between 1 and 68 atm and continue to increase at a slower rate up to 476 atm, the highest pressure tested. For MDH-2 ofS. alascanus, theK _m(NADH) triples between 1 and 68 atm and increases at a slower rate to 340 atm; between 340 and 476 atm, theK _m decreases slightly from the value at 340 atm. TheK _m of coenzyme values are pressure-independent for the MDH-1 and GAPDH homologues ofS. altivelis up to 476 atm (Fig. 1). TheK _m(NADH) of theS. altivelis MDH-2 is sensitive to pressure, but much less so than the homologue ofS. alascanus (Fig. 1). TheK _m increases 63% between 1 and 68 atm and remains constant at this higher value at higher pressures up to 476 atm. The relative increases inK _m values for theS. alascanus enzymes between 1 and 68 atm are large (Table 1). Higher pressures are not as effective in perturbing theK _m of coenzyme values. Perturbation ofK _m of coenzyme by moderate hydrostatic pressures (50–100 atm) may seriously impair the function of dehydrogenases ofS. alascanus at pressures experienced by the deeper-living congener in its habitat. The reduction of the pressure-sensitivity of theK _m of coenzyme in NAD-dependent dehydrogenases may be an important and ubiquitous feature of adaptation to the deep sea.     

Differential effects of turgor on sucrose and potassium transport at the tonoplast and plasma membrane of sugar beet storage root tissue

When turgor was increased, by decreasing the concentration of mannitol bathing discs of sugar beet storage root tissue, the rates of sucrose and potassium uptake into the vacuole were decreased. At all external mannitol concentrations the rate of sucrose and potassium uptake across the plasma membrane was an order of magnitude greater than the rate of quasi-steady uptake into the vacuole, implying a very large efflux. Efflux of both sucrose and potassium was increased at high turgor. However, while increasing turgor decreased the rate of K⁺ uptake, the rate of sucrose uptake at the plasma membrane increased with time. Compartmental analysis of tracer exchange kinetics was used to determine unidirectional K⁺ fluxes. From these results, it was estimated that the increase in K⁺ efflux accompanying a 1.5 MPa increase in turgor could lead to a net increase of 140mol^?3h^?1 in the external potassium concentration. It is suggested that the turgor-imposed increase in solute efflux is a means of regulating intracellular osmotic pressure and/or turgor in sugar beet storage roots, but that sucrose is preferentially retrieved from the apoplast, even under conditions of excessively high turgor. However, much of this sucrose is probably lost from the cell, implying a ‘futile’ sucrose transport cycle at the plasma membrane. The turgor-stimulated leak of potassium could play a major role in the regulation of turgor pressure in sugar beet storage root tissue.     

Growth of Pediococcus soyae nov. sp. in Highly Concentrated Solutions of Inorganic Salts and Sugars

Pediococcus soyae nov. sp., which has an inherited salt tolerant nature, is grown in solutions of high osmotic pressure. When this strain is transferred from 0.5% salted medium to a new medium containing 18% sodium chloride, the viable counts of this organism firstly decrease from about one half to one-third of the inoculated cells, and then normal growth occurs. This indicates the occurrence of physiological adaptation at an early stage of growth.

The growth of this lactic acid bacterium is observed in concentrated solutions of various inorganic salts. The solutions containing Na⁺, K⁺, Cl^?, NO₃^? and SO₄^{– –} ions are not toxic for the organism, and the organism can grow in solutions of 133 atm. osmotic pressure, generally. However, Li⁺, Ca⁺⁺, Mg⁺⁺ and Br⁺ are, toxic for growth.

In concentrated sugar solutions, this organism also propagates well, and growth is observed in the media containing 50% glucose or 60% sucrose, osmotic pressure being 105 and 84 atm., respectively. Therefore, Pediococcus soyae nov. sp. is osmotolerant.     

Effects of abscisic acid on potassium uptake and starch content of stomatal guard cells

Summary Abscisic acid (ABA) at a concentration of 100 m reduced the mean stomatal aperture on isolated epidermis of Commelina communis from 9.5 to 3.1 m. This closure resulted from a fall in osmotic pressure of the guard cells from 14.1 to 9.8 bars; the osmotic pressure of the subsidiary cells did not change significantly. Histochemical tests showed that the potassium concentration in guard cells was reduced by ABA-treatment, while the starch content of the chloroplasts increased. ABA was found to exert a significant effect on Rb⁸⁶ uptake into leaf discs, but this was relatively small in magnitude. It is concluded that ABA has a greater effect on ion uptake into guard cells than into the leaf tissues as a whole.Recent hypotheses of the stomatal mechanism are discussed in relation to these new observations, and the rejection by some writers of any major role for starch hydrolysis is challenged. Evidence from several sources suggests that starch disappearance occurs simultaneously with K⁺ entry into guard cells. Breakdown of starch may lead to formation of organic anions, with which K⁺ uptake may be associated. In this case starch breakdown would contribute as much to the increased osmotic pressure as does K⁺ uptake.     

Water and ion regulation in cicadas in relation to xylem feeding

Cicadas feed on xylem fluid. This is hypotonic to the haemolymph and contains high concentrations of potassium, sodium, calcium, magnesium, chloride, and phosphate ions. The urine contains the same ions in the same proportions but in slightly lower concentrations. Amino acids and sucrose are present in xylem fluid and traces of amino acids are also found in urine.Water is rapidly shunted from foregut to hindgut via the filter chamber. Injection of xylem fluid into the oesophagus results in an immediate tenfold increase in flow rate in the ileum. The osmotic pressure of xylem fluid in the filter chamber rapidly rises whilst the osmotic pressure in the anterior part of the ileum rapidly falls.Absorption of nutrients and ions into the haemolymph probably occurs in the conical segment and anterior tubular midgut. Storage excretion of divalent ions occurs in the mid-midgut and ions may be transported from the haemolymph into the posterior tubular midgut.The Malpighian tubules secrete a fluid slightly hypertonic to blood containing K⁺ (42 mM/l.] and Na⁺ (14 mM/l.).The osmotic pressures within the internal Malpighian tubules and internal midgut in the filter chamber are considerably higher than the osmotic pressure of the xylem fluid when it first enters the filter chamber proper. Passive osmosis will occur and water will be shunted into the ileum.Reabsorption of K⁺ and Na⁺ occurs in the ileum.     

Phosphate cycles in energy crop systems with emphasis on the availability of different phosphate fractions in the soil

The growing cells of hydroponic maize roots expand at constant turgor pressure (0.48 MPa) both when grown in low-(0.5 mol m^-3 CaCl₂) or full-nutrient (Hoagland's) solution and also when seedlings are stressed osmotically (0.96 MPa mannitol). Cell osmotic pressure decreases by 0.1–0.2 MPa during expansion. Despite this, total solute influx largely matches the continuously-varying volume expansion-rate of each cell. K⁺ in the non-osmotically stressed roots is a significant exception-its concentration dropping by 50% regardless of the presence or absence of K⁺ in the nutrient medium. This corresponds to the drop in osmotic pressure. Nitrate appears to replace Cl^- in the Hoagland-grown cells.Analogous insensitivity of solute gradients to external solutes is observed in the radial distribution of water and solutes in the cortex 12 mm from the tip. Uniform turgor and osmotic pressures are accompanied by opposite gradients of K⁺ and Cl^-, outwards, and hexoses and amino acids, inwards, for plants grown in either 0.5 mol m^-3 CaCl₂ or Hoagland's solution (with negligible Cl^-). K⁺ and Cl^- levels within both gradients were slightly higher when the ions were available in the medium. The gradients themselves are independent of the direction of solute supply. In CaCl₂ solution all other nutrients must come from the stele, in Hoagland's solution inorganic solutes are available in the medium.24 h after osmotic stress, turgor pressure is recovered at all points in each gradient by osmotic adjustment using organic solutes. Remarkably, K⁺ and Cl^- levels hardly change, despite their ready availability. Hexoses are responsible for some 50% of the adjustment with mannitol for a further 30%. Some 20% of the final osmotic pressure remains to be accounted for. Proline and sucrose are not significantly involved. Under all conditions a standing water potential step of 0.2 MPa between the rhizodermis and its hydroponic medium was found. We suggest that this is due to solute leakage.Abbreviations EDX energy dispersive X-ray microanalysis - water potential - 11-1 cell osmotic pressure - P turgor pressure     

Membrane Functions and Tolerance to Aromatic Hydrocarbon Fungitoxicants in Conidia of Fusarium solani

With the use of ³²P-labeled phosphate and ⁴²K₂CO₃ the effect of diphenyl on permeability and uptake properties of the cytoplasmic membrane in wild type and diphenyl-tolerant mutant conidia of Fusarium solani f. cucurbitae was studied. No general damage to the membrane with unspecific leakage of cell constituents was demonstrated under conditions in which diphenyl prevents germination of wild type conidia. The fresh conidia do not require exogenous supply of energy for the uptake of phosphate or of potassium. In the wild type the entry of ³²P is inhibited but that of ⁴²K strikingly stimulated by diphenyl. Independently of the tolerant mutant gene present, the mutant conidia are significantly less sensitive to the phosphate uptake inhibition and not affected at all by diphenyl with respect to the uptake of potassium. The latter difference from the wild type seems to indicate genetic control of some property of the potassium transport system in this fungus.     

Interaction of dichlone with human erythrocytes. I. Changes in cell permeability

The uptake of the fungicide dichlone (2,3-dichloro-1,4-naphthoquinone) by human erythrocytes was extremely rapid, reaching a maximum within 5 min of treatment. Most of the dichlone taken up was present in the interior of the cell; only a small fraction of the pesticide (less than 5%) was bound to the cell membrane. Dichlone (3 · 10^?5M-10^?4M) induced a rapid loss of intracellular potassium from the erythrocytes; the leakage of K⁺ varied with the fungicide concentration as well as with cell concentration. Pretreatment of the cells with glutathione was able to reduce potassium loss. Cells exposed to dichlone showed increased osmotic fragility. Dichlone also inhibited Na⁺-K⁺ ATPase, which is associated with active ion transport. However, the leakage of potassium in dichlone-treated cells does not appear to be related to the interference with active ion transport. An extensive loss of potassium within a relatively short time after treatment suggests that dichlone produces its effect by increasing passive cation permeability, probably as a result of direct action on the membrane structure. Dichlone was able to induce hemolysis, but only at concentrations higher than those which resulted in K⁺ loss. The loss of hemoglobin appeared to be mainly due to osmotic swelling of the treated cells. Exposure of red cells to dichlone also resulted in a rapid and extensive formation of methemoglobin as well as a denaturation of hemoglobin. Thus, dichlone not only may be capable of lowering the capacity of erythrocytes to transport oxygen but also alters their permeability.     

Computer simulations of neuron-glia interactions mediated by ion flux

Extracellular potassium concentration, [K⁺]_o, and intracellular calcium, [Ca²⁺]_i, rise during neuron excitation, seizures and spreading depression. Astrocytes probably restrain the rise of K⁺ in a way that is only partly understood. To examine the effect of glial K⁺ uptake, we used a model neuron equipped with Na⁺, K⁺, Ca²⁺ and Cl⁻ conductances, ion pumps and ion exchangers, surrounded by interstitial space and glia. The glial membrane was either “passive”, incorporating only leak channels and an ion exchange pump, or it had rectifying K⁺ channels. We computed ion fluxes, concentration changes and osmotic volume changes. Increase of [K⁺]_o stimulated the glial uptake by the glial 3Na/2K ion pump. The [K⁺]_o flux through glial leak and rectifier channels was outward as long as the driving potential was outwardly directed, but it turned inward when rising [K⁺]_o/[K⁺]_i ratio reversed the driving potential. Adjustments of glial membrane parameters influenced the neuronal firing patterns, the length of paroxysmal afterdischarge and the ignition point of spreading depression. We conclude that voltage gated K⁺ currents can boost the effectiveness of the glial “potassium buffer” and that this buffer function is important even at moderate or low levels of excitation, but especially so in pathological states.     

Bacteriology of Manganese Nodules: V. Effect of Hydrostatic Pressure on Bacterial Oxidation of MnII and Reduction of MnO2

It was experimentally demonstrated that two strains of Arthrobacter 37, one growing at 25 C and the other at 5 C, could catalyze Mn^II oxidation at hydrostatic pressures well in excess of the pressure encountered by the parent culture in its original habitat in the ocean (80 atm). The strain grown at 5 C showed an increase in temperature optimum for manganese oxidation with increase in pressure. It was like-wise experimentally shown that induced Bacillus 29 without added ferricyanide and uninduced Bacillus 29 with added ferricyanide could catalyze MnO₂ reduction at hydrostatic pressures in excess of the pressure encountered by this organism in its original habitat (187 atm). The uninduced Bacillus 29, in the presence of ferricyanide, was active over a wider range of pressures (1 to 1,000 atm) than the induced Bacillus 29 in the absence of ferricyanide (1 to 467 atm). At corresponding pressures, the uninduced culture was also considerably more active than the induced culture. Special techniques were developed for measuring Mn^II-oxidizing and MnO₂-reducing activity under pressure.     

The effect of abscisic acid on the uptake of potassium and chloride into Avena coleoptile sections

Summary The effect of abscisic acid (ABA) on uptake of potassium (⁸⁶Bb⁺ or ⁴²K⁺) by Avena sativa L. coleoptile sections was investigated. ABA lowered the potassium uptake rate within 30 min after its application and inhibition reached a maximum (ca. 75%) after 2 h. The inhibition of K⁺ uptake increased with ABA concentration over a range of 0.03 to 10 g/ml ABA. At a higher K⁺ concentration (20 mM) the percentage inhibition decreased. The percentage inhibition of K⁺ uptake by ABA remained constant with external K⁺ varied from 0.04 to 1.0 mM. After a loading period in 20 mM K⁺ (⁸⁶Rb⁺), apparent efflux of potassium was only slightly increased by ABA. Experiments in which growth was greatly reduced by mannitol or by omission of indole-3-acetic acid from the medium indicated there was no simple quantitative correspondence between ABA inhibition of coleoptile elongation and ABA inhibition of K⁺ uptake. Chloride uptake was also inhibited by ABA but to a smaller degree than was K⁺ uptake. No specificity for counterions was observed for K⁺ uptake. Uptake of 3,0-methylglucose and proline were inhibited by ABA to a much smaller extent (14 and 11%) than that of K⁺, a result which suggests that ABA acts on specific ion uptake mechanisms.     

Solid-State H NMR Shows Equivalence of Dehydration and Osmotic Pressures in Lipid Membrane Deformation

Lipid bilayers represent a fascinating class of biomaterials whose properties are altered by changes in pressure or temperature. Functions of cellular membranes can be affected by nonspecific lipid-protein interactions that depend on bilayer material properties. Here we address the changes in lipid bilayer structure induced by external pressure. Solid-state ²H NMR spectroscopy of phospholipid bilayers under osmotic stress allows structural fluctuations and deformation of membranes to be investigated. We highlight the results from NMR experiments utilizing pressure-based force techniques that control membrane structure and tension. Our ²H NMR results using both dehydration pressure (low water activity) and osmotic pressure (poly(ethylene glycol) as osmolyte) show that the segmental order parameters (S_CD) of DMPC approach very large values of ≈0.35 in the liquid-crystalline state. The two stresses are thermodynamically equivalent, because the change in chemical potential when transferring water from the interlamellar space to the bulk water phase corresponds to the induced pressure. This theoretical equivalence is experimentally revealed by considering the solid-state ²H NMR spectrometer as a virtual osmometer. Moreover, we extend this approach to include the correspondence between osmotic pressure and hydrostatic pressure. Our results establish the magnitude of the pressures that lead to significant bilayer deformation including changes in area per lipid and volumetric bilayer thickness. We find that appreciable bilayer structural changes occur with osmotic pressures in the range of 10−100 atm or lower. This research demonstrates the applicability of solid-state ²H NMR spectroscopy together with bilayer stress techniques for investigating the mechanism of pressure sensitivity of membrane proteins.     

Growth of Corynebacterium glutamicum in glucose-limited continuous cultures under high osmotic pressure. Influence of growth rate on the intracellular accumulation of proline,glutamate and trehalose

In order to determine the response of Corynebacterium glutamicum to osmotic stress under different growth conditions, the bacteria were grown in glucose-limited continuous cultures at osmotic pressures of 0.4–2.4 osmol kg^–1 by addition of NaCl to the culture medium. Steady-state continuous cultures were obtained for all investigated osmotic pressures. Increasing the medium osmolality resulted in a higher specific glucose-uptake rate, a lower glucose-to-biomass conversion yield, as well as important changes in the cellular content. A short-term response to the addition of NaCl to a continuous culture was the rapid but transient uptake of Na⁺ ions. At steady state a higher osmotic pressure resulted in a strong increase of the intracellular concentrations of proline, from 5 mg/g to 125 mg/g dry weight, and of trehalose from 20 mg/g to 60 mg/g dry weight. The level of glutamate, which was the dominant intracellular amino acid at low osmotic pressure at 55 mg/g dry weight, was not affected by the addition of NaCl. The influence of the specific growth rate, between 0.1 h^–1 and 0.4 h^–1, on the intracellular metabolite concentration was also determined. The level of proline was found to increase strongly with the growth rate, whereas the trehalose content decreased slightly and the glutamate content did not change. The observed net increase in accumulated metabolites may be related to a requirement of a higher turgor pressure for rapid cell growth.     

Determination of the hydraulic conductivity and of reflection coefficients in Nitella flexilis by means of direct cell-turgor pressure measurements

From direct and continuous measurements of the internal hydrostatic pressure (P) in the internodes of Nitella flexilis, the reflection coefficients (σ_s) of some non-electrolytes were determined, using a zero-flow method, and were compared with those found previously on Valonia utricularis and with those obtained by Dainty and Ginzburg on other Characean internodes from transcellular osmosis experiments. The hydraulic conductivities (Lp) of the cell membranes were determined by two independent methods, that is, using hydrostatically or osmotically induced flows. From the exponential time course of P in such experiments and from the volumetric elastic modulus (ε) of the cell wall, Lp was calculated. The effect of unstirred layers in the methods described was negligibly small.In osmotic experiments with different non-plasmolysing external sucrose concentrations (20–200 mM) the exosmotic hydraulic conductivity (Lp_ex) decreases markedly with increasing concentration, while the endosmotic hydraulic conductivity (Lp_en) shows only a weak dependence. In the hydrostatic experiments the hydraulic conductivities for single cells were constant in the pressure range for P from 2 to 7 atm. In this pressure range Lp_en and Lp_ex varied for different cells from 2.2·10^?5 to 2.8·10^?5 and from 1.8·10^?5 to 2.5·10^?5 cm·s^?1·atm^?1, respectively, with an average ratio Lp_en to Lp_ex of 1.1, which indicates a polarity in water movement.These values were the same as those obtained in the osmotic experiments from extrapolation to zero sucrose concentration. At internal pressures below 2 atm the Lp-values markedly increase on approaching the plasmolytic point.The results are discussed in terms of a dehydration of the membranes (or the cytoplasm) at increased solute concentrations. In addition, the strong dependence of Lp at low internal hydrostatic pressures points to a direct influence of P on the water permeability of the membranes.     

A Study of the Effects of Hydrostatic Pressure on Macromolecular Synthesis in Escherichia coli

In cultures of Escherichia coli 15 (thymine^-, leucine^-) which were incubated at high hydrostatic pressures, cell division occurred only at pressures below 430 atm but in a somewhat synchronous fashion at around 250 atm. The rate of leucine-¹⁴C incorporation into a macromolecular fraction of the cells diminished to a zero value at about 580 atm and that of uracil-¹⁴C incorporation to a zero value at about 770 atm. The rate of thymine-¹⁴C incorporation at pressures around 330 atm was that to be expected with a culture in which DNA synthesis is somewhat synchronous. At pressures above 500 atm, thymine-¹⁴C was incorporated only over the initial part of the pressure incubation and further incorporation under pressure was not observed no matter how long the duration of the incubation. We present evidence along several lines that the thymine incorporation kinetics reflect an effect of pressure on a locus at the origin (or termination) of a replication of the bacterial chromosome. The recovery of cell division and of the incorporation rates upon release of pressure were found to depend on the magnitude of the pressure and the duration of the pressure incubation.     

Effect of osmotic pressure,Na+/K+ ratio and medium concentration on the enzyme activity and growth of L cells in suspension culture

Summary The effect of changes in osmotic pressure and in the Na⁺/K⁺ ratio on the doubling time, maximum cell population, enzyme activity, and isoenzyme distribution pattern in suspension cultures of L cells was determined. The growth of viable cells is relatively flat over a rather wide range of osmotic pressures (220 to 440 mOsm per kg). The presence of extra salt or sucrose beyond that needed to reach the minimum osmotic pressure (220) is detrimental to cell growth as reflected by a delay in the onset of logarithmic growth, a slower growth rate, a decreased maximum population, and accelerated death phase. Excessive K⁺ ion is toxic, but the level at which it is toxic interacts with osmotic pressure of the medium. Enzyme activity and isoenzyme distribution patterns for those enzymes studied did not vary as a function of osmotic pressure, ionic ratios, or medium concentration.     

Specific Effects of Kinetin on the Uptake of Monovalent Cations by Sunflower Cotyledons

Kinetin promoted the uptake of K⁺ and Rb⁺ into detached sunflower cotyledons. This action was concomitant with an acceleration of growth. A slighter promotion of Li⁺ uptake was also noted, but there was no consistent influence on that of Na⁺. A small inhibitory effect on NH₄⁺₄ uptake was apparent when the latter was computed per average weight of sample during the course of incubation. Light also promoted the growth of the cotyledons, but depressed their capacity to absorb potassium. The action of kinetin on cotyledons removed from 5–7 day old seedlings was weaker than on those removed from 2–4 day old seedlings with regard to growth but stronger with regards to K⁺ uptake. When K⁺ uptake by cotyledons taken from 7-day old seedlings was followed with time the kinetin effect was already detectable within a few hours, but it became more pronounced after 10 hours' incubation. Kinetin did not accelerate growth or K⁺ uptake in hypo-cotyl segments. IAA, which was previously shown to promote these processes in hypocotyl segments, inhibited them in cotyledons. A working hypothesis is suggested according to which endogenous auxins and cytokinins regulate the absorption of K⁺ in shoot cells of the intact plant in a manner similar to that in which they act in excised tissues and in this way affect the distribution and redistribution of K⁺ in the shoot; and that they are among the factors which determine the selectivity of ion uptake in the intact plant.     

Ion movements induced by transcellular osmosis inNitella flexilis

Summary Movements of K⁺, Na⁺, and Cl^}- ions during transcellular osmosis were studied in internodal cells ofNitella flexilis. Much K⁺ was released from the endosmotic cell part, but only a little from the exosmotic cell part. The amount of K⁺ released depended on the osmotic gradient driving transcellular osmosis. Movement of Na⁺ was hardly detected. Cl^}- was released in nearly the same amounts as K⁺. Release of K⁺ from the endosmotic cell half was stimulated remarkably by lowering the temperature from 20 to 1 °C, and also by lowering the internal osmotic pressure but inhibited by raising it.The dependence of K⁺ release on osmotic gradient, internal osmotic pressure and temperature can be explained by their effects on membrane depolarization and membrane resistance (Hayama et al. 1978). We concluded thatP _K remained unchanged, whileP _Cl increased a great deal in the endosmotic cell part.     

Carrier-mediated Potassium Efflux Across the Cell Membrane of Red Beet

The flux ratio (influx/efflux) of K⁺ across the plasmalemma of beet cells at an external potassium concentration of 0.6 mm does not respond to changes of membrane potential in the manner expected for the free diffusion of ions. The K⁺ efflux is affected by the presence of adsorbed Ca²⁺, but is apparently unrelated to the electrical potential or to the net uptake of potassium. The K⁺ efflux is greater than the efflux of the sulfate and organic anions which are accumulated with potassium, and is partially dependent on the presence of external potassium. Thus the loss of ⁴²K from the cell does not appear to be a leakage of freely diffusing K⁺ ions, nor a leakage of ion pairs, but a carrier-mediated transport or exchange of potassium across the cell membrane.     

Apoplastic transport across young maize roots: effect of the exodermis

The uptake of water and of the fluorescent apoplastic dye PTS (trisodium 3-hydroxy-5,8,10-pyrenetrisulfonate) by root systems of young maize (Zea mays L.) seedlings (age: 11–21 d) has been studied with plants which either developed an exodermis (Casparian band in the hypodermis) or were lacking it. Steady-state techniques were used to measure water uptake across excised roots. Either hydrostatic or osmotic pressure gradients were applied to induce water flows. Roots without an exodermis were obtained from plants grown in hydroponic culture. Roots which developed an exodermis were obtained using an aeroponic (=mist) cultivation method. When the osmotic concentration of the medium was varied, the hydraulic conductivity of the root (Lp _r in m³ · m⁻² · MPa⁻¹ · s⁻¹) depended on the osmotic pressure gradient applied between root xylem and medium. Increasing the gradient (i.e. decreasing the osmotic concentration of the medium; range: zero to 40 mM of mannitol), increased the osmotic Lp _r. In the presence of hydrostatic pressure gradients applied by a pressure chamber, root Lp _r was constant over the entire range of pressures (0–0.4 MPa). The presence of an exodermis reduced root Lp _r in hydrostatic experiments by a factor of 3.6. When the osmotic pressure of the medium was low (i.e. in the presence of a strong osmotic gradient between xylem sap and medium), the presence of an exodermis caused the same reduction of root Lp _r in osmotic experiments as in hydrostatic ones. However, when the osmotic concentration of the medium was increased (i.e. the presence of low gradients of osmotic pressure), no marked effect of growth conditions on osmotic root Lp _r was found. Under these conditions, the absolute value of osmotic root Lp _r was lower by factors of 22 (hydroponic culture) and 9.7 (aeroponic culture) than in the corresponding experiments at low osmotic concentration. Apoplastic flow of PTS was low. In hydrostatic experiments, xylem exudate contained only 0.3% of the PTS concentration of the bathing medium. In the presence of osmotic pressure gradients, the apoplastic flow of PTS was further reduced by one order of magnitude. In both types of experiments, the development of an exodermis did not affect PTS flow. In osmotic experiments, the effect of the absolute value of the driving force cannot be explained in terms of a simple dilution effect (Fiscus model). The results indicate that the radial apoplastic flows of water and PTS across the root were affected differently by apoplastic barriers (Casparian bands) in the exodermis. It is concluded that, unlike water, the apoplastic flow of PTS is rate-limited at the endodermis rather than at the exodermis. The use of PTS as a tracer for apoplastic water should be abandoned. Received: 9 October 1997 / Accepted: 5 February 1998