Is the osmotically inactive sodium storage pool fixed or variable?

Recently, there is renewed interest in the role of osmotically inactive Na(+) storage during Na(+) retention. Although it is well accepted that a portion of the total exchangeable Na(+) reservoir is osmotically inactive, there is current controversy as to whether the osmotically inactive Na(+) storage pool is fixed or variable during Na(+) retention. In this article, we analyze the current scientific evidence to assess whether the osmotically inactive Na(+) storage pool can be dynamically regulated. Our analysis supports the assertion that the osmotically inactive Na(+) storage pool is fixed rather than variable.     

Effects of salinity on growth and cation accumulation of Sporobolus virginicus (Poaceae)

Optimal growth of euhalophytes requires moderate concentrations of salt and, in dicotyledons, is associated with succulence and accumulation of Na(+) in plant tissues. However, reports of salt-stimulated growth in monocotyledons are rare. Relative growth rate (RGR), biomass accumulation, and water content were studied in Sporobolus virginicus (Poaceae), a C(4) chloridoid grass, grown hydroponically with different concentrations of NaCl. Cation concentrations were determined by atomic absorption spectrophotometry. Optimal growth occurred at 100-150 mmol/L NaCl and was not dependent on nitrogen levels or accompanied by accumulation of Na(+) in leaves. Biomass accumulation and RGR in plants grown at 450 mmol/L NaCl were greater than in plants grown at 5 mmol/L. The Na?:?K ratios were lower in leaves than in roots, indicating discrimination in Na(+) and K(+) transport. Secretion of Na(+) increased from 166.5 to 336.7 mmol · g(-1) dry biomass · d(-1) as the NaCl concentration of the nutrient solution increased from 125 mmol/L to 450 mmol/L. Water concentrations of leaves and shoots were significantly greater in plants grown at optimal levels of salinity than in plants grown at lower or higher salinities. These results demonstrate salt-stimulated growth in a monocotyledon.     

Functional expression of Sinorhizobium meliloti BetS, a high-affinity betaine transporter, in Bradyrhizobium japonicum USDA110

Among the Rhizobiaceae, Bradyrhizobium japonicum strain USDA110 appears to be extremely salt sensitive, and the presence of glycine betaine cannot restore its growth in medium with an increased osmolarity (E. Boncompagni, M. Osteras, M. C. Poggi, and D. Le Rudulier, Appl. Environ. Microbiol. 65:2072-2077, 1999). In order to improve the salt tolerance of B. japonicum, cells were transformed with the betS gene of Sinorhizobium meliloti. This gene encodes a major glycine betaine/proline betaine transporter from the betaine choline carnitine transporter family and is required for early osmotic adjustment. Whereas betaine transport was absent in the USDA110 strain, such transformation induced glycine betaine and proline betaine uptake in an osmotically dependent manner. Salt-treated transformed cells accumulated large amounts of glycine betaine, which was not catabolized. However, the accumulation was reversed through rapid efflux during osmotic downshock. An increased tolerance of transformant cells to a moderate NaCl concentration (80 mM) was also observed in the presence of glycine betaine or proline betaine, whereas the growth of the wild-type strain was totally abolished at 80 mM NaCl. Surprisingly, the deleterious effect due to a higher salt concentration (100 mM) could not be overcome by glycine betaine, despite a significant accumulation of this compound. Cell viability was not significantly affected in the presence of 100 mM NaCl, whereas 75% cell death occurred at 150 mM NaCl. The absence of a potential gene encoding Na(+)/H(+) antiporters in B. japonicum could explain its very high Na(+) sensitivity.     

Potassium nitrate application alleviates sodium chloride stress in winter wheat cultivars differing in salt tolerance

A sand culture experiment was conducted to answer the question whether or not exogenous KNO(3) can alleviate adverse effects of salt stress in winter wheat by monitoring plant growth, K(+)/Na(+) accumulation and the activity of some antioxidant enzymes. Seeds of two wheat cultivars (CVs), DK961 (salt-tolerant) and JN17 (salt-sensitive), were planted in sandboxes and controls germinated and raised with Hoagland nutrient solution (6 mM KNO(3), no NaCl). Experimental seeds were exposed to seven modified Hoagland solutions containing increased levels of KNO(3) (11, 16, 21 mM) or 100 mM NaCl in combination with the four KNO(3) concentrations (6, 11, 16 and 21 mM). Plants were harvested 30 d after imbibition, with controls approximately 22 cm in height. Both CVs showed significant reduction in plant height, root length and dry weight of shoots and roots under KNO(3) or NaCl stress. However, the combination of increased KNO(3) and NaCl alleviated symptoms of the individual salt stresses by improving growth of shoots and roots, reducing electrolyte leakage, malondialdehyde and soluble sugar contents and enhancing the activities of antioxidant enzymes. The salt-tolerant cultivar accumulated more K(+) in both shoots and roots compared with the higher Na(+) accumulation typical for the salt-sensitive cultivar. Soluble sugar content and activities of antioxidant enzymes were found to be more stable in the salt-tolerant cultivar. Our findings suggest that the optimal K(+)/Na(+) ratio of the nutrient solution should be 16:100 for both the salt-tolerant and the salt-sensitive cultivar under the experimental conditions used, and that the alleviation of NaCl stress symptoms through simultaneously applied elevated KNO(3) was more effective in the salt-tolerant than in the salt-sensitive cultivar.     

Are large amounts of sodium stored in an osmotically inactive form during sodium retention? Balance studies in freely moving dogs

Alterations in total body sodium (TBSodium) that covered the range from moderate deficit to large surplus were induced by 10 experimental protocols in 66 dogs to study whether large amounts of Na+ are stored in an osmotically inactive form during Na+ retention. Changes in TBSodium, total body potassium (TBPotassium), and total body water (TBWater) were determined by 4-day balance studies. A rather close correlation was found between individual changes in TBSodium and those in TBWater (r2 = 0.83). Changes in TBSodium were often accompanied by changes in TBPotassium. Taking changes of both TBSodium and TBPotassium into account, the correlation with TBWater changes became very close (r2 = 0.93). The sum of changes in TBSodium and TBPotassium was accompanied by osmotically adequate TBWater changes, and plasma osmolality remained unchanged. Calculations reveal that even moderate TBSodium changes often included substantial Na+/K+ exchanges between extracellular and cellular space. The results support the theory that osmocontrol effectively adjusts TBWater to the body's present content of the major cations, Na+ and K+, and do not support the notion that, during Na+ retention, large portions of Na+ are stored in an osmotically inactive form. Furthermore, the finding that TBSodium changes are often accompanied by TBPotassium changes and also include Na+/K+ redistributions between fluid compartments suggests that cells may serve as readily available Na+ store. This Na+ storage, however, is osmotically active, since osmotical equilibration is achieved by opposite redistribution of K+.     

An anomaly in potassium accumulation by barley roots: I. Effect of anions, sodium concentration, and length of absorption period

Excised barley roots accumulated 40 to 50% more K(+) from 0.04 mm than from 0.06 mm KCl when incubated for 24 hours in KCl solutions containing 0.2 mm CaSO(4). This phenomenon was not markedly influenced by the rate of absorption of the counteranion. The presence of Na(+) in the treatment solutions decreased total K accumulation but did not alter the K(+) concentration at which the accumulation peak occurred. Short interval studies indicated that this phenomenon is easily observable after 4 hours and begins to become apparent within 2 hours. In comparison with barley, accumulation of K(+) by excised wheat roots decreased as KCl concentration was increased from 0.02 to 0.06 mm; but K(+) accumulation curve for corn roots showed no peaks or depressions in the concentration range of 0.01 to 0.1 mm. A normal hyperbolic curve was noted for the accumulation of Na(+) from 0.01 to 1 mm NaCl by barley roots.     

Leaf gas exchange and solute accumulation in the halophyte Salvadora persica grown at moderate salinity

The domestication of halophytes has been proposed as a strategy to expand cultivation onto unfavorable land. However, halophytes mainly have been considered for their performance in extremely saline environments, and only a few species have been characterized in terms of their tolerance and physiological responses to moderately high levels of salinity. Salvadora persica is an evergreen perennial halophyte capable of growing under extreme conditions, from very dry environments to highly saline soils. It possesses high potential economic value as a source of oil and medicinal compounds. To quantify its response to salinity, S. persica seedlings were exposed to 200 mM NaCl for 3 weeks, and growth, leaf gas exchange and solute accumulation were measured. The presence of NaCl induced a 100% increase in fresh weight and a 30% increase in dry weight, relative to non-salinized controls. Increases in fresh weight and dry weight were not associated with higher rates of net CO(2) assimilation, however. Analysis of ion accumulation revealed that S. persica leaves accumulated Na(+) as a primary osmoticum. The concentration of Na(+) in leaves of salinized plants was approximately 40-fold greater than that measured in non-salinized controls, and this was associated with significant reductions in leaf K(+) and Ca(2+) concentrations. In addition, a significant accumulation of proline, probably associated with osmotic adjustment and protection of membrane stability, occurred in roots of salinized plants.     

Intracellular responses of productive hybridomas subjected to high osmotic pressure

It has previously been found tht hybridoma cells undr hyuerosmotic stress produce higher amounts of antibody. This study indentified the cellular processes and mechanisms that occur during this event. In studies fo hybridomas adpated toosmolarities ranging between 300 and 450 mOsm (uusing NaCl), antibody production increased to a saturation level while cell growth decreased progressively. At 500 mOsm, lower, cell numbers and markedly decreaased productivity resulted. Sucrose and KCl were found to induce similar trends, except to different extents.Several important change in cellulaes in cellular responses were onsserved. Elevation of osmnolarity with NaCl from 300 to 350 mOsm causes an increase of zwiterionic amino acid upatake, which, occurredvia Na(+)-dependent transport systems. In particuar, systedm A was enhanced by 1.86-fold, but noenhancement was observed for Na(+)-independent transport systems, In addition, amino acids reactive with Na(+)-dependent transport systems were onserved to be abundant within osmotically stressed hybridomas in the middle and dlate exponentoial statges. Sucroses ans Kcl caused similar uptake effects, but to a laeeser degree, as long as sodium ions were present in solution.Specific consumption rates fo glucose and glutamine incresase by 19% and 20%, respectively, under high osmolarity treatment. Thewse increases were confirmed by the 5% to 10% increase in cellular metabolic acitivity. At 350 mOsm, growth rate was slower, compared with the 300-mOsm culture, which was reflected by thelower DNA conetr4ation. Stressed cultures contained enhanced leyls of tatal RNA content could in turn increase the translation rates of proteins. This was reflected in the accumulation of both dry cell weight and total cellular protein at linear rates of 0.42 muG/10(6) cells/mOsm and 0.21 mug/10(6) cells/mOmsm, respectively, with increasing osmolarty between 300 and 450 mOsm.Overall, hybridoms increased their metabolic activities and amino acids uptake via the Na(+)-dependent symports to compensate for teh osmotically elevated external environment. These effects contribute directly and indirectly tothe increased cell mass consisting of a larger pool of amono acids, RNA, cellular proteins, and seecreted antibody produt. (c) 1995 John Wiley & Sons, Inc.     

Na+- and K+-dependent oligomeric interconversion among alphabeta-protomers, diprotomers and higher oligomers in solubilized Na+/K+-ATPase

Protein fractions of a higher-oligomer (H), (alphabeta)(2)-diprotomer (D) and alphabeta-protomer (P) were separated from dog kidney Na(+)/K(+)-ATPase solubilized in the presence of NaCl and KCl. Na(+)/K(+)-dependent interconversion of the oligomers was analysed using HPLC at 0 degrees C. With increasing KCl concentrations, the content or amount of D increased from 27.6 to 54.3% of total protein, i.e. DeltaC(max) = 26.7%. DeltaC(max) for the sum of D and H was equivalent to the absolute value of DeltaC(max) for P, regardless of the anion present, indicating that K(+) induced the conversion of P into D and/or H, and Na(+) had the opposite effect. When enzymes that had been denatured to varying degrees by aging were solubilized, DeltaC(max) increased linearly with the remaining ATPase activity. The magnitude of the interconversion could be explained based on an equilibrium of D <==> 2P, assuming 50-fold difference in the K(d) between KCl and NaCl, and coexistence of unconvertible oligomers, which comprised as much as 39% of the eluted protein. Oligomeric interconversion, determined as a function of the KCl or NaCl concentration, showed K(0.5)s of 64.8 microM and 6.50 mM for KCl and NaCl, respectively, implying that oligomeric interconversion was coupled with Na(+)/K(+)-binding to their active transport sites.     

Effect of hyperosmolarity on recombinant protein productivity in baculovirus expression system

A lot of strategies were applied to improve recombinant protein productivity in the baculovirus expression system. In this study we propose for foreign protein production fed-batch cultivation method at hyperosmotic environment induced by increased NaCl content. Obtained results suggested relatively high tolerance and adaptation abilities of Tn-5 insect cells exposed to hyperosmotic stress. The cells under hyperosmotic conditions increased the specific rate of glucose consumption and lactate production. The release of additional energy and precursors as a result of increased metabolism by osmotically stressed culture was involved in recombinant protein synthesis. Recombinant nucleoprotein productivity in nutritional feeding cultures exposed to hyperosmolarity was about 72% higher than that obtained in batch culture at physiological osmolarity, but 31% was a result of feeding and the rest 41% was a result of hyperosmolarity and increasing Na(+) concentration.     

Permeability Properties of Rickettsia mooseri

The passive permeability properties of Rickettsia mooseri to both inorganic and organic solutes have been examined. Visual observations by phase-contrast microscopy of rickettsiae in macerated yolk sacs taken directly from heavily infected eggs revealed plasmolysis with hypertonic NaCl and KCl as well as with sucrose solutions. In contrast, similar visual studies of rickettsiae which had been subjected to freezing or to a purification process, or both, were plasmolyzed by hypertonic sucrose but not by hypertonic NaCl and KCl. These primary observations were extended to a variety of solutes and were placed on a quantitative basis by use of optical density and radioisotope dilution methods. Intracellular Na(+) and K(+) concentrations in processed rickettsiae, measured by flame photometry, closely paralleled the concentration of these ions in the suspending medium. It was concluded that R. mooseri appears to possess an osmotically active, functional, and structural membrane distinct from the cell wall, located at the surface of a structure analogous to the bacterial protoplast. In the intact organism, this membrane is passively impermeable to sucrose, NaCl, and KCl. However, altered permeability properties, especially to inorganic electrolytes, may be expected in rickettsiae which have been stored in the frozen state and subjected to a lengthy purification process.     

Low-affinity Na+ uptake in the halophyte Suaeda maritima

Na(+) uptake by plant roots has largely been explored using species that accumulate little Na(+) into their shoots. By way of contrast, the halophyte Suaeda maritima accumulates, without injury, concentrations of the order of 400 mM NaCl in its leaves. Here we report that cAMP and Ca(2+) (blockers of nonselective cation channels) and Li(+) (a competitive inhibitor of Na(+) uptake) did not have any significant effect on the uptake of Na(+) by the halophyte S. maritima when plants were in 25 or 150 mM NaCl (150 mM NaCl is near optimal for growth). However, the inhibitors of K(+) channels, TEA(+) (10 mM), Cs(+) (3 mM), and Ba(2+) (5 mM), significantly reduced the net uptake of Na(+) from 150 mM NaCl over 48 h, by 54%, 24%, and 29%, respectively. TEA(+) (10 mM), Cs(+) (3 mM), and Ba(2+) (1 mm) also significantly reduced (22)Na(+) influx (measured over 2 min in 150 mM external NaCl) by 47%, 30%, and 31%, respectively. In contrast to the situation in 150 mm NaCl, neither TEA(+) (1-10 mM) nor Cs(+) (0.5-10 mM) significantly reduced net Na(+) uptake or (22)Na(+) influx in 25 mM NaCl. Ba(2+) (at 5 mm) did significantly decrease net Na(+) uptake (by 47%) and (22)Na(+) influx (by 36% with 1 mM Ba(2+)) in 25 mM NaCl. K(+) (10 or 50 mM) had no effect on (22)Na(+) influx at concentrations below 75 mM NaCl, but the influx of (22)Na(+) was inhibited by 50 mM K(+) when the external concentration of NaCl was above 75 mM. The data suggest that neither nonselective cation channels nor a low-affinity cation transporter are major pathways for Na(+) entry into root cells. We propose that two distinct low-affinity Na(+) uptake pathways exist in S. maritima: Pathway 1 is insensitive to TEA(+) or Cs(+), but sensitive to Ba(2+) and mediates Na(+) uptake under low salinities (25 mM NaCl); pathway 2 is sensitive to TEA(+), Cs(+), and Ba(2+) and mediates Na(+) uptake under higher external salt concentrations (150 mM NaCl). Pathway 1 might be mediated by a high-affinity K transporter-type transporter and pathway 2 by an AKT1-type channel.     

Characterization of a Pi transport system in cartilage matrix vesicles. Potential role in the calcification process.

The mechanisms by which calcium (Ca2+) and inorganic phosphate (Pi) accumulate into matrix vesicles (MV) have not been elucidated. In the present study the characteristics of Pi uptake into MV isolated from mildly rachitic chicken growth plate cartilage have been investigated. The results indicate that Pi accumulates into MV mainly via a Na(+)-dependent Pi transport system. In the absence of NaCl in the extravesicular medium, Pi uptake was a nonsaturable process. In the presence of 150 mM NaCl, the initial rate of Pi uptake was 4.38 +/- 1.02-fold higher than with 150 mM choline chloride (mean +/- S.E., n = 8, p less than 0.005). Other cations showed partial activity to drive Pi into MV as compared to Na+:Li+ (64.4%) greater than K+ (39.8%) greater than choline (39.0%) greater than tetramethylammonium (30.0%) greater than N-methylglucamine (26.3%). Na(+)-dependent Pi transport activity displayed saturability towards increasing extra-vesicular concentrations of Na+ and Pi. The apparent Km for Pi was 0.68 +/- 0.16 mM. The Na+ concentration producing half-maximum Pi transport activity was 106.2 +/- 11.0 mM. Kinetic analysis suggests that Na+ interacts with the Pi carrier with a stoichiometry of more than one Na+ ion with one Pi molecule. In MV isolated from normal chicken growth plate cartilage, this Na(+)-dependent Pi transport system was barely expressed. In contrast to the effect on Pi uptake by MV, the activity of alkaline phosphatase was not changed when NaCl was substituted for choline chloride in the assay medium. In addition to this observation which suggests that this enzyme is not related to the Pi transport activity described in this study, levamisole, which inhibited alkaline phosphatase activity did not affect the Na(+)-dependent uptake of Pi. Both arsenate and phosphonoformic acid, two inhibitors of the epithelial Na(+)-dependent Pi transport systems, were active inhibitors of the Na(+)-dependent Pi uptake by MV with a higher potency for phosphonoformic acid. Associated with the expression of a facilitated Na(+)-coupled Pi transport in MV, in vitro calcification assessed by 45Ca2+ uptake also showed a marked dependence on extravesicular sodium. This relationship was markedly attenuated in MV isolated from normal chicken growth plate cartilage expressing a weak Na(+)-facilitated Pi transport activity. In conclusion, a saturable Na(+)-dependent Pi carrier has been characterized which facilitates Pi transport in MV. Its potential role for Ca-Pi accumulation into MV and subsequent development of vesicular calcification followed by mineralization of the osteogenic matrix is proposed and remains to be further investigated.     

Lotus tenuis tolerates the interactive effects of salinity and waterlogging by 'excluding' Na+ and Cl- from the xylem

Salinity and waterlogging interact to reduce growth of poorly adapted species by, amongst other processes, increasing the rate of Na(+) and Cl(-) transport to shoots. Xylem concentrations of these ions were measured in sap collected using xylem-feeding spittlebugs (Philaenus spumarius) from Lotus tenuis and Lotus corniculatus in saline (NaCl) and anoxic (stagnant) treatments. In aerated NaCl solution (200 mM), L. corniculatus had 50% higher Cl(-) concentrations in the xylem and shoot compared with L. tenuis, whereas concentrations of Na(+) and K(+) did not differ between the species. In stagnant-plus-NaCl solution, xylem Cl(-) and Na(+) concentrations of L. corniculatus increased to twice those of L. tenuis. These differences in xylem ion concentrations, which were not caused by variation in transpiration between the two species, contributed to lower net accumulation of Na(+) and Cl(-) in shoots of L. tenuis, indicating that ion transport mechanisms in roots of L. tenuis were contributing to better 'exclusion' of Cl(-) and Na(+) from shoots, compared with L. corniculatus. Root porosity was also higher in L. tenuis, due to constitutive aerenchyma, than in L. corniculatus, suggesting that enhanced root aeration contributed to the maintenance of Na(+) and Cl(-) 'exclusion' in L. tenuis exposed to stagnant-plus-NaCl treatment. Lotus tenuis also had greater dry mass than L. corniculatus after 56 d in NaCl or stagnant-plus-NaCl treatment. Thus, Cl(-) 'exclusion' is a key trait contributing to salt tolerance of L. tenuis, and 'exclusion' of both Cl(-) and Na(+) from the xylem enables L. tenuis to tolerate, better than L. corniculatus, the interactive stresses of salinity and waterlogging.     

Atrium contributes to osmoregulation in eels acclimated to sea water

Since highly concentrated NaCl is suspected to enter into the heart of the seawater eels, effects of high NaCl concentration on the atrial beating was examined, and plasma ion concentrations and osmolality were measured simultaneously in the blood collected from the bulbus arteriosus and from the caudal vessels. When 100 mmole l(-1) NaCl was added to the incubation medium, atrial contraction was enhanced significantly. Similar enhancement in the atrial contractility was also observed after addition of NaCH3SO4 (100 mmole l(-1)) or Tris HCl (100 mmole l(-1)), indicating that Na(+) and Cl(-) are not indispensable for the positive inotropic effect. Furthermore, an addition of sucrose (200 mmole l(-1)) also enhanced the contraction. Inversely, hypoosmotic solution reduced the atrial contraction. These results indicate that the eel atrium is sensitive to environmental osmolarity. The eel atrium responses even at 20 mmole l(-1) sucrose. Such an inotropic effect of sucrose was not depressed after blocking adrenoceptor with betaxolol, a beta1-adrenoceptor antagonist, indicating that the effect is not due to adrenaline release from nerve endings. Plasma osmolality and Na(+) concentration were higher in bulbus arteriosus than in caudal vessels, indicating that the eel heart is really exposed to hyperosmotic blood in sea water. The osmotically enhanced atrial contraction may increase the cardiac outflow into the gill. Such property of the atrium would have clear advantages for seawater teleosts, since the concentrated NaCl from the esophagus can be excreted immediately through the gill, without circulating their body, and blood homeostasis can be maintained efficiently.     

Zinc deficiency-induced iron accumulation, a consequence of alterations in iron regulatory protein-binding activity, iron transporters, and iron storage proteins

One consequence of zinc deficiency is an elevation in cell and tissue iron concentrations. To examine the mechanism(s) underlying this phenomenon, Swiss 3T3 cells were cultured in zinc-deficient (D, 0.5 microM zinc), zinc-supplemented (S, 50 microM zinc), or control (C, 4 microM zinc) media. After 24 h of culture, cells in the D group were characterized by a 50% decrease in intracellular zinc and a 35% increase in intracellular iron relative to cells in the S and C groups. The increase in cellular iron was associated with increased transferrin receptor 1 protein and mRNA levels and increased ferritin light chain expression. The divalent metal transporter 1(+)iron-responsive element isoform mRNA was decreased during zinc deficiency-induced iron accumulation. Examination of zinc-deficient cells revealed increased binding of iron regulatory protein 2 (IRP2) and decreased binding of IRP1 to a consensus iron-responsive element. The increased IRP2-binding activity in zinc-deficient cells coincided with an increased level of IRP2 protein. The accumulation of IRP2 protein was independent of zinc deficiency-induced intracellular nitric oxide production but was attenuated by the addition of the antioxidant N-acetylcysteine or ascorbate to the D medium. These data support the concept that zinc deficiency can result in alterations in iron transporter, storage, and regulatory proteins, which facilitate iron accumulation.