Gastrointestinal osmoreceptors and renal sodium excretion in humans

The hypothesis that natriuresis can be induced by stimulation of gastrointestinal osmoreceptors was tested in eight supine subjects on constant sodium intake (150 mmol NaCl/day). A sodium load equivalent to the amount contained in 10% of measured extracellular volume was administered by a nasogastric tube as isotonic or hypertonic saline (850 mM). In additional experiments, salt loading was replaced by oral water loading (3.5% of total body water). Plasma sodium concentration increased after hypertonic saline (+3.1 +/- 0.7 mM), decreased after water loading (-3.8 +/- 0.8 mM), and remained unchanged after isotonic saline. Oncotic pressure decreased by 9.4 +/- 1.2, 3.7 +/- 1.2, and 10.7 +/- 1.3%, respectively. Isotonic saline induced an increase in renal sodium excretion (104 +/- 15 to 406 +/- 39 micromol/min) that was larger than seen with hypertonic saline (85 +/- 15 to 325 +/- 39 micromol/min) and water loading (88 +/- 11 to 304 +/- 28 micromol/min). Plasma ANG II decreased to 22 +/- 6, 35 +/- 6, and 47 +/- 5% of baseline after isotonic saline, hypertonic saline, and water loading, respectively. Plasma atrial natriuretic peptide (ANP) concentrations and urinary excretion rates of endothelin-1 were unchanged. In conclusion, stimulation of osmoreceptors by intragastric infusion of hypertonic saline is not an important natriuretic stimulus in sodium-replete subjects. The natriuresis after intragastric salt loading was independent of ANP but can be explained by inhibition of the renin-angiotensin system.     

Use of a D-optimal design with constrains to quantify the effects of the mixture of sodium,potassium, calcium and magnesium chloride salts on the growth parameters of <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

The combined effect of NaCl, KCl, CaCl(2), and MgCl(2) on the water activity (a (w)) and the growth parameters of Saccharomyces cerevisiae was studied by means of a D-optimal mixture design with constrains (total salt concentrations < or = 9.0%, w/v). The a (w) was linearly related to the concentrations of the diverse salts; its decrease, by similar concentrations of salts, followed the order NaCl > CaCl(2) > KCl > MgCl(2), regardless of the reference concentrations used (total absence of salts or 5% NaCl). The equations that expressed the maximum specific growth (mu (max)), lag phase duration (lambda), and maximum population reached (N (max)) showed that the values of these parameters depended on linear effects and two-way interactions of the studied chloride salts. The mu (max) decreased as NaCl and CaCl(2) increased (regardless of the presence or not of previous NaCl); however, in the presence of a 5% NaCl, a further addition of KCl and MgCl(2) markedly increased mu (max). The lambda was mainly affected by MgCl(2) and the interactions NaCl x CaCl(2) and CaCl(2) x MgCl(2). The further addition of NaCl and CaCl(2) to a 5% NaCl medium increased the lag phase while KCl and MgCl(2) had negligible or slightly negative effect, respectively. N (max) was mainly affected by MgCl(2) and its interactions with NaCl, KCl, and CaCl(2); MgCl(2) stimulated N (max) in the presence of 5% NaCl while KCl, NaCl, and CaCl(2) had a progressive decreasing effect. These results can be of interest for the fermentation and preservation of vegetable products, and foods in general, in which this yeast could be present.     

Ecological studies onTamarix aphylla (L.) Karst

Summary Young saplings ofTamarix aphylla were investigated for their growth intensity under saline irrigation, as well as for the lethal limits of salinity they can tolerate. The saplings were found to be quite sensitive to the addition of NaCl to the irrigation solutions and died when the concentration of the solutions was raised to about 0.7.M NaCl. Growth was depressed even by irrigation with a 0.1M NaCl solution, and no increase in the plant weight was obtained under irrigation with a 0.3M NaCl solution. It, thus, appears thatT. aphylla is not suitable for afforestation of saline habitats.Some aspects of the salt excretion ofT. aphylla were investigated. Sodium and chlorine were found to be excreted most readily and exhibit an optimum type of curve, when the excretion is plotted against the concentration of the irrigation solution. Interrelations between the various ions in the irrigation solutions and the amounts of salts excreted, were found to take place and to parallel the behaviour of these ions in their uptake by the roots. T. aphylla seems to be able to reflect the soil's salinity and the composition of its salts, by the excreted salt crystals.     

KCl和NaCl处理对盐生植物碱蓬幼苗生长和水分代谢的影响

研究了用不同浓度KCl和等浓度NaCl处理的盐生植物碱蓬幼苗水分代谢的变化.结果表明,NaCl处理显著促进碱蓬生长,根吸水增加,含水量高于对照.而相同浓度KCl处理却严重抑制碱蓬生长,含水量显著下降,400 mmol/L的 KCl处理后6 d,地上部分发生萎蔫,尔后死亡.KCl处理伤害碱蓬的原因之一是抑制根系吸水,而对蒸腾速率无显著影响,即水分吸收速率与蒸腾速率比值下降,植株缺水引起伤害.     

Divergent effects of cations on follicle-stimulating hormone- and forskolin-activated adenylyl cyclase in granulosa cells

The divalent cations magnesium, calcium and manganese, and the monovalent cation, potassium, but not sodium, enhance binding of [125I]iodo-porcine follicle-stimulating hormone to follicle-stimulating hormone (FSH) receptors in membranes of porcine granulosa cells via an increase in the apparent number of binding sites. The objective of the present studies was to determine if increased binding of FSH to its receptor causes increased adenylyl cyclase activity in response to FSH, or conversely, if enhancement of the cyclase or one of its components causes increased binding, or if the two processes are modulated independently. MgCl2 and CaCl2, which both enhance binding in intact cells and in cell-free membrane preparations, had opposite effects on cyclase-MgCl2 stimulatory, CaCl2 inhibitory. In isotonic NaCl, MgCl2 did not enhance binding, but it did increase FSH-stimulated production of cyclic adenosine 3',5'-monophosphate (cAMP). NaCl did not enhance FSH binding and it did not enhance cyclase in cell-free membranes, but it did increase FSH- and forskolin-stimulated cAMP production in intact cells. In intact cells, maximally effective concentrations of MgCl2 and KCl were additive in enhancing cAMP production whereas the effects of NaCl and KCl together were synergistic. The results indicate that although cationic effects on FSH binding are not causally related to effects on cyclase, the cationic microenvironment of the granulosa cell membrane is critical to both FSH receptor and adenylyl cyclase functions.     

Contribution of NaCl excretion to salt resistance of Aeluropus littoralis (Willd) Parl

Aeluropus littoralis is a perennial halophyte, native to coastal zones. Although it is usually exposed to high saline, this plant grows normally without toxicity symptoms. In order to assess leaf salt excretion, different growth parameters, Na(+), K(+), Ca(2+), Mg(2+) and Cl(-) concentrations, as well as excreted ions were examined in plants grown for 2 months in the presence of various salinity levels (0-800 mM NaCl). In addition, salt crystals, salt glands and other leaf epidermal structures were investigated. Results showed that total plant growth decreased linearly with increase to medium salinity. This reduction concerns mainly shoot growth. In addition, this species was able to maintain its shoot water content at nearly 50% of the control even when subjected to 800 mM NaCl. Root water content seemed to be unaffected by salt. Sodium and chloride ion contents in shoots and in roots increased with salinity concentrations, in contrast to our observation for potassium. However, calcium and magnesium contents were not greatly affected by salinity. Excreted salts in A. littoralis leaves were in favor of sodium and chloride, but against potassium, calcium and magnesium which were retained in plants. Sodium and chloride were excreted from special salt glands, which were scattered on the both leaf surfaces. In addition to salt glands, papillae were the most frequent epidermal structure found on A. littoralis leaves, and are likely involved in A. littoralis salt resistance.     

Effect of deicing chloride salts on ion accumulation in spruce (Picea abies (L.) sp.)

Among the inorganic chloride salts, NaCl, CaCl₂ and in a minor proportion KCl and MgCl₂ are used as deicing agents. Mixturs of these salts were merely applied with respect to their physico-chemical properties, but their effect on roadside vegetation has never been studied so far. From a screening of different salt mixtures on ion accumulation in needles and twigs of spruce tress (Picea abies sp.) it was shown that the presence of a small amount of calcium in the salt treatments had some beneficial effects on ion regulation. In the presence of calcium, sodium accumulation could be reduced. But more straightforward was its effect on the selectivity between sodium and potasium in favour of the latter. Chloride concentrations did not alter very much; their role in the presence of monovalent cations is nevertheless obvious and is discussed. The study also confirms the presence of potassium retranslocation in conifer trees. The ion characteristics are briefly discussed with respect to the ecological effects of chloride salts on tress.     

Sodium Chloride Compartmentation in Leaf Vacuoles of the Halophyte Suaeda maritima (L.) Dum. and its Relation to Tonoplast Permeability

Single channel properties, whole vacuole currents and protonpumping capacity were investigated in the intact vacuoles andmembrane patches of leaf tonoplast from the halophyte Suaedamaritima. ATP-dependent proton pumping capacity was similarto non-halophytes whether the plants were or were not grownwith added sodium chloride (200 mM). The most abundant ion channelwas inward rectifying and had a single channel conductance of58 pS in symmetrical KCl solutions (100 mM) to 170 pS usingphysiological conditions (50/150 mM KCl/NaCl cytoplasmic side,50/450 mM KCl/NaCl vacuolar side). The channel showed all thecharacteristics of the SV type channel described in many otherspecies. In the open state these channels caused tonoplast conductancesin excess of 0.5 nS m²– but conductances were much lowerusing physiological ion concentrations and membrane potentials.In spite of the poor selectivity and the potentially large tonoplastconductance it is calculated that compartmentation of NaCl inleaf vacuoles can be sustained by about 30% of ATP-dependentproton pumping capacity. The results do not indicate any specialadaptation of the tonoplast ion channels in the halophyte. Key words: Ion-channels, patch-clamp, salt-tolerance, vacuole     

Regulation of salt gland, gut and kidney interactions

Marine birds can drink seawater because their cephalic 'salt' glands secrete a sodium chloride (NaCl) solution more concentrated than seawater. Salt gland secretion generates osmotically free water that sustains their other physiological processes. Acclimation to saline induces interstitial water and Na move into cells. When the bird drinks seawater, Na enters the plasma from the gut and plasma osmolality (Osm(pl)) increases. This induces water to move out cells expanding the extracellular fluid volume (ECFV). Both increases in Osm(pl) and ECFV stimulate salt gland secretion. The augmented intracellular fluid content should allow more rapid expansion of ECFV in response to elevated Osm(pl) and facilitate activation of salt gland secretion. To fully utilize the potential of the salt glands, intestinally absorbed NaCl must be reabsorbed by the kidneys. Thus, Na uptake at gut and renal levels may constrain extrarenal NaCl secretion. High NaCl intake elevates plasma aldosterone concentration of Pekin ducks and aldosterone stimulates intestinal and renal water and sodium uptake. High NaCl intake induces lengthening of the small intestine of adult Mallards, especially males. High NaCl intake has little effect on glomerular filtration rate or tubular sodium Na uptake of birds with competent salt glands. Relative to body mass, kidney mass and glomerular filtration rate (GFR) are greater in birds with salt glands than in birds that do not have them. Birds with salt glands do not change GFR, when they drink saline. Thus, their renal filtrate contains excess Na that is, in some species, almost completely renally reabsorbed and excreted in a more concentrated salt gland secretion. Na reabsorption by kidneys of other species, like mallards is less complete and their salt glands make less concentrated secretion. Such species may reflux urine into the hindgut, where additional Na may also be reabsorbed for extrarenal secretion. During exposure to saline, marine birds maintain elevated aldosterone levels despite high Na intake. Marine birds are excellent examples of physiological plasticity.     

A thermally induced alteration in lysosome membranes: salt permeability at 0 and 37 degrees C.

Preparations of radioactive lysosomes were obtained from mouse kidney after injection of radioactive iodine-labeled bovine ribonuclease. Stability of these lysosomes in various media was estimated from measurements of proteolytic activity towards the ribonuclease, and of ribonuclease retention in particles. The lysosomes were stable at 37 degrees C in isotonic, sucrose-free solutions of KCl, NaCl, and potassium acetate, and in mixtures of these with MgCl2, showing that these salts are relatively impermeant through the lysosomal membranes. The membranes were less permeable to Na+ than to K+. Both KCl and NaCl exerted their optimal protective effects over a broad concentration range above 0.125 M in 0.025 M acetate buffer. Mg2+ enhanced the protective effect of both K4 and Na+; the osmotic effect of 0.075 M NaC1-0.05 M MgCl2 was indistinguishable during the entire course of ribonuclease digestion from that of isotonic sucrose. Osmotic protection by KC1-MgC12 was demonstrated over the H range5.5-7.0. A marked alteration in membrane properties occurs at lower temperatures in 0.11 M KC1-0.01 M MgCl2 such that, at 0 degrees C, K+ permeability is much higher than at 37 degrees C, as shown by a several-fold decrease in stability at the lower temperature.     

Growth and mineral content of coriander (<Emphasis Type="Italic">Coriandrum sativum</Emphasis> L.) plants under mild salinity with different salts

Soil salinity is a complex issue in which various anions and cations contribute to have a general adverse effect on plant growth. In the present study, effects of salinity from various salts including sodium chloride (NaCl), potassium chloride?+?sodium chloride?+?calcium chloride (KCl?+?NaCl?+?CaCl₂), potassium sulfate?+?magnesium nitrate (K₂SO₄?+?Mg(NO₃)₂) at two electric conductivities (EC) of 2 and 4 dS m^?1 of irrigation water, and a distilled water control were evaluated on coriander plants (Coriandrum sativum L.). At EC?=?2, all salts increased plant yield (shoot fresh weight) than control. Most growth traits including plant height, shoot fresh and dry weight, leaf SPAD value and vitamin C, leaf K, Mg and P concentrations were increased by K₂SO₄?+?MgNO₃, and remained unchanged by KCl?+?NaCl?+?CaCl₂ treatment (except reduced plant height). Leaf’s zinc concentration reduced by either treatment. Even sodium chloride at EC?=?2 showed some beneficial effects on leaf chlorophyll index, root fresh weight, leaf’s calcium and phosphorus concentration; however, most traits remained unchanged than control. Treatment of plants with NaCl or KCl?+?NaCl?+?CaCl₂ at either EC increased the number of flowered shoots and leaf proline content than control. Most growth and quality traits including leaf minerals and vitamin C content were reduced by NaCl at EC?=?4; however, shoot fresh and dry weights remained unchanged than control. Plant root fresh weight increased by NaCl at EC?=?2 and decreased at EC?=?4 than control. At EC?=?4, shoot dry weight was increased and leaf Ca, P, Zn and Mn were decreased by KCl?+?NaCl?+?CaCl₂, whereas shoot dry weight, leaf SPAD value and vitamin C content, leaf Mg and P were increased and leaf Zn was decreased by K₂SO₄?+?MgNO₃ than control. The results indicate that in contrast to sodium chloride, the salinity effects of other salts can not be detrimental on coriander plant growth.     

Taste discrimination between NaCl and KCl is disrupted by amiloride in inbred mice with amiloride-insensitive chorda tympani nerves

The amiloride-sensitive salt transduction pathway is thought to be critical for the discrimination between sodium and nonsodium salts in rodents. In rats, lingual application of amiloride appears to render NaCl qualitatively indistinguishable from KCl. In this study, we tested four strains of mice for salt discriminability. In one strain (C57BL/6J), chorda tympani nerve (CT) responses to NaCl are attenuated by amiloride, and in the other three strains (BALB/cByJ, 129P3/J, DBA/2J) they are not. Under water-restriction conditions, these mice (7 mice/strain) were trained in a gustometer to lick for water from one reinforcement spout in response to a five-lick presentation of NaCl and to lick from another in response to KCl [salt concentration was varied (0.1-1 M) to render intensity irrelevant]. Mice were then tested with the stimuli dissolved in amiloride hydrochloride, and the latter was used as the reinforcer as well. Each concentration of amiloride (0.1-100 microM) was used on 2 separate days with control sessions interposed. Mice from all four strains were able to discriminate NaCl from KCl reliably. Amiloride impaired this discrimination in a dose-dependent fashion. Moreover, performance on NaCl trials appeared to be more affected by amiloride than that on KCl trials in all four strains. Thus, in contrast to the predictions based on CT recordings, discrimination in all four strains appeared to depend on the amiloride-sensitive transduction pathway, which, in the case of BALB/cByJ, 129P3/J, and DBA/2J (and perhaps C57BL/6 as well), may exist in taste buds innervated by nerves other than the CT.     

Uphill and downhill water transport in rat glioma cells

The cell water content determines the cell volume, which in turn controls numerous cellular functions. The mean volume of rat glioma cells was electronically measured under isotonic and anisotonic conditions. Two types of isotonic solutions were used containing either high or low concentrations of NaCl, KCl or N-methylglucamineCl. In low salt solutions, osmolarity was maintained constant by the addition of sucrose or mannitol. Anisotonicity was induced by changing the concentration of electrolytes. As expected, the cell volume increased when the concentration of electrolytes was decreased from a high (165 mM) monovalent cation concentration. In contrast, the cell volume decreased when the concentration of electrolytes was decreased from a low (85 mM) monovalent cation concentration. Reciprocally and unexpectedly, the cell volume increased during a hyperosmotic challenge when the initial cation concentration was low, whereas it decreased when the initial cation concentration was high. These opposite volume changes observed during similar anisotonic challenges but starting from different electrolyte concentrations provide the first evidence that H2O is not only passively transported (downhill) through aquaporins but also follows ion fluxes (uphill).     

Silicon deposition in the root reduces sodium uptake in rice (Oryza sativa L.) seedlings by reducing bypass flow

Sodium chloride reduces the growth of rice seedlings, which accumulate excessive concentrations of sodium and chloride ions in their leaves. In this paper, we describe how silicon decreases transpirational bypass flow and ion concentrations in the xylem sap in rice (Oryza sativa L.) seedlings growing under NaCl stress. Salt (50 mM NaCl) reduced the growth of shoots and roots: adding silicate (3 mM) to the saline culture solution improved the growth of the shoots, but not roots. The improvement of shoot growth in the presence of silicate was correlated with reduced sodium concentration in the shoot. The net transport rate of Na from the root to shoot (expressed per unit of root mass) was also decreased by added silicate. There was, however, no effect of silicate on the net transport of potassium. Furthermore, in salt-stressed plants, silicate did not decrease the transpiration, and even increased it in seedlings pre-treated with silicate for 7 d prior to salt treatment, indicating that the reduction of sodium uptake by silicate was not simply through a reduction in volume flow from root to shoot. Experiments using trisodium-8-hydroxy-1,3,6-pyrenetrisulphonic acid (PTS), an apoplastic tracer, showed that silicate dramatically decreased transpirational bypass flow in rice (from about 4.2 to 0.8%), while the apparent sodium concentration in the xylem, which was estimated indirectly from the flux data, decreased from 6.2 to 2.8 mM. Direct measurements of the concentration of sodium in xylem sap sampled using Philaenus spumarius confirmed that the apparent reduction was not a consequence of sodium recycling. X-ray microanalysis showed that silicon was deposited in the outer part of the root and in the endodermis, being more obvious in the latter than in the former. The results suggest that silicon deposition in the exodermis and endodermis reduced sodium uptake in rice (Oryza sativa L.) seedlings under NaCl stress through a reduction in apoplastic transport across the root.     

Effects of aldosterone and corticosterone on cloacal water and electrolyte excretion of constantly-loaded intact and colostomized ducks (Anas platyrhynchos)

1. Doses of aldosterone (50, 100 and 200 micrograms per kg body wt) evoked similar changes in Na+ and K+ excretion by intact and colostomized ducks loaded with either distilled water or 0.5 isotonic saline (70 mM NaCl, 1.5 mM KCl); both antinatriuretic and antikaliuretic responses were observed. 2. The lowest dose of aldosterone had no effect on electrlyte excretion in intact and colostomized ducks loaded with a solution containing more K+ than Na+ (74 mM KCl, 36 mM NaCl) but the higher doses caused an antinatriuretic response in both groups; a retention of K+ occurred only in intact birds given this solution. 3. The lower dose of corticosterone (1.25 mg per kg body weight) caused both antidiuresis and antinatriuresis in intact birds, but in colostomized birds the decrease in Na+ excretion was not accompanied by an antidiuresis. 4. The higher dose of corticosterone (2.50 mg per kg body wt) caused a significant increase in K+ excretion in colostomized birds, whereas no kaliuresis was ever observed in intact birds. 5. Intact and colostomized birds loaded with 0.5 isotonic saline showed no responses to the lower dose of corticosterone, whereas the higher dose had an antikaliuretic effect in intact birds and an antinatriuretic effect in colostomized birds. 6. Corticosterone had no effect on cloacal water and electrolyte excretion by intact and colostomized birds given loads containing more K+ than Na+.     

Inducing salt tolerance in maize (Zea mays L.) through seed priming with chloride salts: Growth and ion transport at early growth stages

The study was conducted to determine whether salt tolerance could be induced in maize at germination stage by soaking of seeds for 8 h in distilled water or in 200 meq·L⁻¹ of NaCl, KCl, CaCl₂·2H₂O. Both primed and un-primed seeds were subjected for 14 days to 0, 100 or 200 mol·m⁻³ NaCl under controlled conditions. Although all priming agents were effective in alleviating adverse effects of salt stress on maize at germination stage, CaCl₂·2H₂O proved to be more effective since the seeds primed with this salt had significantly higher final germination, rate of germination and fresh and dry weights of plumules and radicles than those treated with other salts or distilled water. Concentration of Na⁺, K⁺ and Ca²⁺ increased significantly in all parts of germinating seeds of maize seeds primed with NaCl, KCl, or CaCl₂·2H₂O, respectively. In addition, seeds primed with CaCl₂·2H₂O were the highest in Cl⁻ accumulation in all parts of the germinating seeds, followed by seeds treated with NaCl and KCl. Most of the Ca²⁺ was retained in seeds and mesocotyl, because of which, transport of this ion to plumules and radicles was low.     

Carbohydrate metabolism and phosphorus/salinity interactions in wheat (Triticum aestivum L.)

Foliar inorganic ion and carbohydrate concentrations were determined in wheat plants treated with factorial combinations of phosphorus fertilizer and NaCl in a glasshouse experiment. Growth reductions and visual symptoms of salt toxicity were minimized when phosphorus nutrition was adequate, and were intensified by phosphorus deficiency. Foliar sodium and chloride accumulated up to 4.0–5.5% d.w. with salinity treatment. However, ionic concentrations within corresponding leaves or distributions between leaves of plants with different phosphorus treatments were not influenced by phosphorus treatment and had no relationship to the severity of salt toxicity symptoms. This suggests that phosphorus deficiency reduced the cellular tolerance for ion accumulation. A combination of phosphorus deficiency and salinity induced an accumulation of foliar starch and sucrose despite substantial reductions in net CO₂ assimilation rates. This accumulation did not occur if phosphorus nutrition was adequate, which is consistent with the roles of phosphorus in carbohydrate metabolism. It is proposed that adequate phosphorus nutrition is essential for effective ion compartmentation by contributing to efficient carbohydrate utilization in salt-stressed wheat.     

Salt specificity of a reduced nicotinamide adenine dinucleotide oxidase prepared from a halophilic bacterium

Extracts prepared from a halophilic bacterium contained a reduced nicotinamide adenine dinucleotide (NADH(2)) oxidase active at high solute concentrations. The cation requirement was nonspecific, since KCl, RbCl, and CsCl replaced NaCl with little or no loss of activity, and NH(4)Cl was only partially effective. Only LiCl failed to replace NaCl. No specific chloride requirement was observed although not all anions replaced chloride. Bromide, nitrate, and iodide were essentially ineffective, whereas acetate, formate, citrate, and sulfate proved suitable. The presence of sulfate affected the ability of a cation to satisfy the solute requirement. Sulfate enhanced the rate of NADH(2) oxidation when compared with the rate observed in the presence of chloride. Cations which were inactive as chlorides (LiCl and MgCl(2) at high concentrations) satisfied the cation requirement when added as sulfate salts. Although magnesium satisfied the cation requirement, a concentration effect, as well as an anion effect, was observed. In the presence of MgCl(2), little NADH(2) oxidation was observed at concentrations greater than 1 m. At lower concentrations, the rate of oxidation increased, reaching a maximal value at 0.1 m and remaining constant up to a concentration of 0.05 m MgCl(2). Magnesium acetate and MgSO(4) also replaced NaCl, and the maximal rate of oxidation occurred at 0.05 m with respect to magnesium. There was no change in the rate of oxidation at high magnesium acetate concentrations, whereas the rate of NADH(2) oxidation increased at higher concentrations of MgSO(4).     

Renal physiology of two southern African Mastomys species (Rodentia: Muridae): a salt-loading experiment to assess concentrating ability

Aspects of renal physiology were examined to test the hypothesis that two cryptic species of the genus Mastomys (Mastomys natalensis and Mastomys coucha) are geographically separated by differences in aridity tolerance. Laboratory-bred females of each species were subjected to different levels of salinity in their water source (distilled water, 0.9% NaCl, and 1.5% NaCl; 10 conspecifics in each group) from weaning until sexual maturity. Individuals of the two species exhibited similar rates of water consumption and urine production. The salinity treatments caused sodium diuresis in both species, evident in increased urine volume, decreased osmolality and increased osmotic output. Urine concentration, kidney mass and kidney relative medullary area (RMA) did not differ between species. The results of our study do not support the hypothesis that differences in osmoregulatory ability separate these two cryptic species. Nor do they support the use of salt loading to elicit maximum urine concentrations in mammals.     

Effects of oligomycin on the partial reactions of the sodium plus potassium-stimulated adenosine triphosphatase

The effects on phosphoenzyme (E-P) formation of ligands which activate Electrophorus (Na,K)-ATPase were investigated in the presence of oligomycin. When the enzyme was allowed to bind oligomycin in the presence of NaCl and MgCl2, subsequent addition of ATP plus KCl produced a monoexponential time course of E-P formation with a rate of 56 s-1, similar to the rate obtained in the uninhibited enzyme phosphorylated by ATP in the absence of KCl. Pi liberation under these conditions was slow and showed no initial burst phase, consistent with the inhibitory effect oligomycin has on the E1-P to E2-P conformational transition. Addition to KCl to a preincubation medium containing oligomycin, NaCl, and MgCl2 had no further effect on E-P formation. However, equilibration with oligomycin, KCl, and MgCl2 prior to the addition of NaCl plus ATP gave a much slower rate of E-P formation (5 s-1) and resulted in an initial rapid release of Pi similar to that found in the uninhibited enzyme. The slow increase in E-P level observed after incubation with oligomycin, KCl, and MgCl2 may be due to secondary formation of an inhibition complex following rapid binding of oligomycin. In contrast to the monophasic behavior which resulted from pre-exposure to NaCl or KCl, preincubation with oligomycin in the presence of MgCl2 plus Tris or Tris alone gave a biphasic pattern of E-P formation in which about 50% of the intermediate accumulated at a rate of 56 s-1 and the remainder at a rate of 5 s-1. In addition, the Pi burst amplitude was reduced, indicating partial inhibition of the enzyme. These results suggest that in the absence of Na+ and K+ only half of the enzyme is inhibited by oligomycin while the remainder undergoes inhibition subsequent to initiation of phosphorylation. Since the oligomycin concentration was saturating, the partial inhibition reflected in the biphasic pattern of E-P formation may be due to half-of-the-sites reactivity in which only half of the subunits bind oligomycin in the absence of monovalent cations.