Digitalis-like compounds in the toad Bufo viridis: tissue and plasma levels and significance in osmotic stress.

Digitalis-like compounds (DLC), constituents of animal tissues, are possible regulators of the Na+, K(+)-ATPase implicated in water and salt homeostasis. The distribution of DLC in the toad (Bufo viridis) was determined following methanol extraction and partial purification. DLC highest levels were found in the skin but it was also detected in the plasma and many internal organs. Short term (hours) exposure of the toad to hypertonic shock (1.5% NaCl) induced an increase in plasma osmolarity due to an increase in Na+ and Cl- levels. This treatment induced a transient, three fold, increase of DLC levels in the brain and transient reduction of its levels in the ventral skin. Acclimation of the toads to burrowing conditions for six weeks resulted in an increase in plasma osmolarity due to a large increase in plasma urea with a small increase in ion concentrations. Under these conditions DLC levels in the dorsal skin increased by 100% without alteration of its levels in the plasma, brain and ventral skin. DLC levels in the toad brain of control animals, showed a significant dependence on season, being highest in the summer and lowest in the winter. DLC levels in the skin peaked in May while the levels in the plasma were season independent. The changes in DLC levels induced by the short- as well as long-term perturbations in the animal environmental salinity together with the seasonal differences suggest that DLC in the toad is involved in water and salt homeostasis of these animals, but may also participate in other unknown functions.     

The digitalis-like steroid hormones: new mechanisms of action and biological significance

Digitalis-like compounds (DLC) are a family of steroid hormones synthesized in and released from the adrenal gland. DLC, the structure of which resembles that of plant cardiac glycosides, bind to and inhibit the activity of the ubiquitous cell surface enzyme Na(+), K(+)-ATPase. However, there is a large body of evidence suggesting that the regulation of ion transport by Na(+), K(+)-ATPase is not the only physiological role of DLC. The binding of DLC to Na(+), K(+)-ATPase induces the activation of various signal transduction cascades that activate changes in intracellular Ca(++) homeostasis, and in specific gene expression. These, in turn, stimulate endocytosis and affect cell growth and proliferation. At the systemic level, DLC were shown to be involved in the regulation of major physiological parameters including water and salt homeostasis, cardiac contractility and rhythm, systemic blood pressure and behavior. Furthermore, the DLC system has been implicated in several pathological conditions, including cardiac arrhythmias, hypertension, cancer and depressive disorders. This review evaluates the evidence for the different aspects of DLC action and delineates open questions in the field.     

Temperature and humidity alter prolactin receptor expression in the skin of toad (Bufo bankorensis and Bufo melanostictus)

Bufo bankorensis and Bufo melanostictus, the only two species of Bufonidae genus in Taiwan, live in habitats that differ in altitude and humidity. This study tested the hypothesis that prolactin receptor (PRLR) expression responds to environmental change. Western blot analysis showed that the PRLR protein was widely distributed in brain, lung, liver, kidney, dorsal skin and ventral skin of toads. The level PRLR protein was elevated in the dorsal skin of the two toad species treated with dry or wet conditions for 14 days. The increase in PRLR of dorsal skin in B. bankorensis was higher than that in B. melanostictus. This experimental result suggests that B. bankorensis secretes more mucus to reduce water evaporation from its thinner cuticle than B. melanostictus. The expression of PRLR protein was increased in the lung of B. bankorensis and decreased in the lung of B. melanostictus. Moreover, PRLR protein levels were increased in the kidneys in the two species toad, likely due to reduction in water lost through lung and urine. The two toad species were subjected to varying temperatures (25 degrees C, 15 degrees C and 10 degrees C) for 14 days. The lowest PRLR protein expression was observed at 10 degrees C. Comparison of the decreasing trend in PRLR protein levels demonstrated that the variation in B. bankorensis was significantly higher than that in B. melanostictus. Comparisons of variation in PRLR protein expression in the two species under different environments suggest that B. bankorensis is more adaptable to different environments than B. melanostictus.     

Water retention and plasma and urine composition in toads (Bufo viridis Laur.) under burrowing conditions

Summary Osmoregulation in the terrestrial toad,Bufo viridis, was studied under burrowing conditions in the laboratory. The toads can live for over 3 months burrowed in soil containing 9–10% moisture, maintaining constant body volume due to a large increase in the plasma osmolality, contributed mainly by urea. Water content of the tissues remains constant. Relatively large volumes of urine are stored in the urinary bladder during water restriction. The osmolality of the urine does not exceed that of the plasma. Urea uptake across the skin was measured in vitro and was greatly elevated in skins from the burrowed toads. The increase in plasma osmolality enables greater water absorption from the soil under water restricted conditions while the water content of the tissues is maintained constant since cell membranes are highly permeable to urea. It is concluded that the urea accumulating ability and urea tolerance form the basis for both the terrestriality and salt adaptability of this and other amphibian species.     

Vascular aspects of water uptake mechanisms in the toad skin: perfusion, diffusion, confusion

Blood cell flow (BCF) in the water absorbing "seat patch" region of toad skin was measured with laser Doppler flow cytometry. BCF of dehydrated toads increased by a factor of 6-8 when water contact was made and declined gradually as toads rehydrated. Water absorption was initially stimulated and declined in parallel with BCF. Water absorption measured during the initial rehydration period did not correlate with BCF and hydrated toads injected with AVT increased water absorption without an increase in BCF indicating the lack of an obligate relation between blood flow and water absorption. Aquaporins 1-3 were characterized by RT-PCR analysis of seat patch skin. AQP 1 was localized in the endothelium of subepidermal capillaries and serves as a pathway for water absorption in series with the apical and basolateral membranes of the epithelium. Dehydrated toads rehydrated more rapidly from dilute NaCl solutions than from deionized water despite the reduced osmotic gradient. BCF of toads rehydrating on 50 mM NaCl was not different than on deionized water and blocking Na+ transport with 100 microM amiloride did not reduce water absorption from 50 mM NaCl. Thus, neither circulation nor solute coupling explains the greater absorption from dilute salt solutions. Rehydration from 10 mM CaCl2 was stimulated above that of DI water by a similar degree as with 50 mM NaCl suggesting the anion might control water permeability of the skin.     

Effect of acute serum depletion on Na+-K+ homeostasis in cultured human skin fibroblasts

In order to elucidate changes in cell transport behavior of cultured human skin fibroblasts in response to acute serum depletion, we performed uptake and washout of 22Na+ and 86Rb+ as well as measurements of the intracellular Na+ and K+ levels in the presence and absence of ouabain. Pronounced and lasting increase in cellular Na+ and decrease in K+ were observed after removal of fetal bovine serum (FBS) from the medium. The sum of the Na+ and K+ contents (nEq/10(5) cells) was lower in FBS-free medium (mean +/- SD; 17.3 +/- 2.2) than in FBS-containing medium (26.2 +/- 3.8; P less than .02). Simultaneously, a decrease in cellular water volume was detected in the FBS-free medium. The cation uptake and washout data suggest that FBS removal primarily renders the cells more permeable to Na+ and K+ with a secondary stimulation of the ouabain-sensitive Na+ extrusion mechanism. FBS at a concentration of 0.2% prevented approximately 50% of the maximal increase in the 86Rb+ washout rate constant associated with FBS depletion. Ouabain (2 microM) produced an increase in the 86Rb+ washout rate constant. This effect was substantially larger in cells subjected to medium without FBS (from 0.0303 to 0.2500 min-1) than in fibroblasts incubated in medium with FBS (from 0.0107 to 0.0487 min-1). The cellular K+ content was drastically reduced by ouabain to a level not different in medium with or without FBS (33.9 +/- 4.5 to 1.75 +/- 0.38 and 16.7 +/- 1.4 to 1.4 +/- 0.13 nEq/10(5) cells, respectively). The 22Na+ washout data exhibited a three-exponential pattern. Analytical solutions of the washout data by means of two models (serial and parallel) with three compartments showed that FBS depletion resulted in increase of the size of all three compartments. It is concluded that in cultured human skin fibroblasts, FBS is essential to the maintenance of a normal Na+ and K+ homeostasis. The removal of FBS results in dramatic permutation of this homeostasis that develops within minutes and lasts for hours.     

METABOLISM OF GLUCOSE, AMINO ACIDS, AND SOME RELATED METABOLITES IN THE BRAIN OF TOADS (BUFO BOREAS) ADAPTED TO FRESH WATER OR HYPEROSMOTIC ENVIRONMENTS

The levels and specific radioactivities (SA) of glucose, lactate, pyruvate, α-oxoglutarate and seven amino acids in the brain of toads adapted to fresh water or to an hyperosmotic environment were analysed at various times (5 min–4 h) after an injection of [U-¹⁴C]glucose into the bloodstream. The concentrations and SA of glucose, lactate and five amino acids in blood plasma also were measured. In addition, the SA of glutamine, glutamate, aspartate and GABA in brain were determined 30 min after an injection of [1,5-¹⁴C]citrate into the cisterna magna. The flow of labelled carbon atoms from glucose to amino acids and related metabolites in the toad brain was qualitatively similar to that in the mammalian brain, but quantitatively less than one-tenth of the rate in the brain of rats. Hyperosmotic adaptation induced a large increase in the levels of glucose and amino acids in the brain without affecting the rate of glucose utilization. The SA of several amino acids relative to the SA of glucose were initially lower in hyperosmotically-adapted toads than in toads adapted to fresh water, presumably because of a greater dilution of isotope by the larger amino acid pools in the hyperosmotically-adapted toads. The rates of synthesis of alanine and glutamine from pyruvate and glutamate, respectively, appeared to increase with hyperosmotic adaptation, but the rate of GABA synthesis from glutamate was unaltered. The SA of α-oxoglutarate and glutamate were similar at all time periods in both groups of toads, an indication that these compounds were interconverted much more rapidly than the rate at which α-oxoglutarate was formed from isocitrate. The SA of lactate in comparison to that of glucose varied but was always considerably lower, even at 4 h after the [¹⁴C]glucose injection. After[U-¹⁴C]glucose, glutamine had a SA lower than that of glutamate, whereas after the injection of [1⁴C]citrate, glutamine was formed with a SA much higher than that of glutamate. Hence, glutamate in the toad brain exhibited metabolic compartmentation similar to that in rat brain.     

Effects of dehydration on plasma osmolality, thirst-related behavior, and plasma and brain angiotensin concentrations in Couch's spadefoot toad, Scaphiopus couchii

Under dehydrating conditions, many terrestrial vertebrates species exhibit increases in plasma osmolality and their drinking behavior. Under some circumstances, this behavioral change is accompanied by changes in plasma and central angiotensin concentrations, and it has been proposed that these changes in angiotensin levels induce the thirst-related behaviors. In response to dehydration, the spadefoot toad, Scaphiopus couchii, exhibits thirst-related behavior in the form of cutaneous drinking. This behavior has been termed water absorption response (WR) behavior. Spadefoot toads live in harsh desert environments and are subject annually to dehydrating conditions that may induce thirst-related behavior. We tested the hypothesis that an increase in WR behavior is associated with both an increase in plasma osmolality and an increase in plasma and brain angiotensin concentrations. First, we determined the degree of dehydration that was necessary to initiate WR behavior. Animals dehydrated to 85% of their standard bladder-empty weight via deprivation of water exhibited WR behavior more frequently than control toads left in home containers with water available. Next, using the same dehydration methods, we determined the plasma osmolality and sodium concentrations of dehydrated toads. Toads dehydrated to 85% standard weight also had a significant increase in plasma osmolality, but exhibited no overall change in plasma sodium concentrations, indicating that while an overall increase in plasma osmolality appears to be associated with WR behavior in S. couchii, changes in sodium concentrations alone are not sufficient to induce the behavior. Finally, plasma and brain angiotensin concentrations were measured in control toads and toads dehydrated to 85% standard weight. Plasma and brain angiotensin concentrations did not increase in dehydrated toads, indicating that dehydration-induced WR behavior that is associated with changes in plasma osmolality may not be induced by changes in endogenous angiotensin concentrations in S. couchii.     

Effect of prolonged high salt diet on atrial natriuretic factor in rats

Normotensive Sprague-Dawley rats were given 8% NaCl for 5 weeks. This salt load did not affect their blood pressure nor hematocrit, and plasma atrial natriuretic factor (ANF) showed no change at 3 weeks but decreased after 5 weeks of the experimental period when compared with control rats. The responsiveness of particulate guanylate cyclase and formation of cGMP in ANF target organs suggested an augmented baseline activity of the cGMP system but its relative hyporesponsiveness to exogenous ANF following prolonged salt loading. Decreased plasma ANF levels cannot be explained by its altered production since atrial levels of the peptide were comparable in rats with or without salt loading. Atrial ANF mRNA was unaffected by the salt regimen. This study demonstrates that plasma ANF does not increase during long-term NaCl loading and even decreases after 5 weeks of 8% NaCl. The changes in plasma ANF are associated with changes in the functional state of ANF receptors coupled to particulate guanylate cyclase, but in the opposite direction than expected from lowered plasma ANF. Thus, ANF may not play a significant role in the regulation of sodium excretion in response to prolonged high salt consumption or, if it does, it is not reflected by expected changes in its plasma levels.     

UPTAKE AND METABOLISM OF GLUTAMATE BY ISOLATED TOAD BRAINS CONTAINING DIFFERENT LEVELS OF ENDOGENOUS AMINO ACIDS

—The uptake of [U-¹⁴C]glutamate into the amphibian brain was studied in vitro using brains from toads (Bufo boreas) adapted either to a fresh water (FWA) or an hyperosmotic saline (HOA) environment. Initial rates of ¹⁴C-glutamate uptake showed a single apparent K_m of about 0·2 mm . Uptake by HOA brains was slower than that by FWA brains, reflecting perhaps a non-competitive type of inhibition by the higher content of glutamate in the HOA brains. Although the glutamate content of HOA brains was maintained during prolonged incubation at twice the level found in FWA toads, other metabolic parameters measured in the two types of brain preparations were surprisingly similar. Tissue to medium concentration ratios of greater than 3000:1 were generated by both FWA and HOA brains. In both brain systems the clearance of glutamate from the medium was accompanied by a rapid conversion of the amino acid to glutamine and its release into the medium. In both the FWA and HOA toad brain systems some [U-¹⁴C]glutamate was metabolized to aspartate and GABA; in both systems the specific radioactivity (SA) of glutamine in the tissue was from two to four times greater than that of glutamate; also the SA of glutamine released into the medium was higher by several orders of magnitude than the SA of glutamine in brain tissues. These and other findings support the concept that, in both the FWA and HOA toad brains, transport processes are instrumental in preserving low extracellular levels of glutamate but that mechanisms other than transport are responsible for the maintenance of different levels of glutamate in the FWA and HOA toad brains.     

Inhibition of the permeability response to vasopressin and oxytocin in the toad bladder: Effects of bradykinin,kallidin, eledoisin,and physalaemin

Summary It has been shown by means of Bentley'sin vitro preparation of the isolated urinary bladder of the toad,Bufo marinus paracnemis Lutz, that bradykinin reversibly inhibited the increase brought about by vasopressin on the permeability to water of the toad bladder. The increased hydro-osmotic response of the bladder to oxytocin was also inhibited by the kinin. The effect on water permeability was observed when bradykinin was added either to the serosal Ringer's solution or to the mucosal solution. The addition of bradykinin alone did not alter the basal osmotic water transfer across the bladder. In this context, bradykinin acted as a competitive antagonist of vasopressin (and oxytocin). Although lacking intrinsic activity, bradykinin exhibited affinity for receptor sites that are also common to the neurohypophysial hormones, causing a parallel shift of the log-dose/response curve for vasopressin without changing the maximal responses. The effects of other kinins (namely kallidin, eledoisin and physalaemin) on the toad bladder were also tested. Each of these drugs alone did not change the basal water flux across the bladder wall. Like bradykinin, these peptides inhibited the increase in water permeability evoked by vasopressin and oxytocin in the bladder. In view of the importance of neurohypophysial hormones and their target tissues to the osmotic homeostasis of amphibians, and the observation of antagonism between the kinins and the pituitary hormones coupled to the abundance of kinins in the amphibian organism, particularly in the skin and urinary bladder, teleological reasoning predicts a physiological role for the kinins, possibly functioning to dampen excesses and oscillations in membrane permeability that could occur in face of a constant and variable secretion of neurohypophysial hormone, thus adding to the homeostatic response of the amphibian organism.     

Effect of rat cardionatrin I (rat ANF 99-126) on the response of toad skin to angiotensin II

The atrial natriuretic peptide cardionatrin I (cardionatrin I is ANF 99-126) was used in studies directed to assess its effects on osmotic water permeability (Posm) and short-circuit current (SCC) in isolated toad skin. Results showed that ANF 99-126 (10(-7) M) added to the dermal side of the skin had no effect on basal Posm or SCC. However, ANF 99-126 (3.3 x 10(-8) M) was able to produce a 50% reversible inhibition of the maximal Posm response to angiotensin II (AII) (3.2 x 10(-8) M). These effects were seen when the skins were preincubated with ANF 99-126 for 10 min or less before the addition of AII. Longer preincubation appeared to inactivate ANF 99-126 through proteolysis. ANF 99-126(10(-7) M) failed to inhibit the SCC response to AII (10(-5) M) in toad skin. These results are compatible with a modulatory function for ANF on several systems including those involved in the regulation of extracellular fluid volume.     

NaCl alleviates polyethylene glycol-induced water stress in the halophyte species Atriplex halimus L

Atriplex halimus L. is a C4 xero-halophyte species well adapted to salt and drought conditions. To collect information on the physiological impact of low salt levels on their water-stress resistance, seedlings were exposed for 6 d to nutrient solution containing either 0% or 15% polyethylene glycol 10,000 (PEG), in the presence or in the absence of 50 mM NaCl. Similar experiments were performed with one PEG-resistant and one PEG-sensitive selected cell line exposed for 50 d to 0% or 15% PEG on standard Linsmaier and Skoog (LS) medium, on LS medium supplemented with 50 mM NaCl, or on Na+-free medium. NaCl mitigated the deleterious impact of PEG on growth of both whole plants and PEG-sensitive cell lines and improved the ability of stressed tissues to perform osmotic adjustment (OA). Water stress reduced CO2 net assimilation rates quantified in the presence of high CO2 and low O2 levels (A), stomatal conductance and transpiration, but NaCl improved water use efficiency of PEG-treated plants through its positive effect on A values, especially in young leaves. PEG increased the internal Na+ concentration. The resistant cell line accumulated higher concentration of Na+ than the PEG-sensitive one. The complete absence of Na+ in the medium endangered the survival of both cell lines exposed to PEG. Although Na+ by itself contributed only for a small part to OA, NaCl induced an increase in proline concentration and stimulated the synthesis of glycinebetaine in response to PEG in photosynthetic tissues. Soluble sugars were the main contributors to OA and increased when tissues were simultaneously exposed to PEG and NaCl compared with PEG alone, suggesting that Na+ may influence sugar synthesis and/or translocation.     

Effect of experimental hyperphenylalaninemia induced by dietary phenylalanine plus α-methylphenylalanine administration on amino acid concentration in neonatal chick brain,plasma, and liver

Supplementation of 5% phenylalanine plus 0.4% -methylphenylalanine to the standard diet or 1% phenylalanine plus 0.08% -methylphenylalanine to the drinking water produced phenylketonuria-like conditions in 5-day-old chicks. An increase of 10 to 15-fold in the phenylalanine content was observed in plasma or brain of animals after 9 days of both types of treatment. A smaller but significant increase was also observed in liver. However, practically no changes were found in the levels of tyrosine in the same conditions. Thus, the high values of plasma and brain phenylalanine/tyrosine ratio obtained by these treatments were mainly due to an increase in the phenylalanine levels, without increasing those of tyrosine. Chronic hyperphenylalaninemia induced a nonsignificant decrease in the most of amino acid contents in brain, especially after 9 days of treatment, although the levels of glycine and serine were significantly increased. A similar decrease was found in the plasma and liver concentration of various amino acids, although the variations observed in the liver were smaller than those found in plasma and brain.     

Plasma GABA levels in neurological patients under treatment with valproic acid

The effect of chronic treatment with valproic acid (VPA), administered as its sodium salt, on the plasma concentrations of GABA was studied in 5 in-patients. Within 2–10 days of treatment with daily doses of 1500–3000 mg sodium VPA GABA levels increased to 30–80 % compared to control days. This increase was transient in 3 out of 5 patients. In 19 epileptic patients under VPA medication plasma GABA levels were 40 % higher than those determined in non-epileptic patients serving as controls. The possibility that the increase in plasma GABA induced by VPA reflects similar increases in brain GABA content is discussed.     

Trypsin affects basal and stimulated osmotic water permeability in isolated toad skin

1. We investigated the effect of trypsin (Tryp) on basal, stimulated and fluphenazine (FPZ)-inhibited net water flow (Jw) through isolated toad skin (Bufo arenarum). 2. Epidermal Tryp (20 min) promoted an increase in basal Jw which was dose-dependent (maximal with 0.5 mg/ml) and was prevented by a Tryp inhibitor (SBTI). 3. Tryp treatment inhibited the subsequent response to substances known to act before (oxytocin, Oxy) or after cyclic AMP (cAMP) generation (theophylline). 4. Tryp-induced Jw was not additive with the maximal response to Oxy or theophylline and did not modify FPZ's inhibitory effect on stimulated Jw. 5. Dermal Tryp (0.5 mg/ml, 20 min) did not modify basal, but inhibited Oxy and isoproterenol-stimulated Jw, without altering the response to theophylline or db-cAMP. 6. Collectively, our results show a differential action for epidermal and dermal Tryp. Tryp's side-selective action enables its use as a pharmacological tool in the functional dissection of Jw across toad skin.     

Viability of some metabolic processes in the isolated toad brain adapted to two osmotic environments.

The viability of the isolated toad brain in an aerated Ringer-like medium has been evaluated by the following criteria: 1) amino acid content before and after incubation; 2) accumulation of amino acids in the incubation medium; 3) a comparison of glucose utilization and [U-14C]glucose metabolism with that occurring in vivo; 4) tissue swelling; and 5) tissue lactate contents. On the basis of these criteria, the isolated toad brain, from toads adapted to a fresh-water or a salt-water environment, retains considerable metabolic integrity for at least 2 hr of incubation at 25 degrees C. Specifically, there was no swelling of the tissue, no apparent accumulation of lactate in the tissue, glucose appeared to be utilized at a rate not too different from that calculated for the toad brain in vivo, and the distribution of label from [U-14C]glucose had an overall pattern which resembled that observed in vivo. The tissue levels of amino acids were generally stable in vitro; however, there was a marked decline in the content of aspartate. The accumulation of amino acids in the medium varied considerably from one amino acid to another. Thus, there was very little net efflux of aspartate, GABA, and glutamate from the tissue but considerable net efflux of glutamine. This efflux of amino acids was greater from brains of hyperosmotically adapted toads than from the brains of toads adapted to fresh water by amounts proportional to their initial tissue contents.     

Atrial natriuretic peptide in the locus coeruleus and its possible role in the regulation of arterial blood pressure, fluid and electrolyte homeostasis.

Atrial natriuretic factor (ANP) is present in neuronal cells of the locus coeruleus and its vicinity in the pontine tegmentum and moderate amount of ANP is detectable in this area by radioimmunoassay. The ANP (both peripheral and brain-born) is known as a neuropeptide which may influence the body salt and water homeostasis and blood pressure by targeting both central and peripheral regulatory mechanisms. Whether this pontine ANP cell group is involved in any of these regulatory mechanisms, the effect of various types of hypertension and experimental alterations in the salt and water balance on ANP levels was measured by radioimmunoassay in the locus coeruleus of rats. Adrenalectomy, as well as aldosterone and dexamethasone treatments failed to alter ANP levels in the locus coeruleus. Reduced ANP levels were measured in spontaneously hypertensive (both young and adult) rats, and in diabetes insipidus (Brattleboro) rats with vasopressin replacement. In contrast to these situations, elevated ANP levels were found in rats with DOCA-salt or 1-kidney-1-clip hypertension. These data suggest a link between ANP levels in the locus coeruleus and fluid volume homeostasis. Whether this link is causal and connected with the major activity of locus coeruleus neurons (noradrenergic influence on brain regulatory activities) needs further informations.     

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.