Interaction of fatty acid sodium salts with sodium deoxycholate

Interaction of homologous fatty acids (C3-C18) with sodium deoxycholate was investigated. From NMR and ultrasonic results it was found that short chain homologues (up to C9) do not participate in the formation of mixed micelles with sodium deoxycholate. Fatty acid homologues with longer chains (starting with C9) form mixed micelles by "burying" hydrophobic chains in hydrophobic environment of a sodium deoxycholate micelle.     

Intracellular sodium regulates proteolytic activation of the epithelial sodium channel

Na(+) transport across epithelia is mediated in part by the epithelial Na(+) channel ENaC. Previous work indicates that Na(+) is an important regulator of ENaC, providing a negative feedback mechanism to maintain Na(+) homeostasis. ENaC is synthesized as an inactive precursor, which is activated by proteolytic cleavage of the extracellular domains of the alpha and gamma subunits. Here we found that Na(+) regulates ENaC in part by altering proteolytic activation of the channel. When the Na(+) concentration was low, we found that the majority of ENaC at the cell surface was in the cleaved/active state. As Na(+) increased, there was a dose-dependent decrease in ENaC cleavage and, hence, ENaC activity. This Na(+) effect was dependent on Na(+) permeation; cleavage was increased by the ENaC blocker amiloride and by a mutation that decreases ENaC activity (alpha(H69A)) and was reduced by a mutation that activates ENaC (beta(S520K)). Moreover, the Na(+) ionophore monensin reversed the effect of the inactivating mutation (alpha(H69A)) on ENaC cleavage, suggesting that intracellular Na(+) regulates cleavage. Na(+) did not alter activity of Nedd4-2, an E3 ubiquitin ligase that modulates ENaC cleavage, but Na(+) reduced ENaC cleavage by exogenous trypsin. Our findings support a model in which intracellular Na(+) regulates cleavage by altering accessibility of ENaC cleavage sites to proteases and provide a molecular explanation for the earlier observation that intracellular Na(+) inhibits Na(+) transport via ENaC (Na(+) feedback inhibition).     

The epithelial sodium channel and the control of sodium balance

Studies aiming at the elucidation of the genetic basis of rare monogenic forms of hypertension have identified mutations in genes coding for the epithelial sodium channel ENaC, for the mineralocorticoid receptor, or for enzymes crucial for the synthesis of aldosterone. These genetic studies clearly demonstrate the importance of the regulation of Na⁺ absorption in the aldosterone-sensitive distal nephron (ASDN), for the maintenance of the extracellular fluid volume and blood pressure.Recent studies aiming at a better understanding of the cellular and molecular basis of ENaC-mediated Na⁺ absorption in the distal part of nephron, have essentially focused on the regulation ENaC activity and on the aldosterone-signaling cascade. ENaC is a constitutively open channel, and factors controlling the number of active channels at the cell surface are likely to have profound effects on Na⁺ absorption in the ASDN, and in the amount of Na⁺ that is excreted in the final urine.A number of membrane-bound proteases, kinases, have recently been identified that increase ENaC activity at the cell surface in heterologous expressions systems. Ubiquitylation is a general process that regulates the stability of a variety of target proteins that include ENaC. Recently, deubiquitylating enzymes have been shown to increase ENaC activity in heterologous expressions systems.These regulatory mechanisms are likely to be nephron specific, since in vivo studies indicate that the adaptation of the renal excretion of Na⁺ in response to Na⁺ diet occurs predominantly in the early part (the connecting tubule) of the ASDN.An important work is presently done to determine in vivo the physiological relevance of these cellular and molecular mechanisms in regulation of ENaC activity. The contribution of the protease-dependent ENaC regulation in mediating Na⁺ absorption in the ASDN is still not clearly understood. The signaling pathway that involves ubiquitylation of ENaC does not seem to be absolutely required for the aldosterone-mediated control of ENaC. These in vivo physiological studies presently constitute a major challenge for our understanding of the regulation of ENaC to maintain the Na⁺ balance.     

Ultrastructural staining with sodium metaperiodate and sodium borohydride.

This article describes new ultrastructural staining methods for osmicated tissues based on the incubation of sections with sodium metaperiodate and sodium borohydride solutions before uranyl/lead staining. Sections incubated with sodium metaperiodate and sodium borohydride, treated with Triton X-100, and stained with ethanolic uranyl acetate/lead citrate showed a good contrast for the nucleolus and the interchromatin region, whereas the chromatin masses were bleached. Chromatin bleaching depended on the incubation with these oxidizing (metaperiodate) and reducing (borohydride) agents. Other factors that influenced the staining of the chromatin masses were the en bloc staining with uranyl acetate, the incubation of sections with Triton X-100, and the staining with aqueous or ethanolic uranyl acetate. The combination of these factors on sections treated with metaperiodate/borohydride provided a different appearance to the chromatin, from bleached to highly contrasted. Most cytoplasmic organelles showed a similar appearance with these procedures than with conventional uranyl/lead staining. However, when sections were incubated with metaperiodate/borohydride and Triton X-100 before uranyl/lead staining, the collagen fibers, and the glycocalix and zymogen granules of pancreatic acinar cells, appeared bleached. The possible combination of these methods with the immunolocalization of the amino acid taurine was also analyzed. (J Histochem Cytochem 50:11-19, 2002)     

Endocrine disorders of sodium regulation. Role of adrenal steroids in genetic defects causing sodium loss or sodium retention

Salt and water homoeostasis is tightly regulated by a variety of control mechanisms with the adrenal steroid hormone aldosterone playing a central role. Defects or disturbances in these systems lead to either salt loss, which is life threatening in the neonatal period, or sodium retention causing hypertension. Rapid and accurate diagnosis is required to avoid severe complications. During the last few years molecular genetic advances have been identified as the basic genetic defects for a number of clinical syndromes. This knowledge has considerably increased our understanding of the basic pathways involved in sodium and water homoeostasis and of the pathophysiology of these syndromes, particularly the hypertension. In this review we have summarized the biochemical, physiological and genetic basis for clinical syndromes presenting with salt loss and failure to thrive as well as the rare but important genetic syndromes causing sodium retention and hypertension. Early diagnosis and identification will help to prevent severe complications, but it has to be emphasized that the complicated cascade of aldosterone action is still relatively poorly understood. Further syndromes may exist which once identified will help to better understand the basic physiology of aldosterone action.     

Intracellular sodium activity and sodium transport inNecturus gallbladder epithelium

Summary Ion-sensitive glass microelectrodes, conventional microelectrodes and isotope flux measurements were employed inNecturus gallbladder epithelium to study intracellular sodium activity, [Na] _i , electrical parameters of epithelial cells, and properties of active sodium transport. Mean control values were: [Na] _i : 9.2 to 12.1mm; transepithelial potential difference, _ms : –1.5 mV (lumen negative); basolateral cell membrane potential, _es : –62 mV (cell interior negative); sodium conductance of the luminal cell membrane,g _Na: 12 mho cm^–2; active transcellular sodium flux, 88 to 101 pmol cm^–2 sec^–1 (estimated as instantaneous short-circuit current). Replacement of luminal Na by K led to a decrease of the intracellular sodium activity at a rate commensurate to the rate of active sodium extrusion across the basolateral cell membrane. Mucosal application of amphotericin B resulted in an increase of the luminal membrane conductance, a rise of intracellular sodium activity, and an increase of short-circuit current and unidirectional mucosa to serosa sodium flux. Conclusions: (i) sodium transport across the basolateral membrane can proceed against a steeper chemical potential difference at a higher rate than encountered under control conditions; (ii) the luminal Na-conductance is too low to accommodate sodium influx at the rate of active basolateral sodium extrusion, suggesting involvement of an electrically silent luminal transport mechanism; (iii) sodium entry across the luminal membrane is the rate-limiting step of transcellular sodium transport and active sodium extrusion across the basolateral cell membrane is not saturated under control conditions.     

Effects of cytoplasmic sodium concentration on the electrogenicity of the sodium pump

Inside-out membrane vesicles were prepared from human red blood cells pretreated with diisothiocyano-2,2'-disulfonic stilbene to inhibit anion fluxes. The pH-sensitive probe fluorescein isothiocyanate-dextran was incorporated inside the vesicles. Formation of pH gradients due to proton transport by the sodium pump was distinguished from pH gradients formed in response to transmembrane electrical potentials generated by the pump by virtue of their insensitivity and sensitivity, respectively, to dissipation by lipophilic cations. Under the conditions used (pH 6.6), proton transport by the Na,K-ATPase was minimized, and the formation of pH gradients in response to electrical potentials was detected. Thus, the generation of a strophanthidin-sensitive, ATP-dependent electrical potential, inside positive (approximately 1 mV) upon addition of 4 meq of sodium to potassium-filled inside-out vesicles is consistent with the well documented stoichiometry of three sodium ions exchanging with two potassium ions. In contrast, when the cytoplasmic sodium concentration is reduced to less than or equal to 0.4 mM, the potential generated is of the opposite sign, i.e. inside negative, consistent with the decreased Na:K coupling ratio reported previously, i.e. Na:K(Rb) coupling ratios of approximating 1:2 when the sodium concentration is reduced to 0.2 mM (Blostein, R. (1983) J. Biol. Chem. 258, 12228-12232).     

Crystallization of sodium taurocholate

Success in crystallizing sodium taurocholate from ethanol by the addition of ether is critically dependent on the water content of the system. Two crystalline forms of sodium taurocholate were obtained with melting points of 180 degrees C and 225-235 degrees C respectively.     

Viscosity behaviour and persistence length of sodium xanthan in aqueous sodium chloride

Zero-shear-rate intrinsic viscosities [eta] of sodium xanthan in aqueous NACl at 25 degrees C were determined for five samples ranging in weight- average molecular weight from 2 x 10(5) to 4 x 10(6) at salt concentrations Cs between 0.005 and 1 M, at which the polysaccharide maintains its double-helical structure. The measured [eta] for every sample was almost independent of Cs, in contrast to usual observations on flexible polyelectrolytes. The persistence length q of sodium xanthan was determined as a function of Cs by use of the theory of Yamakawa et al. for [eta] of an unperturbed worm-like cylinder, and from its Cs dependence the intrinsic persistence length q(o) ( = q at infinite ionic strength) was estimated to be 106 nm. This q(o) value was roughly twice as large as that of double-stranded DNA, indicating a high intrinsic rigidity of the xanthan double helix. The electrostatic contribution ( = q - q(o)) to q was only about 10% even at the lowest Cs of 0.005 M. Thus, it was concluded that above Cs = 0.005 M, the double- helical structure of sodium xanthan is hardly stiffened by electrostatic interactions between charged groups.     

Inhibition of sodium for sodium exchange by phlorizin in frog sartorius muscle

The effects of phlorizin (2 X 10(-3) mol X l-1) on the Na transport of frog (Rana esculenta) sartorius muscle were investigated in glucose-free medium. Phlorizin decreased the rate coefficient of 24Na efflux by about 40%. The degree of inhibition was comparable to that caused by ouabain (10(-4) mol X l-1). Phlorizin could evoke a further reduction in the 24Na efflux also in the presence of ouabain. The intracellular Na content of the phlorizin-treated muscles remained unchanged, in contrast to a 60% increase induced by ouabain. 42K uptake was not affected by phlorizin. Data indicate that the ouabain-sensitive Na-K pump was not involved in the action of phlorizin. At the same time, phlorizin failed to alter the residual 24Na efflux measured in Li-Ringer solution containing ouabain. When Na: Na exchange was restored by replacing Na into the washout solution in the presence of ouabain, the increase of 24Na efflux was significantly diminished by phlorizin. Phlorizin reduced the 24Na uptake into a compartment with a half time of 6 min by about 40% without affecting the intracellular compartment. The results suggest that phlorizin inhibits the ouabain-insensitive Na: Na exchange in a superficial Na compartment.