Simulations of the bis-penicillamine enkephalin in sodium chloride solution: a parameter study.

A simulation study of DPDPE in sodium chloride solution has been performed and compared with previous simulations using a different interaction potential for the ions. Both global thermodynamics as well as a characterization of association to DPDPE have been calculated. We show that the parameters used for the ions have a profound effect on the association to the peptide in 1M NaCl. The observed differences suggest that individual associations in these and previous simulations are sensitive to parameters.     

Molecular simulation study of structure and dynamical properties of nitrate anion in sodium chloride aqueous solution

The molecular dynamics simulations have been performed for the sodium nitrate solution at various concentrations in the 1.1 mol% sodium chloride aqueous solution, which is a model of the sea water. The structure, the velocity correlation functions and the frequency-dependent diffusion coefficients have been obtained. The share viscosity has also been obtained at various concentrations using the Green–Kubo formula, which agrees well with the experimental data. The complex formation and the microscopic charge neutrality in the solution have been discussed in relation to the ionic conductivity estimated by the Nernst–Einstein relation.     

Influence of sodium chloride on hydrophobic adsorption of PEGylated lysozyme

Interaction of macromolecules in aqueous salt‐containing solution with a hydrophobic adsorbent is studied by adsorption equilibrium measurements and by independent isothermal titration calorimetry. The macromolecules are native as well as mono‐, di‐, and tri‐PEGylated lysozyme and four pure PEGs. The hydrophobic adsorbent is Toyopearl PPG‐600M. The salt is sodium chloride. The sodium chloride concentration in the aqueous 25 mM sodium phosphate buffer is varied from 2000 to 4500 mM at pH 7.0 and 25°C. PEGylation of the lysozyme is carried using 5 and 10 kDa PEG chains. The molar enthalpy of adsorption is calculated from the adsorption equilibrium and the calorimetric data. The results show that the adsorption of the PEGylated lysozyme is caused by both the interaction of the lysozyme and the interaction of the PEG chains with the adsorbent, respectively, but the interaction of the lysozyme is stronger than that of PEG. The comparison of the results of the present study on the influence of sodium chloride with a corresponding study on the influence of ammonium sulfate shows that the adsorption mechanism changes upon the variation of the salt. The knowledge of the adsorption mechanisms supports the systematic development of chromatographic purification steps.     

Diffusion of lysozyme chloride in water and aqueous potassium chloride solutions.

The diffusion of lysozyme chloride in aqueous solution has been studied at 25 degrees C using the Goüy interferometric technique. The concentration dependence of the diffusion coefficient in water has been measured over the concentration range 1.1599-9.1556 gcm-3 and the results suggest a value of D 25, w at infinite dilution of 5.838 x 10(-6) cm2s-1. The variation in diffusion coefficient with ionic strength has also been considered by following the diffusion of 0.45% lysozyme chloride in a series of potassium chloride solutions. The value of D in 0.15 M KCl has been found to be approximately one quarter of that in water alone an the diffusion coefficient has been shown to increase markedly as the KCl concentration is reduced below 0.05 M. Interpretation of these observations involves consideration of solution electrostatic effects.     

Effect of sodium chloride on a lipid bilayer

Electrostatic interactions govern structural and dynamical properties of membranes and can vary considerably with the composition of the aqueous buffer. We studied the influence of sodium chloride on a pure POPC lipid bilayer by fluorescence correlation spectroscopy experiments and molecular dynamics simulations. Increasing sodium chloride concentration was found to decrease the self-diffusion of POPC lipids within the bilayer. Self-diffusion coefficients calculated from the 100 ns simulations agree with those measured on a millisecond timescale, suggesting that most of the relaxation processes relevant for lipid diffusion are faster than the simulation timescale. As the dominant effect, the molecular dynamics simulations revealed a tight binding of sodium ions to the carbonyl oxygens of on average three lipids leading to larger complexes with reduced mobility. Additionally, the bilayer thickens by approximately 2 A, which increases the order parameter of the fatty acyl chains. Sodium binding alters the electrostatic potential, which is largely compensated by a changed polarization of the aqueous medium and a lipid dipole reorientation.     

The recovery of transfer ribonucleic acid by binding to DEAE-cellulose induced by ammonium sulfate

tRNA samples may be adsorbed quantitatively to DEAE-cellulose from 2m ammonium sulfate solution, pH 4.5. Washing with 0.3 m NaCl removes the ammonium sulfate and the tRNA is recovered in ethanol-precipitable form by elution with 1.1 m NaCl. The procedure allows convenient and efficient recovery of tRNAs from larger volumes of aqueous salt solutions. A moderate concentration of sodium chloride does not interfere with adsorption.     

Effect of calcium chloride on the conformation of proteins. Thermodynamic studies of some model compounds

Partial molar heat capacities (CP2 degrees) and volumes (V2 degrees) for some amino acids and peptides were measured in 1 M aqueous calcium chloride solutions at 298.15 degrees K using a Picker flow microcalorimeter and an oscillating-tube digital density meter. Using the data for these amino acids and peptides in water, the corresponding partial molar heat capacities of transfer (CP2,tr degree) and volumes (V2,tr degree) from water to 1 M aqueous calcium chloride were deduced. These thermodynamic parameters are significantly positive, indicating that strong interactions occur between the ions of calcium chloride and the charged centres of these amino acids and peptides. A comparison has been made with a similar transfer of these compounds to sodium chloride solutions. The thermodynamic parameters of the transfer of peptide group (-CONH) are much more positive in calcium chloride than in sodium chloride solutions. The implication of this result for the ability of calcium chloride to act as a stronger destabilizer of protein conformation is discussed.     

Ammonium chloride: a novel effective and inexpensive salt solution for phycocyanin extraction from <Emphasis Type="BoldItalic">Arthrospira</Emphasis> (<Emphasis Type="BoldItalic">Spirulina</Emphasis>) <Emphasis Type="BoldItalic">platensis</Emphasis>

Phycocyanin, a blue pigment, is a type of phycobiliproteins. Because of its various potential properties, phycocyanin is applied to various fields, such as nutraceutical, pharmaceutical, medicine, cosmetics, and biotechnological research. The cost and application of phycocyanin are highly dependent on its purity index. In this study, ammonium chloride is presented as a novel, effective, and inexpensive salt for phycocyanin extraction. Compared with sodium phosphate, which is commonly used during phycocyanin extraction process, ammonium chloride solution efficiently extracted phycocyanin with high purity from Arthrospira platensis FACHB-314. In addition, ammonium phosphate solution is also presented as an alternative precipitation agent in phycocyanin purification that may replace the widely used ammonium sulfate. Statistical analysis shows that there is no significant difference in phycocyanin concentration between crude extracts (overall mean of 0.208 and 0.215 for extraction using sodium phosphate and ammonium chloride, respectively). However, the difference in phycocyanin purity ratio (A₆₂₀/A₂₈₀) between these two extractions is significant (overall mean of 0.742 and 1.428 for extraction using sodium phosphate and ammonium chloride, respectively). With ammonium chloride, the purity indexes of phycocyanin are 1.5 and 2.81 after the optimum extraction step, and precipitation used as the primary purification step, respectively. The present study describes a novel purification method to achieve phycocyanin with analytical grade without multiple purification steps.     

Conformation of xanthan dissolved in aqueous urea and sodium chloride solutions

Quasielastic light-scattering and other physical-chemical techniques have been used to compare the conformation and intermolecular interactions of xanthan in water, aqueous sodium chloride, and urea solutions. The results showed that xanthan dissolved in 4m urea has a disordered conformation after the solution has been maintained for 3 h at 95° and then cooled to room temperature. This conformation is similar to that previously observed only in solutions having low ionic strength at higher temperatures, following disruption of the ordered, low-temperature form. “Anomalous” behavior is seen for xanthan as a function of ionic strength, in that the hydrodynamic radius increases with increase in ionic strength, whereas a decrease is typical for polyelectrolytes. These observations suggest that aggregation of rod-like chains, similar to that seen for other stiff-chain polymers, occurs for xanthan in salt solutions, where the charged groups of the polyelectrolyte are screened by the salt ions. This aggregation may explain some of the high values reported in the literature for the molecular weight.     

Complex permittivity of sodium chloride solutions at microwave frequencies

The complex permittivity of aqueous solutions at 20 degrees C has been measured at concentrations between 0.001 and 5 mol/L and over a frequency range 0.13-20 GHz. The results were combined with literature values to derive empirical equations to predict the dielectric behavior of sodium chloride solutions between 0 and 5 mol/L and 5 degrees C-35 degrees C.     

Erythrocyte lysis in isotonic solution of ammonium chloride: theoretical modeling and experimental verification

A mathematical model of erythrocyte lysis in isotonic solution of ammonium chloride is presented in frames of a statistical approach. The model is used to evaluate several parameters of mature erythrocytes (volume, surface area, hemoglobin concentration, number of anionic exchangers on membrane, elasticity and critical tension of membrane) through their sphering and lysis measured by a scanning flow cytometer (SFC). SFC allows measuring the light-scattering pattern (indicatrix) of an individual cell over the angular range from 10° to 60°. Comparison of the experimentally measured and theoretically calculated light scattering patterns allows discrimination of spherical from non-spherical erythrocytes and evaluation of volume and hemoglobin concentration for individual spherical cells. Three different processes were applied for erythrocytes sphering: (1) colloid osmotic lysis in isotonic solution of ammonium chloride, (2) isovolumetric sphering in the presence of sodium dodecyl sulphate and albumin in neutrally buffered isotonic saline, and (3) osmotic fragility test in hypotonic media. For the hemolysis in ammonium chloride, the evolution of distributions of sphered erythrocytes on volume and hemoglobin content was monitored in real-time experiments. The analysis of experimental data was performed in the context of a statistical approach, taking into account that parameters of erythrocytes vary from cell to cell.     

Hydrophobic forces between protein molecules in aqueous solutions of concentrated electrolyte

Protein-protein interactions have been measured for a mutant (D101F) lysozyme and for native lysozyme in concentrated solutions of ammonium sulfate at pH 7 and sodium chloride at pH 4.5. In the mutant lysozyme, a surface aspartate residue has been replaced with a hydrophobic phenylalanine residue. The protein-protein interactions of D101F lysozyme are more attractive than those of native lysozyme for all conditions studied. The salt-induced attraction is correlated with a solvation potential of mean force given by the work required to desolvate the part of the protein surfaces that is buried by the protein-protein interaction. This work is proportional to the aqueous surface-tension increment of the salt and the fractional non-polar surface coverage of the protein. Experimental measurements of osmotic second virial coefficients validate a proposed potential of mean force that ascribes the salt-induced attraction between protein molecules to an enhancement of the hydrophobic attraction. This model provides a first approximation for predicting the protein-protein potential of mean force in concentrated aqueous electrolyte solutions; this potential is useful for determining solution conditions favorable for protein crystallization.     

Study of a lipopolysaccharide-protein complex from Yersinia pseudotuberculosis in aqueous solutions by light scattering

Lipopolysaccharide-protein complex isolated from Yersinia pseudotuberculosis forms aggregates in aqueous solutions. Dissociation of aggregates was found by light scattering method for 1 M sodium chloride, 1 M guanidine chloride, and urea solutions. Very large particles were detected also in these solutions and acid media. Little light scattering alterations have been observed for 0.27 g/l solution, and pronounced effect of temperature has been detected for more diluted solutions.     

Inhibition of epithelial chloride channels by a semi-purified fraction of Crotalus atrox venom

Rattlesnake venom has a strong effect on the ionic permeability of plasma membranes. Rattlesnake venom and one of its semipurified fractions (CAV-C2) has been implicated in affecting both sodium and chloride transfer across epithelia. The mechanism of CAV-C2 action on epithelia, however, is still open to question. Aplysia californica intestine has been shown to contain both chloride conductive channels and sodium dependent chloride uptake mechanisms in the mucosal membrane of its enterocytes which makes it an ideal model to differentiate the CAV-C2 action on either of these membrane transport processes. In the absence of sodium in the bathing medium, chloride is the only ion actively transported. CAV-C2 and piretanide have similar types of inhibitory effects on net chloride transport while furosemide had no effect on chloride movement across the intestine. It was concluded that CAV-C2 action is on chloride conductive channels located in the mucosal membrane of the enterocytes.     

Palladium chloride as a stain for elastin at the ultrastructural level.

Palladium chloride in aqueous solution stains elastic fibers in thin sections of Epon-embedded tissues. When palladium chloride is used with a lead citrate counterstain, high contrast sections with gray to black elastic fibers are obtained. The stain was tested on newborn and adult mammalian tissues and on adult tissues from lower animals. Sections were mounted on stainless steel grids, stained with 1% palladium chloride solution for 5 to 15 min, rinsed thoroughly, and counterstained with lead citrate for 7 min. Palladium chloride staining solution is stable for several months at room temperature and if the stain is filtered immediately before use, contamination of sections is not a problem. Chemical studies indicate that palladium binds directly to purified bovine ligamentum nuchae elastin and that this binding is not affected by glutaraldehyde fixation or by sodium borohydride reduction of elastin. Osmium post-fixation of glutaraldehyde-fixed elastin did significantly lower the amount of palladium bound. Palladium was shown to be chemically bound to sites on the elastin and not weakly associated. The nature of these sites is discussed.     

Influence of ammonium sulfate and sodium chloride on ethyl methanesulfonate-induced chromosomal aberrations and HPRT mutations in V79 hamster cells

V79 hamster cells were mutagenized with ethyl methanesulfonate (EMS) and immediately afterwards posttreated with hypertonic solutions of sodium chloride or ammonium sulfate. The posttreatment had a clear effect on chromosomal aberrations, but TGr mutations were only enhanced by ammonium sulfate, but not by sodium chloride posttreatment. It is suggested that hypertonic salt posttreatment leads to conformational changes in the DNA, resulting in an increase in TGr mutations and chromosomal aberrations.     

Hollandite as a Functional and Structural Model for the Biological Water Oxidizing Complex: Manganese-Calcium Oxide Minerals as a Possible Evolutionary Origin for the CaMn4 Cluster of the Biological Water Oxidizing Complex

Oxygen evolution was observed upon mixing either hollandite, which has been proposed as a structural model for the biological water oxidizing complex, or hausmannite with an aqueous solution of cerium (IV) ammonium nitrate. Oxygen evolution from water during irradiation with visible light (λ > 400 nm) was also observed upon adding either hollandite or hausmannite to an aqueous solution containing tris (2,2′-bipyridyl)ruthenium(II) chloride and chloro pentaammine cobalt(III) chloride in acetate buffer. These experiments showed that hollandite is a good catalyst for oxygen evolution in presence of cerium (IV) ammonium nitrate or tris (2,2′-bipyridyl)ruthenium (III). Thus, hollandite is not only a structural but also a functional model for the biological water oxidizing complex. Supplemental materials are available for this article. Go to the publisher's online edition of Geomicrobiology Journal to view the free supplemental file.     

Mid-infrared spectroscopic analysis of saccharides in aqueous solutions with sodium chloride

The infrared spectral characteristics of three different types of disaccharides (trehalose, maltose, and sucrose) and four different types of monosaccharides (glucose, mannose, galactose, and fructose) in aqueous solutions with sodium chloride (NaCl) were determined. The infrared spectra were obtained using the FT-IR/ATR method and the absorption intensities respected the interaction between the saccharide and water with NaCl were determined. This study also focused on not only the glycosidic linkage position and the constituent monosaccharides, but also the concentration of the saccharides and NaCl and found that they have a significant influence on the infrared spectroscopic characterization of the disaccharides in an aqueous solution with NaCl. The absorption intensities representing the interaction between a saccharide and water with NaCl were spectroscopically determined. Additionally, the applications of MIR spectroscopy to obtain information about saccharide–NaCl interactions in foods and biosystems were suggested.     

Action of sodium chloride on Yersinia pseudotuberculosis and Yersinia enterocolitica

The bacteriostatic and bactericidal action of sodium chloride on 60 Y. pseudotuberculosis strains, 75 Y. enterocolitica strains and 158 urine-fermenting strains has been studied. A new specific feature of Y. pseudotuberculosis has been revealed: high sensitivity to sodium chloride. The suitability of the sodium chloride test has been shown for the identification of Yersinia and the differentiation of Y. pseudotuberculosis and Y. enterocolitica.