Contribution of the surface free energy perturbation to protein-solvent interactions.

Surface tension measurements were carried out at 20 degrees C by a capillary drop-weight method on aqueous solutions of sodium glutamate (NaGlu), lysine hydrochloride (LysHCl), potassium aspartate (KAsp), arginine hydrochloride (ArgHCl), lysylglutamate (LysGlu), argininylglutamate (ArgGlu), guanidinium sulfate, trehalose, trimethylamine N-oxide (TMAO), dimethyl sulfoxide, 2-methyl-2,4-pentanediol (hexylene glycol), and poly(ethylene glycol)s of molecular weights 200, 400, 600, and 1000. All of the salts and the sugar increased the surface tension of water, while the last four compounds decreased it, with 2-methyl-2,4-pentanediol lowering it most effectively and TMAO being the least effective. The preferential hydration of bovine serum albumin (BSA) and lysozyme was measured in KAsp, ArgHCl, LysGlu, and ArgGlu. The high values of preferential hydration found in all cases, except for BSA in ArgHCl, suggest that they should stabilize protein structure, as had been found for lysine hydrochloride and monosodium glutamate [Arakawa, T., & Timasheff, S. N. (1984) J. Biol. Chem. 259, 4979-4986]. A correlation was found for both BSA and lysozyme in KAsp, NaGlu, LysHCl, ArgGlu, and LysGlu between the surface tension effect and the observed preferential interactions, indicating that the change in the surface free energy of the protein-containing cavity due to the surface tension increase for water by these amino acid salts contributes dominantly to the observed increase in the chemical potential of the protein by their addition. The lack of a correlation observed for BSA, but not lysozyme, in ArgHCl at low concentrations where preferential binding is close to zero suggests, however, that the surface tension effect is not the sole factor involved in the protein-solvent interactions in these amino acid salts. Binding of ArgHCl to BSA, probably through hydrogen bonds between the Arg guanidinium group and peptide bonds, was proposed to occur, the affinity of Arg+ being reduced by electrostatic repulsion when proteins carry a net positive charge, such as is the case with lysozyme. Since the four organic solvent additives also lead to protein preferential hydration, no correlation exists between their preferential interactions and the surface free energy perturbation. Therefore, in their case, the preferential hydration must be ascribed to other factors that overcome the preferential binding expected from the Gibbs adsorption isotherm. The surface tension results, however, are consistent with the binding of the organic solvents to proteins through hydrophobic interactions, explaining, at least in part, the observed concentration dependence of the interactions.

[1]  T. Arakawa,et al.  Protein stabilization and destabilization by guanidinium salts. , 1984, Biochemistry.

[2]  H. Eisenberg,et al.  Bovine serum albumin and aqueous guanidine hydrochloride solutions. Preferential and absolute interactions and comparison with other systems. , 1977, Biochemistry.

[3]  J. Pappenheimer,et al.  The Surface Tension of Aqueous Solutions of Dipolar Ions , 1936 .

[4]  C. Tanford,et al.  Hydrogen ion titration curve of lysozyme in 6 M guanidine hydrochloride. , 1971, Biochemistry.

[5]  T. Lin,et al.  Why do some organisms use a urea-methylamine mixture as osmolyte? Thermodynamic compensation of urea and trimethylamine N-oxide interactions with protein. , 1994, Biochemistry.

[6]  Serge N. Timasheff,et al.  Preferential interactions determine protein solubility in three-component solutions: the magnesium chloride system , 1990 .

[7]  S. N. Timasheff,et al.  Interaction of ribonuclease A with aqueous 2-methyl-2,4-pentanediol at pH 5.8. , 1978, Biochemistry.

[8]  P. Schimmel,et al.  An Investigation of Water-Urea and Water-Urea-Polyethylene Glycol Interactions , 1967 .

[9]  W. Stockmayer Light Scattering in Multi‐Component Systems , 1950 .

[10]  T. Arakawa,et al.  Mechanism of protein salting in and salting out by divalent cation salts: balance between hydration and salt binding. , 1984, Biochemistry.

[11]  M. A. Lauffer,et al.  The hydration, size and shape of tobacco mosaic virus. , 1949, Journal of the American Chemical Society.

[12]  W. D. Harkins,et al.  THE DROP WEIGHT METHOD FOR THE DETERMINATION OF SURFACE TENSION.2 (SURFACE TENSION I.) , 1916 .

[13]  S. N. Timasheff,et al.  Preferential solvation of bovine serum albumin in aqueous guanidine hydrochloride. , 1967, The Journal of biological chemistry.

[14]  K. Sharp,et al.  Protein folding and association: Insights from the interfacial and thermodynamic properties of hydrocarbons , 1991, Proteins.

[15]  R. Hofer-Warbinek,et al.  Complete amino acid sequence of beta-tubulin from porcine brain. , 1981, Proceedings of the National Academy of Sciences of the United States of America.

[16]  H. Eisenberg,et al.  Halophilic proteins and the influence of solvent on protein stabilization. , 1990, Trends in biochemical sciences.

[17]  S. N. Timasheff,et al.  The extrapolation of light-scattering data to zero concentration. , 1959, Archives of biochemistry and biophysics.

[18]  S. N. Timasheff,et al.  Interactions of proteins with solvent components in 8 M urea. , 1981, Archives of biochemistry and biophysics.

[19]  C. Horváth,et al.  Salt effect on hydrophobic interactions in precipitation and chromatography of proteins: an interpretation of the lyotropic series. , 1977, Archives of biochemistry and biophysics.

[20]  C. Tanford,et al.  The solubility of amino acids, diglycine, and triglycine in aqueous guanidine hydrochloride solutions. , 1970, The Journal of biological chemistry.

[21]  G. Alderton,et al.  ISOLATION OF LYSOZYME FROM EGG WHITE , 1945 .

[22]  W. Jencks,et al.  THE EFFECT OF COMPOUNDS OF THE UREA-GUANIDINIUM CLASS ON THE ACTIVITY COEFFICIENT OF ACETYLTETRAGLYCINE ETHYL ESTER AND RELATED COMPOUNDS. , 1965, Journal of the American Chemical Society.

[23]  S. Abdulnur,et al.  HYDROPHOBIC STACKING OF BASES AND THE SOLVENT DENATURATION OF DNA * , 1964 .

[24]  S. N. Timasheff,et al.  The use of small-angle x-ray scattering to determine protein conformation. , 1971, Journal of Agricultural and Food Chemistry.

[25]  H. Bull,et al.  Protein hydration. II. Specific heat of egg albumin. , 1968, Archives of biochemistry and biophysics.

[26]  R. Bhat,et al.  Steric exclusion is the principal source of the preferential hydration of proteins in the presence of polyethylene glycols , 1992, Protein science : a publication of the Protein Society.

[27]  T. Arakawa,et al.  Why preferential hydration does not always stabilize the native structure of globular proteins. , 1990, Biochemistry.

[28]  I. Kuntz,et al.  Hydration of proteins and polypeptides. , 1974, Advances in protein chemistry.

[29]  J. Schellman The thermodynamic stability of proteins. , 1987, Annual review of biophysics and biophysical chemistry.

[30]  T. Halicioǧlu,et al.  SOLVENT EFFECTS ON CIS‐TRANS AZOBENZENE ISOMERIZATION: A DETAILED APPLICATION OF A THEORY OF SOLVENT EFFECTS ON MOLECULAR ASSOCIATION * , 1969 .

[31]  H. Bull,et al.  Surface tension of amino acid solutions: a hydrophobicity scale of the amino acid residues. , 1974, Archives of biochemistry and biophysics.

[32]  E. P. Pittz,et al.  Studies on bovine pancreatic ribonuclease A and model compounds in aqueous 2-methyl-2,4-pentanediol. I. Amino acid solubility, thermal reversibility of ribonuclease A, and preferential hydration of ribonuclease A crystals. , 1971, Archives of biochemistry and biophysics.

[33]  T. Arakawa,et al.  Theory of protein solubility. , 1985, Methods in enzymology.

[34]  T. Arakawa,et al.  Preferential interactions of proteins with solvent components in aqueous amino acid solutions. , 1983, Archives of biochemistry and biophysics.

[35]  S. N. Timasheff Water as ligand: preferential binding and exclusion of denaturants in protein unfolding. , 1992, Biochemistry.

[36]  S. N. Timasheff,et al.  The control of protein stability and association by weak interactions with water: how do solvents affect these processes? , 1993, Annual review of biophysics and biomolecular structure.

[37]  K. Gekko,et al.  Mechanism of protein stabilization by glycerol: preferential hydration in glycerol-water mixtures. , 1981, Biochemistry.

[38]  J. Lee,et al.  Preferential solvent interactions between proteins and polyethylene glycols. , 1981, The Journal of biological chemistry.

[39]  P. V. von Hippel,et al.  On the conformational stability of globular proteins. The effects of various electrolytes and nonelectrolytes on the thermal ribonuclease transition. , 1965, The Journal of biological chemistry.

[40]  Serge N. Timasheff,et al.  Abnormal solubility behavior of .beta.-lactoglobulin: salting-in by glycine and sodium chloride , 1987 .

[41]  J. Lee,et al.  The stabilization of proteins by sucrose. , 1981, The Journal of biological chemistry.

[42]  V. Luzzati,et al.  La structure de la sérum albumine de boeuf en solution à pH 5,3 et 3,6: Étude par diffusion centrale absolue des rayons X , 1961 .

[43]  A. McPherson,et al.  Crystallization of proteins from polyethylene glycol. , 1976, The Journal of biological chemistry.

[44]  B Honig,et al.  Reconciling the magnitude of the microscopic and macroscopic hydrophobic effects. , 1991, Science.

[45]  G. Scatchard,et al.  Physical chemistry of protein solutions; derivation of the equations for the osmotic pressure. , 1946, Journal of the American Chemical Society.

[46]  T. Arakawa,et al.  Mechanism of poly(ethylene glycol) interaction with proteins. , 1985, Biochemistry.

[47]  D. Harker,et al.  Crystalline forms of bovine pancreatic ribonuclease: techniques of preparation, unit cells, and space groups , 1956 .

[48]  J. Lee,et al.  Partial specific volumes and interactions with solvent components of proteins in guanidine hydrochloride. , 1974, Biochemistry.

[49]  H. Eisenberg,et al.  THERMODYNAMIC ANALYSIS OF MULTICOMPONENT SOLUTIONS. , 1964, Advances in protein chemistry.

[50]  Irwin D. Kuntz,et al.  Hydration of macromolecules. III. Hydration of polypeptides , 1971 .

[51]  J. Lee,et al.  Interaction of calf brain tubulin with poly(ethylene glycols). , 1979, Biochemistry.

[52]  H. Ponstingl,et al.  Complete amino acid sequence of alpha-tubulin from porcine brain. , 1981, Proceedings of the National Academy of Sciences of the United States of America.

[53]  K. Gekko,et al.  Thermodynamic and kinetic examination of protein stabilization by glycerol. , 1981, Biochemistry.

[54]  T. Arakawa,et al.  Stabilization of protein structure by sugars. , 1982, Biochemistry.

[55]  R. Breslow,et al.  Surface tension measurements show that chaotropic salting-in denaturants are not just water-structure breakers. , 1990, Proceedings of the National Academy of Sciences of the United States of America.

[56]  S. N. Timasheff,et al.  Preferential and absolute interactions of solvent components with proteins in mixed solvent systems , 1972, Biopolymers.

[57]  T. Arakawa,et al.  The mechanism of action of Na glutamate, lysine HCl, and piperazine-N,N'-bis(2-ethanesulfonic acid) in the stabilization of tubulin and microtubule formation. , 1984, The Journal of biological chemistry.

[58]  J. Kirkwood,et al.  Light Scattering Arising from Composition Fluctuations in Multi‐Component Systems , 1950 .

[59]  William D. Harkins,et al.  THE DETERMINATION OF SURFACE TENSION (FREE SURFACE ENERGY), AND THE WEIGHT OF FALLING DROPS: THE SURFACE TENSION OF WATER AND BENZENE BY THE CAPILLARY HEIGHT METHOD. , 1919 .

[60]  J. Lee,et al.  Measurements of preferential solvent interactions by densimetric techniques. , 1979, Methods in enzymology.

[61]  H. Eisenberg,et al.  Structure and activity of malate dehydrogenase from the extreme halophilic bacteria of the Dead Sea. 1. Conformation and interaction with water and salt between 5 M and 1 M NaCl concentration. , 1981, European journal of biochemistry.

[62]  T. Arakawa,et al.  Preferential interactions of proteins with salts in concentrated solutions. , 1982, Biochemistry.