• Title of article

    Relationship between preferential interaction of a protein in an aqueous mixed solvent and its solubility Original Research Article

  • Author/Authors

    Ivan L. Shulgin، نويسنده , , Eli Ruckenstein، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2005
  • Pages
    7
  • From page
    128
  • To page
    134
  • Abstract
    The present paper is devoted to the derivation of a relation between the preferential solvation of a protein in a binary aqueous solution and its solubility. The preferential binding parameter, which is a measure of the preferential solvation (or preferential hydration) is expressed in terms of the derivative of the protein activity coefficient with respect to the water mole fraction, the partial molar volume of protein at infinite dilution and some characteristics of the protein-free mixed solvent. This expression is used as the starting point in the derivation of a relationship between the preferential binding parameter and the solubility of a protein in a binary aqueous solution. The obtained expression is used in two different ways: (1) to produce a simple criterion for the salting-in or salting-out by various cosolvents on the protein solubility in water, (2) to derive equations which predict the solubility of a protein in a binary aqueous solution in terms of the preferential binding parameter. The solubilities of lysozyme in aqueous sodium chloride solutions (pH = 4.5 and 7.0), in aqueous sodium acetate (pH = 8.3) and in aqueous magnesium chloride (pH = 4.1) solutions are predicted in terms of the preferential binding parameter without any adjustable parameter. The results are compared with experiment, and for aqueous sodium chloride mixtures the agreement is excellent, for aqueous sodium acetate and magnesium chloride mixtures the agreement is only satisfactory.
  • Keywords
    protein , Solubility , Preferential binding parameter , Aqueous mixed solvent
  • Journal title
    Biophysical Chemistry
  • Serial Year
    2005
  • Journal title
    Biophysical Chemistry
  • Record number

    1113749