Hydrophobic interaction chromatography of proteins. II. Solution thermodynamic properties as a determinant of retention.

A general thermodynamic relation was derived to correlate protein solubility to retention in hydrophobic interaction chromatography (HIC). This relation is built on a thermodynamic formulation presented previously by Melander, Horváth and co-workers in the context of the solvophobic theory, but the final result is independent of this model framework. The relation reflects an increase in protein retention in HIC under conditions that promote precipitation or crystallization, consistent with early descriptions of HIC. To examine the contribution of protein solubility to retention in HIC, isocratic elution experiments were performed with four different commercially available agarose media and four model proteins (ribonuclease A (RNA), lysozyme (LYS), myoglobin (MYO), and ovalbumin (OVA)). A wide variety of retention trends were observed as a function of protein, adsorbent type, salt type and concentration, and pH. In general, however, the results show that solubility, or its surrogate, the second osmotic virial coefficient, which reflects solution thermodynamic properties, correlates well with HIC retention in many cases; this includes correctly predicting reverse Hofmeister effects, which cannot be explained by retention models based on the solvophobic theory and preferential interaction theory. However, solution properties could not explain retention behavior under some conditions. In those cases, effects such as protein-surface interactions or conformational change could be important determinants of protein adsorption.

[1]  M T Hearn,et al.  Microcalorimetric studies on the interaction mechanism between proteins and hydrophobic solid surfaces in hydrophobic interaction chromatography: effects of salts, hydrophobicity of the sorbent, and structure of the protein. , 2001, Analytical chemistry.

[2]  A. Sarvazyan,et al.  Hydrational and intrinsic compressibilities of globular proteins , 1993, Biopolymers.

[3]  C. Horváth,et al.  Protein surface area and retention in hydrophobic interaction chromatography , 1987 .

[4]  K. D. Collins,et al.  The Hofmeister effect and the behaviour of water at interfaces , 1985, Quarterly Reviews of Biophysics.

[5]  A. Lyddiatt,et al.  On the use of mild hydrophobic interaction chromatography for “method scouting” protein purification strategies in aqueous two‐phase systems: A study using model proteins , 1994, Biotechnology and bioengineering.

[6]  C. Horváth,et al.  Interplay of hydrophobic and electrostatic interactions in biopolymer chromatography. Effect of salts on the retention of proteins. , 1989, Journal of chromatography.

[7]  S. Berkowitz,et al.  Use of high-performance hydrophobic interaction chromatography for the determination of salting-out conditions of proteins. , 1987, Journal of Chromatography A.

[8]  A. Lenhoff,et al.  A consistent experimental and modeling approach to light-scattering studies of protein-protein interactions in solution. , 2005, Biophysical journal.

[9]  K. Gekko,et al.  Compressibility-structure relationship of globular proteins. , 1986, Biochemistry.

[10]  W. William Wilson,et al.  Correlation of second virial coefficients and solubilities useful in protein crystal growth , 1999 .

[11]  K. Higashitani,et al.  Circular dichroism studies on conformational changes in protein molecules upon adsorption on ultrafine polystyrene particles , 1992, Biotechnology and bioengineering.

[12]  A. Kondo,et al.  Structural changes in protein molecules adsorbed on ultrafine silica particles , 1991 .

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

[14]  T. Arakawa,et al.  Mechanism of protein precipitation and stabilization by co-solvents , 1988 .

[15]  T. Arakawa,et al.  Thermodynamic analysis of the effect of concentrated salts on protein interaction with hydrophobic and polysaccharide columns. , 1986, Archives of biochemistry and biophysics.

[16]  Z Dauter,et al.  Anomalous signal of solvent bromides used for phasing of lysozyme. , 1999, Journal of molecular biology.

[17]  E. J. Fernandez,et al.  Hydrophobic interaction chromatography selectivity changes among three stable proteins: conformation does not play a major role , 2004, Biotechnology and bioengineering.

[18]  S. Sandler,et al.  Predictive crystallization of ribonuclease A via rapid screening of osmotic second virial coefficients , 2002, Proteins.

[19]  W. William Wilson,et al.  Relation between the solubility of proteins in aqueous solutions and the second virial coefficient of the solution , 1999 .

[20]  R Abagyan,et al.  The hydration of globular proteins as derived from volume and compressibility measurements: cross correlating thermodynamic and structural data. , 1996, Journal of molecular biology.

[21]  K. P. Murphy,et al.  Common features of protein unfolding and dissolution of hydrophobic compounds. , 1990, Science.

[22]  G. W. Hatfield,et al.  Phosphate-Induced Protein Chromatography , 1973, Science.

[23]  W. Norde,et al.  Adsorption of proteins from solution at the solid-liquid interface. , 1986, Advances in colloid and interface science.

[24]  W. Y. Chen,et al.  Microcalorimetric studies of interactions between proteins and hydrophobic ligands in hydrophobic interaction chromatography: effects of ligand chain length, density and the amount of bound protein. , 2000, Journal of chromatography. A.

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

[26]  Tara Tibbs Jones,et al.  Alpha-lactalbumin tertiary structure changes on hydrophobic interaction chromatography surfaces. , 2003, Journal of colloid and interface science.

[27]  Abraham M Lenhoff,et al.  Hydrophobic interaction chromatography of proteins. I. The effects of protein and adsorbent properties on retention and recovery. , 2007, Journal of chromatography. A.

[28]  A. Powers,et al.  Evaluation of microcapsule permeability via inverse size exclusion chromatography. , 1996, Analytical biochemistry.

[29]  Carol Beth Post,et al.  Adhesive–cohesive model for protein compressibility: An alternative perspective on stability , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[30]  A. Ducruix,et al.  Relative effectiveness of various ions on the solubility and crystal growth of lysozyme. , 1989, The Journal of biological chemistry.

[31]  C. Horváth,et al.  Retention thermodynamics in hydrophobic interaction chromatography , 1996 .

[32]  X. Geng,et al.  Study of the retention mechanism of proteins in hydrophobic interaction chromatography , 1990 .

[33]  Abraham M. Lenhoff,et al.  Electrostatic and van der Waals contributions to protein adsorption: computation of equilibrium constants , 1993 .

[34]  J A Asenjo,et al.  Effect of surface hydrophobicity distribution on retention of ribonucleases in hydrophobic interaction chromatography. , 2004, Journal of chromatography. A.

[35]  E. T. White,et al.  Solubility of ovalbumin in ammonium sulfate solutions , 1996 .

[36]  Abraham M Lenhoff,et al.  Self-interaction chromatography: a novel screening method for rational protein crystallization. , 2002, Acta crystallographica. Section D, Biological crystallography.

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

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

[39]  S. Sandler,et al.  Correlation between the Osmotic Second Virial Coefficient and the Solubility of Proteins , 2001, Biotechnology progress.

[40]  Kristen Demoruelle,et al.  Correlation between the osmotic second virial coefficient and solubility for equine serum albumin and ovalbumin. , 2002, Acta crystallographica. Section D, Biological crystallography.

[41]  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.

[42]  J. Prausnitz,et al.  Protein-protein interactions in concentrated electrolyte solutions: Hofmeister-series effects , 2002 .

[43]  J. Mollerup,et al.  Solute retention of lysozyme in hydrophobic interaction perfusion chromatography , 1996 .

[44]  Kinam Park,et al.  Effect of surface hydrophobicity on the conformational changes of adsorbed fibrinogen , 1991 .

[45]  J. Prausnitz,et al.  Lysozyme Net Charge and Ion Binding in Concentrated Aqueous Electrolyte Solutions , 1999 .

[46]  T. L. Hill,et al.  An Introduction to Statistical Thermodynamics , 1960 .

[47]  C. Horváth,et al.  Salt-mediated retention of proteins in hydrophobic-interaction chromatography. Application of solvophobic theory. , 1984, Journal of chromatography.

[48]  O. Velev,et al.  Protein interactions in solution characterized by light and neutron scattering: comparison of lysozyme and chymotrypsinogen. , 1998, Biophysical journal.

[49]  D. Winzor,et al.  Negative second virial coefficients as predictors of protein crystal growth: evidence from sedimentation equilibrium studies that refutes the designation of those light scattering parameters as osmotic virial coefficients. , 2006, Biophysical chemistry.

[50]  Abraham M Lenhoff,et al.  Rapid measurement of protein osmotic second virial coefficients by self-interaction chromatography. , 2002, Biophysical journal.

[51]  T. Root,et al.  Protein retention in hydrophobic interaction chromatography: modeling variation with buffer ionic strength and column hydrophobicity , 1997 .

[52]  G. Doellgast,et al.  Hemoglobin & serum albumin: salt-mediated hydrophobic chromatography. , 1975, Biochemical and biophysical research communications.

[53]  A. Lenhoff,et al.  Measurements of protein self-association as a guide to crystallization. , 2003, Current opinion in biotechnology.

[54]  G. Guiochon,et al.  Theoretical advancement in chromatography and related separation techniques , 1992 .

[55]  F. Regnier,et al.  Comparison of hydrophobic-interaction and reversed-phase chromatography of proteins. , 1984, Journal of chromatography.

[56]  C. Shepard,et al.  The chromatography of proteins. The effect of salt concentration and pH on the adsorption of proteins to silica gel , 1949 .

[57]  B. Karger,et al.  Protein conformational effect in hydrophobic interaction chromatography , 1986 .

[58]  C. Horváth,et al.  Solvophobic interactions in liquid chromatography with nonpolar stationary phases , 1976 .

[59]  K. B. Morris Principles of Chemical Equilibrium , 1965 .

[60]  Y. Sakai,et al.  Moment analysis of retention equilibrium, mass transfer kinetics, and thermodynamic properties in reversed-phase liquid chromatography using phenyl bonded silica gel. , 2003, The Analyst.

[61]  S. Cramer,et al.  Evaluation of selectivity changes in HIC systems using a preferential interaction based analysis , 2004, Biotechnology and bioengineering.

[62]  J. Prausnitz,et al.  Effect of alcohols on aqueous lysozyme-lysozyme interactions from static light-scattering measurements. , 2004, Biophysical chemistry.

[63]  J. Barker,et al.  High temperature adsorption and the determination of the surface area of solids , 1962 .

[64]  S. Hjertén,et al.  Hydrophobic interaction chromatography on uncharged Sepharose derivatives. Effects of neutral salts on the adsorption of proteins. , 1977 .

[65]  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.

[66]  J. Prausnitz,et al.  Protein—Protein Interactions in Aqueous Ammonium Sulfate Solutions. Lysozyme and Bovine Serum Albumin (BSA) , 2000 .