Heat capacity changes upon burial of polar and nonpolar groups in proteins

In this paper we address the question of whether the burial of polar and nonpolar groups in the protein locale is indeed accompanied by the heat capacity changes, ΔCp, that have an opposite sign, negative for nonpolar groups and positive for polar groups. To accomplish this, we introduced amino acid substitutions at four fully buried positions of the ubiquitin molecule (Val5, Val17, Leu67, and Gln41). We substituted Val at positions 5 and 17 and Leu at position 67 with a polar residue, Asn. As a control, Ala was introduced at the same three positions. We also replaced the buried polar Gln41 with Val and Leu, nonpolar residues that have similar size and shape as Gln. As a control, Asn was introduced at Gln41 as well. The effects of these amino acid substitutions on the stability, and in particular, on the heat capacity change upon unfolding were measured using differential scanning calorimetry. The effect of the amino acid substitutions on the structure was also evaluated by comparing the 1H‐15N HSQC spectra of the ubiquitin variants. It was found that the Ala substitutions did not have a considerable effect on the heat capacity change upon unfolding. However, the substitutions of aliphatic side chains (Val or Leu) with a polar residue (Asn) lead to a significant (> 30%) decrease in the heat capacity change upon unfolding. The decrease in heat capacity changes does not appear to be the result of significant structural perturbations as seen from the HSQC spectra of the variants. The substitution of a buried polar residue (Gln41) to a nonpolar residue (Leu or Val) leads to a significant (> 25%) increase in heat capacity change upon unfolding. These results indicate that indeed the heat capacity change of burial of polar and nonpolar groups has an opposite sign. However, the observed changes in ΔCp are several times larger than those predicted, based on the changes in water accessible surface area upon substitution.

[1]  C. Pace,et al.  Denaturant m values and heat capacity changes: Relation to changes in accessible surface areas of protein unfolding , 1995, Protein science : a publication of the Protein Society.

[2]  R. Jernigan,et al.  Solvent effect on binding thermodynamics of biopolymers , 1990, Biopolymers.

[3]  J. Ladbury,et al.  Water mediated protein‐DNA interactions: The relationship of thermodynamics to structural detail , 1996, Protein science : a publication of the Protein Society.

[4]  W. Kauzmann Some factors in the interpretation of protein denaturation. , 1959, Advances in protein chemistry.

[5]  S. T. Thomas,et al.  Heat capacity change for ribonuclease A folding , 1999, Protein science : a publication of the Protein Society.

[6]  F. Neidhardt,et al.  Culture Medium for Enterobacteria , 1974, Journal of bacteriology.

[7]  S. Brown,et al.  Sequential 1H NMR assignments and secondary structure identification of human ubiquitin. , 1987, Biochemistry.

[8]  E. Lattman,et al.  High apparent dielectric constants in the interior of a protein reflect water penetration. , 2000, Biophysical journal.

[9]  G. Makhatadze,et al.  Anion binding to the ubiquitin molecule , 1998, Protein science : a publication of the Protein Society.

[10]  P. Privalov,et al.  Energetics of protein structure. , 1995, Advances in protein chemistry.

[11]  A M Lesk,et al.  Interior and surface of monomeric proteins. , 1987, Journal of molecular biology.

[12]  R. S. Spolar,et al.  Use of liquid hydrocarbon and amide transfer data to estimate contributions to thermodynamic functions of protein folding from the removal of nonpolar and polar surface from water. , 1992, Biochemistry.

[13]  S. T. Thomas,et al.  Contribution of the 30/36 hydrophobic contact at the C-terminus of the alpha-helix to the stability of the ubiquitin molecule. , 2000, Biochemistry.

[14]  Y. Yamagata,et al.  Contribution of the hydrophobic effect to the stability of human lysozyme: calorimetric studies and X-ray structural analyses of the nine valine to alanine mutants. , 1997, Biochemistry.

[15]  G. Hummer,et al.  Water penetration and escape in proteins , 2000, Proteins.

[16]  G. Makhatadze,et al.  Engineering a thermostable protein via optimization of charge-charge interactions on the protein surface. , 1999, Biochemistry.

[17]  Hans J. Vogel,et al.  Energetics of Target Peptide Binding by Calmodulin Reveals Different Modes of Binding* , 2001, The Journal of Biological Chemistry.

[18]  K. Dill,et al.  Thermal stabilities of globular proteins. , 1989, Biochemistry.

[19]  D. Woolfson,et al.  Protein folding in the absence of the solvent ordering contribution to the hydrophobic interaction. , 1993, Journal of molecular biology.

[20]  A. Ben-Naim Solvent effects on protein association and protein folding , 1990, Biopolymers.

[21]  B Honig,et al.  Analysis of the heat capacity dependence of protein folding. , 1992, Journal of molecular biology.

[22]  B. Matthews,et al.  Structural and genetic analysis of the folding and function of T4 lysozyme , 1996, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[23]  G. Makhatadze Heat capacities of amino acids, peptides and proteins. , 1998, Biophysical chemistry.

[24]  R. L. Baldwin,et al.  Temperature dependence of the hydrophobic interaction in protein folding. , 1986, Proceedings of the National Academy of Sciences of the United States of America.

[25]  K. Sharp,et al.  Heat Capacity Changes Accompanying Hydrophobic and Ionic Solvation: A Monte-Carlo and Random Network Model Study , 2001 .

[26]  D. M. Schneider,et al.  Fast internal main-chain dynamics of human ubiquitin. , 1992, Biochemistry.

[27]  R. S. Spolar,et al.  Hydrophobic effect in protein folding and other noncovalent processes involving proteins. , 1989, Proceedings of the National Academy of Sciences of the United States of America.

[28]  A M Gronenborn,et al.  Disordered water within a hydrophobic protein cavity visualized by x-ray crystallography. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[29]  J M Sturtevant,et al.  Heat capacity and entropy changes in processes involving proteins. , 1977, Proceedings of the National Academy of Sciences of the United States of America.

[30]  K. P. Murphy,et al.  Solid model compounds and the thermodynamics of protein unfolding. , 1991, Journal of molecular biology.

[31]  J. Edsall Apparent Molal Heat Capacities of Amino Acids and Other Organic Compounds , 1935 .

[32]  G. A. Lazar,et al.  De novo design of the hydrophobic core of ubiquitin , 1997, Protein science : a publication of the Protein Society.

[33]  James O. Wrabl,et al.  A model of the changes in denatured state structure underlying m value effects in staphylococcal nuclease , 1999, Nature Structural Biology.

[34]  C. Woodward,et al.  Crevice‐forming mutants of bovine pancreatic trypsin inhibitor: Stability changes and new hydrophobic surface , 1993, Protein science : a publication of the Protein Society.

[35]  P. Privalov,et al.  Contribution of hydration to protein folding thermodynamics. I. The enthalpy of hydration. , 1993, Journal of molecular biology.

[36]  Y. Kao,et al.  1H and 15N NMR assignments of PsaE, a photosystem I subunit from the cyanobacterium Synechococcus sp. strain PCC 7002. , 1994, Biochemistry.

[37]  Y. Yamagata,et al.  Contribution of intra- and intermolecular hydrogen bonds to the conformational stability of human lysozyme(,). , 1999, Biochemistry.

[38]  Andrew D. Robertson,et al.  Protein Structure and the Energetics of Protein Stability. , 1997, Chemical reviews.

[39]  W E Stites,et al.  In a staphylococcal nuclease mutant the side-chain of a lysine replacing valine 66 is fully buried in the hydrophobic core. , 1991, Journal of molecular biology.

[40]  G. Makhatadze,et al.  To charge or not to charge? , 2001, Trends in biotechnology.

[41]  P. Privalov,et al.  Stability of protein structure and hydrophobic interaction. , 1988, Advances in protein chemistry.

[42]  P. Privalov,et al.  Thermodynamics of ubiquitin unfolding , 1994, Proteins.

[43]  B. Matthews,et al.  Studies on protein stability with T4 lysozyme. , 1995, Advances in protein chemistry.

[44]  Y. Yamagata,et al.  Contribution of hydrogen bonds to the conformational stability of human lysozyme: calorimetry and X-ray analysis of six tyrosine --> phenylalanine mutants. , 1998, Biochemistry.

[45]  G. Drobny,et al.  Fourier transform multiple quantum nuclear magnetic resonance , 1978 .

[46]  P. Privalov,et al.  A thermodynamic approach to the problem of stabilization of globular protein structure: a calorimetric study. , 1974, Journal of molecular biology.

[47]  B. Matthews,et al.  Structural and genetic analysis of protein stability. , 1993, Annual review of biochemistry.

[48]  K. Sharp,et al.  Molecular Origin of Hydration Heat Capacity Changes of Hydrophobic Solutes: Perturbation of Water Structure around Alkanes , 1997 .

[49]  K. P. Murphy,et al.  Thermodynamics of structural stability and cooperative folding behavior in proteins. , 1992, Advances in protein chemistry.

[50]  R M Jackson,et al.  Comparison of binding energies of SrcSH2‐phosphotyrosyl peptides with structure‐based prediction using surface area based empirical parameterization , 2000, Protein science : a publication of the Protein Society.

[51]  A. Gronenborn,et al.  Solvent isotope effect and protein stability , 1995, Nature Structural Biology.

[52]  C. Chothia,et al.  The Packing Density in Proteins: Standard Radii and Volumes , 1999 .

[53]  J. Lecomte,et al.  Design challenges for hemoproteins: the solution structure of apocytochrome b5. , 1996, Biochemistry.

[54]  P. Privalov,et al.  Heat capacity of proteins. I. Partial molar heat capacity of individual amino acid residues in aqueous solution: hydration effect. , 1990, Journal of molecular biology.

[55]  Tina M. Hay To Charge or Not to Charge. , 1989 .

[56]  G. Makhatadze Measuring Protein Thermostability by Differential Scanning Calorimetry , 1998, Current protocols in protein science.

[57]  V. Saudek,et al.  Gradient-tailored excitation for single-quantum NMR spectroscopy of aqueous solutions , 1992, Journal of biomolecular NMR.

[58]  P. Privalov,et al.  Contribution of hydration and non-covalent interactions to the heat capacity effect on protein unfolding. , 1992, Journal of molecular biology.

[59]  K. Sharp,et al.  Hydrophobic Effect, Water Structure, and Heat Capacity Changes , 1997 .

[60]  L. Regan,et al.  Dramatic structural and thermodynamic consequences of repacking a protein's hydrophobic core. , 2000, Structure.

[61]  K. Sharp,et al.  Electrostatic contributions to heat capacity changes of DNA-ligand binding. , 1998, Biophysical journal.