Alpha-helix stability in proteins. I. Empirical correlations concerning substitution of side-chains at the N and C-caps and the replacement of alanine by glycine or serine at solvent-exposed surfaces.

The importance of amino acid side-chains in helix stability has been investigated by making a series of mutations at the N-caps, C-caps and internal positions of the solvent-exposed faces of the two alpha-helices of barnase. There is a strong positional and context dependence of the effect of a particular amino acid on stability. Correlations have been found that provide insight into the physical basis of helix stabilization. The relative effects of Ala and Gly (or Ser) may be rationalized on the basis of solvent-accessible surface areas: burial of hydrophobic surface stabilizes the protein as does exposure to solvent of unpaired hydrogen bond donors or acceptors in the protein. There is a good correlation between the relative stabilizing effects of Ala and Gly at internal positions with the total change in solvent-accessible hydrophobic surface area of the folded protein on mutation of Ala----Gly. The relationship may be extended to the N and C-caps by including an extra term in hydrophilic surface area for the solvent exposure of the non-intramolecularly hydrogen-bonded main-chain CO, NH or protein side-chain hydrogen bonding groups. The requirement for solvent exposure of the C-cap main-chain CO groups may account for the strong preference for residues having positive phi and psi angles at this position, since this alpha L-conformation results in the largest solvent exposure of the C-terminal CO groups. Glycine in an alpha L-conformation results in the greatest exposure of these CO groups. Further, the side-chains of His, Asn, Arg and Lys may, with positive phi and psi-angles, form a hydrogen bond with the backbone CO of residue in position C -3 (residues are numbered relative to the C-cap). The preferences at the C-cap are Gly much greater than His greater than Asn greater than Arg greater than Lys greater than Ala approximately Ser approximately greater than Asp. The preferences at the N-cap are determined by hydrogen bonding of side-chains or solvent to the exposed backbone NH groups and are: Thr approximately Asp approximately Ser greater than Gly approximately Asn greater than Gln approximately Glu approximately His greater than Ala greater than Val much greater than Pro. These general trends may be obscured when mutation allows another side-chain to become a surrogate cap.(ABSTRACT TRUNCATED AT 400 WORDS)

[1]  M. Levitt,et al.  Molecular dynamics of native protein. I. Computer simulation of trajectories. , 1983, Journal of molecular biology.

[2]  D E Tronrud,et al.  Contributions of left-handed helical residues to the structure and stability of bacteriophage T4 lysozyme. , 1990, Journal of molecular biology.

[3]  A. Fersht,et al.  Strength and co-operativity of contributions of surface salt bridges to protein stability. , 1990, Journal of molecular biology.

[4]  Three‐dimensional structure of ribonuclease from Bacillus intermedius 7P at 3.2 Å resolution , 1983, FEBS letters.

[5]  Harold A. Scheraga,et al.  Helix-coil stability constants for the naturally occurring amino acids in water. 22. Histidine parameters from random poly[(hydroxybutyl)glutamine-co-L-histidine] , 1984 .

[6]  R. L. Baldwin,et al.  Position effect on apparent helical propensities in the C-peptide helix. , 1991, Journal of molecular biology.

[7]  R. L. Baldwin,et al.  Straight-chain non-polar amino acids are good helix-formers in water. , 1991, Journal of molecular biology.

[8]  H. Scheraga,et al.  Helix‐coil stability constants for the naturally occurring amino acids in water. XXIV. Half‐cystine parameters from random poly(hydroxybutylglutamine‐CO‐S‐methylthio‐L‐cysteine) , 1990 .

[9]  William F. DeGrado,et al.  Induction of peptide conformation at apolar water interfaces. 1. A study with model peptides of defined hydrophobic periodicity , 1985 .

[10]  R. L. Baldwin,et al.  Effect of the substitution Ala----Gly at each of five residue positions in the C-peptide helix. , 1989, Biochemistry.

[11]  A. Fersht,et al.  Histidine-aromatic interactions in barnase. Elevation of histidine pKa and contribution to protein stability. , 1992, Journal of molecular biology.

[12]  C. Tanford,et al.  Empirical correlation between hydrophobic free energy and aqueous cavity surface area. , 1974, Proceedings of the National Academy of Sciences of the United States of America.

[13]  A. Shrake,et al.  Environment and exposure to solvent of protein atoms. Lysozyme and insulin. , 1973, Journal of molecular biology.

[14]  R. L. Baldwin,et al.  Large differences in the helix propensities of alanine and glycine , 1991, Nature.

[15]  A. Fersht,et al.  COSMIC analysis of the major α-helix of barnase during folding , 1991 .

[16]  James G. Boyd,et al.  The helical s constant for alanine in water derived from template-nucleated helices , 1991, Nature.

[17]  Robert L. Baldwin,et al.  Relative helix-forming tendencies of nonpolar amino acids , 1990, Nature.

[18]  S. Lifson,et al.  On the Theory of Helix—Coil Transition in Polypeptides , 1961 .

[19]  U. Sauer,et al.  Contributions of engineered surface salt bridges to the stability of T4 lysozyme determined by directed mutagenesis. , 1991, Biochemistry.

[20]  O. Ptitsyn,et al.  Physical reasons for secondary structure stability: α‐Helices in short peptides , 1991 .

[21]  J. Richardson,et al.  Amino acid preferences for specific locations at the ends of alpha helices. , 1988, Science.

[22]  L Serrano,et al.  Aromatic-aromatic interactions and protein stability. Investigation by double-mutant cycles. , 1991, Journal of molecular biology.

[23]  J. Lecomte,et al.  Helix formation in apocytochrome b5: the role of a neutral histidine at the N-cap position , 1991 .

[24]  P. S. Kim,et al.  Specific intermediates in the folding reactions of small proteins and the mechanism of protein folding. , 1982, Annual review of biochemistry.

[25]  R. Hartley,et al.  Expression of Bacillus amyloliquefaciens extracellular ribonuclease (barnase) in Escherichia coli following an inactivating mutation. , 1987, Gene.

[26]  H. Scheraga,et al.  Helix‐coil stability constants for the naturally occurring amino acids in water. XXIII. Proline parameters from random poly(hydroxybutylglutamine‐CO‐L‐proline) , 1990, Biopolymers.

[27]  C. Chothia The nature of the accessible and buried surfaces in proteins. , 1976, Journal of molecular biology.

[28]  Alan R. Fersht,et al.  Stabilization of protein structure by interaction of α-helix dipole with a charged side chain , 1988, Nature.

[29]  A. Fersht,et al.  Surface electrostatic interactions contribute little of stability of barnase. , 1991, Journal of molecular biology.

[30]  Alan R. Fersht,et al.  The use of double mutants to detect structural changes in the active site of the tyrosyl-tRNA synthetase (Bacillus stearothermophilus) , 1984, Cell.

[31]  R. L. Baldwin,et al.  Unusually stable helix formation in short alanine-based peptides. , 1989, Proceedings of the National Academy of Sciences of the United States of America.

[32]  A. Fersht,et al.  Estimating the contribution of engineered surface electrostatic interactions to protein stability by using double-mutant cycles. , 1990, Biochemistry.

[33]  M Levitt,et al.  Molecular dynamics of native protein. II. Analysis and nature of motion. , 1983, Journal of molecular biology.

[34]  L Serrano,et al.  The folding of an enzyme. II. Substructure of barnase and the contribution of different interactions to protein stability. , 1992, Journal of molecular biology.

[35]  R. Sauer,et al.  Stabilization of λ repressor against thermal denaturation by site‐directed Gly→Ala changes in α‐helix 3 , 1986 .

[36]  H. Scheraga,et al.  Helix‐coil stability constants for the naturally occurring amino acids in water. XII. Asparagine parameters from random poly(hydroxybutylglutamine‐co‐L‐asparagine) , 1977, Biopolymers.

[37]  M. Levitt,et al.  Conformation of amino acid side-chains in proteins. , 1978, Journal of molecular biology.

[38]  A. D. McLachlan,et al.  Solvation energy in protein folding and binding , 1986, Nature.

[39]  Alan R. Fersht,et al.  Capping and α-helix stability , 1989, Nature.

[40]  L Serrano,et al.  The folding of an enzyme. IV. Structure of an intermediate in the refolding of barnase analysed by a protein engineering procedure. , 1992, Journal of molecular biology.

[41]  A. Fersht,et al.  Histidine residues at the N- and C-termini of alpha-helices: perturbed pKas and protein stability. , 1992, Biochemistry.

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

[43]  P. Bork,et al.  On α-helices terminated by glycine , 1991 .

[44]  R. Sharon,et al.  Accurate simulation of protein dynamics in solution. , 1988, Proceedings of the National Academy of Sciences of the United States of America.

[45]  J. Janin,et al.  Crystal structure of a barnase-d(GpC) complex at 1.9 A resolution. , 1991, Journal of molecular biology.

[46]  H. Berendsen,et al.  The α-helix dipole and the properties of proteins , 1978, Nature.

[47]  G. Rose,et al.  Helix signals in proteins. , 1988, Science.

[48]  B. Zimm,et al.  Theory of the Phase Transition between Helix and Random Coil in Polypeptide Chains , 1959 .

[49]  B. Matthews,et al.  Enhanced protein thermostability from site-directed mutations that decrease the entropy of unfolding. , 1987, Proceedings of the National Academy of Sciences of the United States of America.

[50]  A. Fersht,et al.  Energetics of complementary side-chain packing in a protein hydrophobic core. , 1989, Biochemistry.

[51]  C. Sander,et al.  Database of homology‐derived protein structures and the structural meaning of sequence alignment , 1991, Proteins.

[52]  T. Higuchi,et al.  Thermodynamic group contributions from ion pair extraction equilibriums for use in the prediction of partition coefficients. Correlation of surface area with group contributions , 1973 .

[53]  W. DeGrado,et al.  A thermodynamic scale for the helix-forming tendencies of the commonly occurring amino acids. , 1990, Science.

[54]  A violent birth for Mercury , 1988, Nature.

[55]  Wim G. J. Hol,et al.  The role of the α-helix dipole in protein function and structure , 1985 .

[56]  A. Fersht,et al.  Hydrogen bonding and biological specificity analysed by protein engineering , 1985, Nature.

[57]  A. Fersht,et al.  Alpha-helix stability in proteins. II. Factors that influence stability at an internal position. , 1992, Journal of molecular biology.

[58]  Robert B. Hermann,et al.  Theory of hydrophobic bonding. II. Correlation of hydrocarbon solubility in water with solvent cavity surface area , 1972 .

[59]  Alarums and diversions , 1991, Nature.

[60]  Cyrus Chothia,et al.  Molecular structure of a new family of ribonucleases , 1982, Nature.

[61]  J. Sayers,et al.  5'-3' exonucleases in phosphorothioate-based oligonucleotide-directed mutagenesis. , 1988, Nucleic acids research.

[62]  Uwe Sauer,et al.  Dissection of helix capping in T4 lysozyme by structural and thermodynamic analysis of six amino acid substitutions at Thr 59 , 1993 .

[63]  B Honig,et al.  Extracting hydrophobic free energies from experimental data: relationship to protein folding and theoretical models. , 1991, Biochemistry.

[64]  A. Fersht The hydrogen bond in molecular recognition , 1987 .

[65]  R. Hartley A two-state conformational transition of the extracellular ribonuclease of Bacillus amyloliquefaciens (barnase) induced by sodium dodecyl sulfate. , 1975, Biochemistry.

[66]  B. Matthews,et al.  Analysis of the interaction between charged side chains and the alpha-helix dipole using designed thermostable mutants of phage T4 lysozyme. , 1991, Biochemistry.

[67]  L Serrano,et al.  The folding of an enzyme. VI. The folding pathway of barnase: comparison with theoretical models. , 1992, Journal of molecular biology.

[68]  A. Fersht,et al.  Contribution of hydrophobic interactions to protein stability , 1988, Nature.

[69]  C. Chothia,et al.  Hydrophobic bonding and accessible surface area in proteins , 1974, Nature.

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

[71]  E. Milner-White Recurring loop motif in proteins that occurs in right-handed and left-handed forms. Its relationship with alpha-helices and beta-bulge loops. , 1988, Journal of molecular biology.

[72]  Alan R. Fersht,et al.  Determination of the three-dimensional solution structure of barnase using nuclear magnetic resonance spectroscopy , 1991 .

[73]  C. Richardson,et al.  DNA sequence analysis with a modified bacteriophage T7 DNA polymerase. , 1987, Proceedings of the National Academy of Sciences of the United States of America.

[74]  R. L. Baldwin,et al.  Helix stabilization by Glu-...Lys+ salt bridges in short peptides of de novo design. , 1987, Proceedings of the National Academy of Sciences of the United States of America.

[75]  H. Scheraga,et al.  Accessible surface areas as a measure of the thermodynamic parameters of hydration of peptides. , 1987, Proceedings of the National Academy of Sciences of the United States of America.

[76]  N R Kallenbach,et al.  Side chain contributions to the stability of alpha-helical structure in peptides. , 1990, Science.

[77]  L Serrano,et al.  Effect of active site residues in barnase on activity and stability. , 1992, Journal of molecular biology.

[78]  P. Y. Chou,et al.  Empirical predictions of protein conformation. , 1978, Annual review of biochemistry.

[79]  E. Stellwagen,et al.  Positional independence and additivity of amino acid replacements on helix stability in monomeric peptides. , 1990, Biochemistry.

[80]  B. Matthews,et al.  Enhanced protein thermostability from designed mutations that interact with α-helix dipoles , 1990, Nature.

[81]  C. Pace Determination and analysis of urea and guanidine hydrochloride denaturation curves. , 1986, Methods in enzymology.

[82]  C. Richardson,et al.  Selective inactivation of the exonuclease activity of bacteriophage T7 DNA polymerase by in vitro mutagenesis. , 1989, The Journal of biological chemistry.

[83]  A. Finkelstein,et al.  Theory of protein secondary structure and algorithm of its prediction , 1983, Biopolymers.

[84]  F. Richards,et al.  Solvents, interfaces and protein structure. , 1977, Ciba Foundation symposium.

[85]  R. L. Baldwin,et al.  Proline for alanine substitutions in the C-peptide helix of ribonuclease A. , 1991, Biochemistry.

[86]  A. Fersht,et al.  An N-terminal fragment of barnase has residual helical structure similar to that in a refolding intermediate. , 1992, Journal of molecular biology.

[87]  A. Fersht,et al.  Effect of alanine versus glycine in α-helices on protein stability , 1992, Nature.

[88]  P. Lyu,et al.  Local effect of glycine substitution in a model helical peptide , 1991 .

[89]  M Bycroft,et al.  Characterization of phosphate binding in the active site of barnase by site-directed mutagenesis and NMR. , 1991, Biochemistry.