A procedure for the prediction of temperature-sensitive mutants of a globular protein based solely on the amino acid sequence.

Temperature-sensitive (Ts) mutants of a protein are an extremely powerful tool for studying protein function in vivo and in cell culture. We have devised a method to predict those residues in a protein sequence that, when appropriately mutated, are most likely to give rise to a Ts phenotype. Since substitutions of buried hydrophobic residues often result in significant destabilization of the protein, our method predicts those residues in the sequence that are likely to be buried in the protein structure. We also indicate a set of amino acid substitutions, which should be made to generate a Ts mutant of the protein. This method requires only the protein sequence. No structural information or homologous sequence information is required. This method was applied to a test data set of 30 nonhomologous protein structures from the Protein Data Bank. All of the residues predicted by the method to be > or = 95% buried were, in fact, buried in the protein crystal structure. In contrast, only 50% of all hydrophobic residues in this data set were > or = 95% buried. This method successfully predicts several known Ts and partially active mutants of T4 lysozyme, lambda repressor, gene V protein, and staphylococcal nuclease. This method also correctly predicts residues that form part of the hydrophobic cores of lambda repressor, myoglobin, and cytochrome b562.

[1]  S H Kim,et al.  Predicting surface exposure of amino acids from protein sequence. , 1990, Protein engineering.

[2]  R. Krumlauf,et al.  Hoxb-4 (Hox-2.6) mutant mice show homeotic transformation of a cervical vertebra and defects in the closure of the sternal rudiments , 1993, Cell.

[3]  N. Horowitz,et al.  Biochemical genetics of Neurospora. , 1950, Advances in genetics.

[4]  G. Fasman Prediction of Protein Structure and the Principles of Protein Conformation , 2012, Springer US.

[5]  W E Stites,et al.  Contributions of the large hydrophobic amino acids to the stability of staphylococcal nuclease. , 1990, Biochemistry.

[6]  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.

[7]  A. Varshavsky,et al.  Heat-inducible degron: a method for constructing temperature-sensitive mutants. , 1994, Science.

[8]  R. W. Davis,et al.  Replacement of chromosome segments with altered DNA sequences constructed in vitro. , 1979, Proceedings of the National Academy of Sciences of the United States of America.

[9]  T L Blundell,et al.  Use of amino acid environment-dependent substitution tables and conformational propensities in structure prediction from aligned sequences of homologous proteins. I. Solvent accessibility classes. , 1994, Journal of molecular biology.

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

[11]  B. Matthews,et al.  Temperature-sensitive mutations of bacteriophage T4 lysozyme occur at sites with low mobility and low solvent accessibility in the folded protein. , 1987, Biochemistry.

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

[13]  S Roy,et al.  Hydrophobic basis of packing in globular proteins. , 1980, Proceedings of the National Academy of Sciences of the United States of America.

[14]  B. Matthews,et al.  Structural and thermodynamic consequences of burying a charged residue within the hydrophobic core of T4 lysozyme. , 1991, Biochemistry.

[15]  T C Terwilliger,et al.  Relationship between in vivo activity and in vitro measures of function and stability of a protein. , 1995, Biochemistry.

[16]  S. Boxer,et al.  Electrostatic interactions in wild-type and mutant recombinant human myoglobins. , 1989, Biochemistry.

[17]  R. Sauer,et al.  Mutations in lambda repressor's amino-terminal domain: implications for protein stability and DNA binding. , 1983, Proceedings of the National Academy of Sciences of the United States of America.

[18]  G J Williams,et al.  The Protein Data Bank: a computer-based archival file for macromolecular structures. , 1977, Journal of molecular biology.

[19]  B Rost,et al.  Progress of 1D protein structure prediction at last , 1995, Proteins.

[20]  R. Sauer,et al.  Genetic analysis of protein stability and function. , 1989, Annual review of genetics.

[21]  G. Rubin,et al.  Ras1 and a putative guanine nucleotide exchange factor perform crucial steps in signaling by the sevenless protein tyrosine kinase , 1991, Cell.

[22]  H. Nash Integration and Excision of Bacteriophage λ: The Mechanism of Conservative Site Specific Recombination , 1981 .

[23]  G. Sarkar,et al.  The "megaprimer" method of site-directed mutagenesis. , 1990, BioTechniques.

[24]  R. Sauer,et al.  The structural stability of a protein is an important determinant of its proteolytic susceptibility in Escherichia coli. , 1989, The Journal of biological chemistry.

[25]  R. Sauer,et al.  Bacteriophage lambda cro mutations: effects on activity and intracellular degradation. , 1986, Proceedings of the National Academy of Sciences of the United States of America.

[26]  T. Loukeris,et al.  Gene Transfer into the Medfly, Ceratitis capitata, with a Drosophila hydei Transposable Element , 1995, Science.

[27]  C. DeLisi,et al.  Hydrophobicity scales and computational techniques for detecting amphipathic structures in proteins. , 1987, Journal of molecular biology.

[28]  M. Fried,et al.  CELL-TRANSFORMING ABILITY OF A TEMPERATURE-SENSITIVE MUTANT OF POLYOMA VIRUS. , 1965, Proceedings of the National Academy of Sciences of the United States of America.

[29]  D. Eisenberg Three-dimensional structure of membrane and surface proteins. , 1984, Annual review of biochemistry.

[30]  M. Bate,et al.  A wingless-dependent polar coordinate system in Drosophila imaginal discs. , 1993, Science.

[31]  F. Richards,et al.  Crystallographic structures of ribonuclease S variants with nonpolar substitution at position 13: packing and cavities. , 1993, Biochemistry.

[32]  T C Terwilliger,et al.  Influence of interior packing and hydrophobicity on the stability of a protein. , 1989, Science.

[33]  K. R. Woods,et al.  Prediction of protein antigenic determinants from amino acid sequences. , 1981, Proceedings of the National Academy of Sciences of the United States of America.

[34]  R. Waterston,et al.  The Nematode Caenorhabditis elegans and Its Genome , 1995, Science.

[35]  Robert T. Sauer,et al.  Lambda repressor mutations that increase the affinity and specificity of operator binding , 1985, Cell.

[36]  W. Lim,et al.  Structural and energetic consequences of disruptive mutations in a protein core. , 1992, Biochemistry.

[37]  W. Lim,et al.  Alternative packing arrangements in the hydrophobic core of λrepresser , 1989, Nature.

[38]  M B Swindells,et al.  A procedure for the automatic determination of hydrophobic cores in protein structures , 1995, Protein science : a publication of the Protein Society.

[39]  G. Rose,et al.  Hydrophobicity of amino acid residues in globular proteins. , 1985, Science.

[40]  G. Rubin,et al.  The effect of chromosomal position on the expression of the drosophila xanthine dehydrogenase gene , 1983, Cell.

[41]  B. Lee,et al.  The interpretation of protein structures: estimation of static accessibility. , 1971, Journal of molecular biology.

[42]  D. Suzuki,et al.  Temperature-sensitive mutations in Drosophila melanogaster. VII. A mutation (para-ts) causing reversible adult paralysis. , 1971, Proceedings of the National Academy of Sciences of the United States of America.