Structural basis for broad specificity in alpha-lytic protease mutants.

Binding pocket mutants of alpha-lytic protease (Met 192----Ala and Met 213----Ala) have been constructed recently in an effort to create a protease specific for Met just prior to the scissile bond. Instead, mutation resulted in proteases with extraordinarily broad specificity profiles and high activity [Bone, R., Silen, J. L., & Agard, D. A. (1989) Nature 339, 191-195]. To understand the structural basis for the unexpected specificity profiles of these mutants, high-resolution X-ray crystal structures have been determined for complexes of each mutant with a series of systematically varying peptidylboronic acids. These inhibitory analogues of high-energy reaction intermediates provide models for how substrates with different side chains interact with the enzyme during the transition state. Fifteen structures have been analyzed qualitatively and quantitatively with respect to enzyme-inhibitor hydrogen-bond lengths, buried hydrophobic surface area, unfilled cavity volume, and the magnitude of inhibitor accommodating conformational adjustments (particularly in the region of another binding pocket residue, Val 217A). Comparison of these four parameters with the Ki of each inhibitor and the kcat and Km of the analogous substrates indicates that while no single structural parameter consistently correlates with activity or inhibition, the observed data can be understood as a combination of effects. Furthermore, the relative contribution of each term differs for the three enzymes, reflecting the altered conformational energetics of each mutant. From the extensive structural analysis, it is clear that enzyme flexibility, especially in the region of Val 217A, is primarily responsible for the exceptionally broad specificity observed in either mutant. Taken together, the observed patterns of substrate specificity can be understood to arise directly from interactions between the substrate and the residues lining the specificity pocket and indirectly from interactions between peripheral regions of the protein and the active-site region that serve to modulate active-site flexibility.

[1]  D. Agard,et al.  Crystal structures of alpha-lytic protease complexes with irreversibly bound phosphonate esters. , 1993, Biochemistry.

[2]  John B. O. Mitchell,et al.  The nature of the N  H…︁OC hydrogen bond: An intermolecular perturbation theory study of the formamide/formaldehyde complex , 1990 .

[3]  K. Brady,et al.  Inhibition of chymotrypsin by peptidyl trifluoromethyl ketones: determinants of slow-binding kinetics. , 1990, Biochemistry.

[4]  D. Agard,et al.  Structural analysis of specificity: alpha-lytic protease complexes with analogues of reaction intermediates. , 1990, Biochemistry.

[5]  D. Agard,et al.  Structural analysis of specificity: .alpha.-lytic protease complexes with analogs of reaction intermediates , 1989 .

[6]  S. Scheiner,et al.  Factors contributing to distortion energies of bent hydrogen bonds: implications for proton-transfer potentials , 1989 .

[7]  David A. Agard,et al.  Structural plasticity broadens the specificity of an engineered protease , 1989, Nature.

[8]  D. Agard,et al.  Analysis of prepro-alpha-lytic protease expression in Escherichia coli reveals that the pro region is required for activity , 1989, Journal of bacteriology.

[9]  W. Bachovchin,et al.  Nitrogen-15 NMR spectroscopy of the catalytic-triad histidine of a serine protease in peptide boronic acid inhibitor complexes. , 1988, Biochemistry.

[10]  D. Agard,et al.  Kinetic properties of the binding of alpha-lytic protease to peptide boronic acids. , 1988, Biochemistry.

[11]  J. L. Smith,et al.  Refinement at 1.4 A resolution of a model of erabutoxin b: treatment of ordered solvent and discrete disorder. , 1988, Acta crystallographica. Section A, Foundations of crystallography.

[12]  A. Fersht Relationships between apparent binding energies measured in site-directed mutagenesis experiments and energetics of binding and catalysis. , 1988, Biochemistry.

[13]  D. Agard,et al.  Serine protease mechanism: structure of an inhibitory complex of alpha-lytic protease and a tightly bound peptide boronic acid. , 1987, Biochemistry.

[14]  A. Fersht,et al.  Electrostatic effects on modification of charged groups in the active site cleft of subtilisin by protein engineering. , 1987, Journal of molecular biology.

[15]  G. Rose,et al.  Loops in globular proteins: a novel category of secondary structure. , 1986, Science.

[16]  J. V. Miller,et al.  Probing Steric and Hydrophobic Effects on Enzyme-Substrate Interactions by Protein Engineering , 1986, Science.

[17]  B Honig,et al.  Internal cavities and buried waters in globular proteins. , 1986, Biochemistry.

[18]  Frank Weinhold,et al.  Natural bond orbital analysis of molecular interactions: Theoretical studies of binary complexes of , 1986 .

[19]  L. Delbaere,et al.  Refined structure of alpha-lytic protease at 1.7 A resolution. Analysis of hydrogen bonding and solvent structure. , 1985, Journal of molecular biology.

[20]  J. Derancourt,et al.  Molecular movements promoted by metal nucleotides in the heavy-chain regions of myosin heads from skeletal muscle. , 1985, Journal of molecular biology.

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

[22]  Michael L. Connolly,et al.  Computation of molecular volume , 1985 .

[23]  U. Singh,et al.  A NEW FORCE FIELD FOR MOLECULAR MECHANICAL SIMULATION OF NUCLEIC ACIDS AND PROTEINS , 1984 .

[24]  M. L. Connolly Analytical molecular surface calculation , 1983 .

[25]  P. Bartlett,et al.  Phosphonamidates as transition-state analogue inhibitors of thermolysin. , 1983, Biochemistry.

[26]  M. L. Connolly Solvent-accessible surfaces of proteins and nucleic acids. , 1983, Science.

[27]  P. Righetti Gel electrophoresis of proteins: A practical approach. Edited by B. Hames and D. Rickwood, IRL Press Ltd, Oxford, England, 1981, $ 18 , 1982 .

[28]  M. James,et al.  Active Site of α-Lytic Protease , 1981 .

[29]  A. Fersht,et al.  Probing the limits of protein-amino acid side chain recognition with the aminoacyl-tRNA synthetases. Discrimination against phenylalanine by tyrosyl-tRNA synthetases. , 1980, Biochemistry.

[30]  L. Delbaere,et al.  Molecular structure of the α-lytic protease from Myxobacter 495 at 2·8 Å resolution☆ , 1979 .

[31]  Georg E. Schulz,et al.  Principles of Protein Structure , 1979 .

[32]  F M Richards,et al.  Areas, volumes, packing and protein structure. , 1977, Annual review of biophysics and bioengineering.

[33]  M. Hunkapiller,et al.  Mechanism of action of serine proteases: tetrahedral intermediate and concerted proton transfer. , 1976, Biochemistry.

[34]  G. G. Christoph,et al.  Data collection in protein crystallography: capillary effects and background corrections , 1974 .

[35]  R. Dickerson,et al.  The structure of bovine trypsin : Electron density maps of the inhibited enzyme at 5 Å and at 2·7 Å resolution☆ , 1974 .

[36]  M. Hunkapiller,et al.  Carbon nuclear magnetic resonance studies of the histidine residue in alpha-lytic protease. Implications for the catalytic mechanism of serine proteases. , 1973, Biochemistry.

[37]  R. Thompson Use of peptide aldehydes to generate transition-state analogs of elastase. , 1973, Biochemistry.

[38]  R. Wolfenden,et al.  Aldehydes as inhibitors of papain. , 1972, The Journal of biological chemistry.

[39]  K. Martínek,et al.  The influence of the geometric properties of the active centre on the specificity of α‐chymotrypsin catalysis , 1972, FEBS letters.

[40]  P. R. Bevington,et al.  Data Reduction and Error Analysis for the Physical Sciences , 1969 .

[41]  N. Allewell,et al.  Design of a diffractometer and flow cell system for X-ray analysis of crystalline proteins with applications to the crystal chemistry of ribonuclease-S. , 1967, Journal of molecular biology.

[42]  A. Berger,et al.  On the size of the active site in proteases. I. Papain. , 1967, Biochemical and biophysical research communications.

[43]  P. Flory,et al.  Conformational energy estimates for statistically coiling polypeptide chains , 1967 .

[44]  C. Chothia Principles that determine the structure of proteins. , 1984, Annual review of biochemistry.

[45]  J. Morrison,et al.  [17] The kinetics of reversible tight-binding inhibition , 1979 .

[46]  A. Fersht Enzyme structure and mechanism , 1977 .

[47]  A. Zamyatnin,et al.  Protein volume in solution. , 1972, Progress in biophysics and molecular biology.

[48]  Richard Wolfenden,et al.  Analog approaches to the structure of the transition state in enzyme reactions , 1972 .

[49]  D. R. Whitaker [43] The α-lytic protease of a myxobacterium , 1970 .