Structural bases of stability-function tradeoffs in enzymes.

The structures of enzymes reflect two tendencies that appear opposed. On one hand, they fold into compact, stable structures; on the other hand, they bind a ligand and catalyze a reaction. To be stable, enzymes fold to maximize favorable interactions, forming a tightly packed hydrophobic core, exposing hydrophilic groups, and optimizing intramolecular hydrogen-bonding. To be functional, enzymes carve out an active site for ligand binding, exposing hydrophobic surface area, clustering like charges, and providing unfulfilled hydrogen bond donors and acceptors. Using AmpC beta-lactamase, an enzyme that is well-characterized structurally and mechanistically, the relationship between enzyme stability and function was investigated by substituting key active-site residues and measuring the changes in stability and activity. Substitutions of catalytic residues Ser64, Lys67, Tyr150, Asn152, and Lys315 decrease the activity of the enzyme by 10(3)-10(5)-fold compared to wild-type. Concomitantly, many of these substitutions increase the stability of the enzyme significantly, by up to 4.7kcal/mol. To determine the structural origins of stabilization, the crystal structures of four mutant enzymes were determined to between 1.90A and 1.50A resolution. These structures revealed several mechanisms by which stability was increased, including mimicry of the substrate by the substituted residue (S64D), relief of steric strain (S64G), relief of electrostatic strain (K67Q), and improved polar complementarity (N152H). These results suggest that the preorganization of functionality characteristic of active sites has come at a considerable cost to enzyme stability. In proteins of unknown function, the presence of such destabilized regions may indicate the presence of a binding site.

[1]  S. Mobashery,et al.  Class C β-Lactamases Operate at the Diffusion Limit for Turnover of Their Preferred Cephalosporin Substrates , 1999, Antimicrobial Agents and Chemotherapy.

[2]  L. Shapiro,et al.  Finding function through structural genomics. , 2000, Current opinion in biotechnology.

[3]  J. Thornton,et al.  PROCHECK: a program to check the stereochemical quality of protein structures , 1993 .

[4]  B K Shoichet,et al.  A relationship between protein stability and protein function. , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[5]  R. Sauer,et al.  Effect of single amino acid replacements on the thermal stability of the NH2-terminal domain of phage lambda repressor. , 1984, Proceedings of the National Academy of Sciences of the United States of America.

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

[7]  A. Dubus,et al.  Role of asparagine 152 in catalysis of beta-lactam hydrolysis by Escherichia coli AmpC beta-lactamase studied by site-directed mutagenesis. , 1995, Biochemistry.

[8]  R J Williams,et al.  Energised (entatic) states of groups and of secondary structures in proteins and metalloproteins. , 1995, European journal of biochemistry.

[9]  W. J. Becktel,et al.  Protein stability curves , 1987, Biopolymers.

[10]  Conrad C. Huang,et al.  The MIDAS display system , 1988 .

[11]  E. Billings,et al.  Crystallographic structure of a phosphonate derivative of the Enterobacter cloacae P99 cephalosporinase: mechanistic interpretation of a beta-lactamase transition-state analog. , 1994, Biochemistry.

[12]  G Schreiber,et al.  Stability and function: two constraints in the evolution of barstar and other proteins. , 1994, Structure.

[13]  J. Knox,et al.  Inhibition of class C beta-lactamases: structure of a reaction intermediate with a cephem sulfone. , 2001, Biochemistry.

[14]  Refined crystal structure of beta-lactamase from Citrobacter freundii indicates a mechanism for beta-lactam hydrolysis. , 1990, Nature.

[15]  M. Ondrechen,et al.  THEMATICS: A simple computational predictor of enzyme function from structure , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[16]  A. Warshel,et al.  Evaluation of catalytic free energies in genetically modified proteins. , 1988, Journal of molecular biology.

[17]  R. Sauer,et al.  Amino acid substitutions that increase the thermal stability of the λ Cro protein , 1989 .

[18]  D. Torchia,et al.  Deletion of the omega-loop in the active site of staphylococcal nuclease. 2. Effects on protein structure and dynamics. , 1991, Biochemistry.

[19]  B. Shoichet,et al.  Functional analyses of AmpC β‐lactamase through differential stability , 1999 .

[20]  J. Moult,et al.  Biological function made crystal clear - annotation of hypothetical proteins via structural genomics. , 2000, Current opinion in biotechnology.

[21]  R. Sauer,et al.  Amino acid substitutions that increase the thermal stability of the lambda Cro protein. , 1989, Proteins.

[22]  J. Gerlt,et al.  Site-directed mutants of staphylococcal nuclease. Detection and localization by 1H NMR spectroscopy of conformational changes accompanying substitutions for glutamic acid-43. , 1987, Biochemistry.

[23]  Akinori Sarai,et al.  ProTherm, version 2.0: thermodynamic database for proteins and mutants , 2000, Nucleic Acids Res..

[24]  R. Williams The entatic state. , 1972, Cold Spring Harbor symposia on quantitative biology.

[25]  A. Warshel,et al.  Energetics of enzyme catalysis. , 1978, Proceedings of the National Academy of Sciences of the United States of America.

[26]  Functional analyses of AmpC beta-lactamase through differential stability. , 1999, Protein science : a publication of the Protein Society.

[27]  A. Elcock Prediction of functionally important residues based solely on the computed energetics of protein structure. , 2001, Journal of molecular biology.

[28]  G S Weston,et al.  Three-dimensional structure of AmpC beta-lactamase from Escherichia coli bound to a transition-state analogue: possible implications for the oxyanion hypothesis and for inhibitor design. , 1998, Biochemistry.

[29]  F. Richards The interpretation of protein structures: total volume, group volume distributions and packing density. , 1974, Journal of molecular biology.

[30]  S. Ho,et al.  Site-directed mutagenesis by overlap extension using the polymerase chain reaction. , 1989, Gene.

[31]  J. Frère,et al.  The roles of residues Tyr150, Glu272, and His314 in class C β‐lactamases , 1996 .

[32]  Beth M Beadle,et al.  Structural milestones in the reaction pathway of an amide hydrolase: substrate, acyl, and product complexes of cephalothin with AmpC beta-lactamase. , 2002, Structure.

[33]  R J Read,et al.  Crystallography & NMR system: A new software suite for macromolecular structure determination. , 1998, Acta crystallographica. Section D, Biological crystallography.

[34]  S V Evans,et al.  SETOR: hardware-lighted three-dimensional solid model representations of macromolecules. , 1993, Journal of molecular graphics.

[35]  J Moult,et al.  Analysis of the steric strain in the polypeptide backbone of protein molecules , 1991, Proteins.

[36]  G S Weston,et al.  Structure-based enhancement of boronic acid-based inhibitors of AmpC beta-lactamase. , 1998, Journal of medicinal chemistry.

[37]  J. Frère,et al.  Role of residue Lys315 in the mechanism of action of the Enterobacter cloacae 908R beta-lactamase. , 1994, Biochemistry.

[38]  Z. Otwinowski,et al.  Processing of X-ray diffraction data collected in oscillation mode. , 1997, Methods in enzymology.

[39]  B K Shoichet,et al.  Structures of ceftazidime and its transition-state analogue in complex with AmpC beta-lactamase: implications for resistance mutations and inhibitor design. , 2001, Biochemistry.

[40]  F. K. Gleason,et al.  Mutation of conserved residues in Escherichia coli thioredoxin: Effects on stability and function , 1992, Protein science : a publication of the Protein Society.

[41]  B. Shoichet,et al.  Crystal Structures of Substrate and Inhibitor Complexes with AmpC β-Lactamase: Possible Implications for Substrate-Assisted Catalysis , 2000 .

[42]  T. Sawai,et al.  Role of lysine-67 in the active site of class C beta-lactamase from Citrobacter freundii GN346. , 1990, European journal of biochemistry.

[43]  R. Pratt,et al.  Evidence for an oxyanion hole in serine beta-lactamases and DD-peptidases. , 1988, The Biochemical journal.

[44]  I. Luque,et al.  Structural stability of binding sites: Consequences for binding affinity and allosteric effects , 2000, Proteins.

[45]  S Karlin,et al.  Clusters of charged residues in protein three-dimensional structures. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[46]  A. Warshel Electrostatic Origin of the Catalytic Power of Enzymes and the Role of Preorganized Active Sites* , 1998, The Journal of Biological Chemistry.

[47]  T. Clackson,et al.  A hot spot of binding energy in a hormone-receptor interface , 1995, Science.

[48]  J. Gerlt,et al.  Deletion of the omega-loop in the active site of staphylococcal nuclease. 1. Effect on catalysis and stability. , 1991, Biochemistry.

[49]  J. Frère,et al.  The diversity of the catalytic properties of class A beta-lactamases. , 1990, The Biochemical journal.

[50]  J. Zou,et al.  Improved methods for building protein models in electron density maps and the location of errors in these models. , 1991, Acta crystallographica. Section A, Foundations of crystallography.