Re‐examining the role of Lys67 in class C β‐lactamase catalysis

Lys67 is essential for the hydrolysis reaction mediated by class C β‐lactamases. Its exact catalytic role lies at the center of several different proposed reaction mechanisms, particularly for the deacylation step, and has been intensely debated. Whereas a conjugate base hypothesis postulates that a neutral Lys67 and Tyr150 act together to deprotonate the deacylating water, previous experiments on the K67R mutants of class C β‐lactamases suggested that the role of Lys67 in deacylation is mainly electrostatic, with only a 2‐ to 3‐fold decrease in the rate of the mutant vs the wild type enzyme. Using the Class C β‐lactamase AmpC, we have reinvestigated the activity of this K67R mutant enzyme, using biochemical and structural studies. Both the rates of acylation and deacylation were affected in the AmpC K67R mutant, with a 61‐fold decrease in kcat, the deacylation rate. We have determined the structure of the K67R mutant by X‐ray crystallography both in apo and transition state‐analog complexed forms, and observed only minimal conformational changes in the catalytic residues relative to the wild type. These results suggest that the arginine side chain is unable to play the same catalytic role as Lys67 in either the acylation or deacylation reactions catalyzed by AmpC. Therefore, the activity of this mutant can not be used to discredit the conjugate base hypothesis as previously concluded, although the reaction catalyzed by the K67R mutant itself likely proceeds by an alternative mechanism. Indeed, a manifold of mechanisms may contribute to hydrolysis in class C β‐lactamases, depending on the enzyme (wt or mutant) and the substrate, explaining why different mutants and substrates seem to support different pathways. For the WT enzyme itself, the conjugate base mechanism may be well favored.

[1]  Yoshiaki Oyama,et al.  pKa measurements from nuclear magnetic resonance of tyrosine-150 in class C beta-lactamase. , 2003, The Biochemical journal.

[2]  J. Frère,et al.  The role of lysine-67 in a class C β-lactamase is mainly electrostatic , 1994 .

[3]  Samy O Meroueh,et al.  Ab initio QM/MM study of class A beta-lactamase acylation: dual participation of Glu166 and Lys73 in a concerted base promotion of Ser70. , 2005, Journal of the American Chemical Society.

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

[5]  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.

[6]  Richard A Friesner,et al.  Mixed quantum mechanical/molecular mechanical (QM/MM) study of the deacylation reaction in a penicillin binding protein (PBP) versus in a class C beta-lactamase. , 2004, Journal of the American Chemical Society.

[7]  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.

[8]  Jesús Blázquez,et al.  The complexed structure and antimicrobial activity of a non‐β‐lactam inhibitor of AmpC β‐lactamase , 2008, Protein science : a publication of the Protein Society.

[9]  F. Winkler,et al.  Refined crystal structure of beta-lactamase from Citrobacter freundii indicates a mechanism for beta-lactam hydrolysis. , 2001, Nature.

[10]  N. Gensmantel,et al.  The chemical reactivity of penicillins and other β-lactam antibiotics , 1982 .

[11]  R. Pratt,et al.  Kinetics and mechanism of the hydrolysis of depsipeptides catalyzed by the beta-lactamase of Enterobacter cloacae P99. , 1996, Biochemistry.

[12]  I. Massova,et al.  Nuances of Mechanisms and Their Implications for Evolution of the Versatile β-Lactamase Activity: From Biosynthetic Enzymes to Drug Resistance Factors , 1997 .

[13]  O. Herzberg,et al.  Structure of a phosphonate-inhibited beta-lactamase. An analog of the tetrahedral transition state/intermediate of beta-lactam hydrolysis. , 1993, Journal of molecular biology.

[14]  F. Winkler,et al.  Refined crystal structure of β-lactamase from Citrobacter freundiiindicates a mechanism for β-lactam hydrolysis , 1990, Nature.

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

[16]  Samy O Meroueh,et al.  Bacterial resistance to beta-lactam antibiotics: compelling opportunism, compelling opportunity. , 2005, Chemical reviews.

[17]  J. Frère,et al.  Catalytic properties of class A beta-lactamases: efficiency and diversity. , 1998, The Biochemical journal.

[18]  Collaborative Computational,et al.  The CCP4 suite: programs for protein crystallography. , 1994, Acta crystallographica. Section D, Biological crystallography.

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

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

[21]  M. Ishiguro,et al.  Reaction of Lys-Tyr-Lys triad mimics with benzylpenicillin: insight into the role of Tyr150 in class C beta-lactamase. , 2001, Bioorganic & medicinal chemistry letters.

[22]  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.

[23]  S. Meroueh,et al.  Catalytic mechanism of penicillin-binding protein 5 of Escherichia coli. , 2007, Biochemistry.

[24]  Samy O Meroueh,et al.  Investigation of the mechanism of the cell wall DD-carboxypeptidase reaction of penicillin-binding protein 5 of Escherichia coli by quantum mechanics/molecular mechanics calculations. , 2008, Journal of the American Chemical Society.

[25]  A. Dubus,et al.  The role of tyrosine 150 in catalysis of beta-lactam hydrolysis by AmpC beta-lactamase from Escherichia coli investigated by site-directed mutagenesis. , 1994, Biochemistry.

[26]  E. Colt Inactivation of Antibiotics and the Dissemination of Resistance Genes , 2001 .

[27]  Brian K Shoichet,et al.  Structure-based approach for binding site identification on AmpC beta-lactamase. , 2002, Journal of medicinal chemistry.

[28]  R. Pratt,et al.  Effectiveness of Tetrahedral Adducts as Transition-State Analogs and Inhibitors of the Class C β-Lactamase of Enterobacter cloacae P99 , 1997 .

[29]  S. Meroueh,et al.  The Importance of a Critical Protonation State and the Fate of the Catalytic Steps in Class A β-Lactamases and Penicillin-binding Proteins* , 2004, Journal of Biological Chemistry.

[30]  Alain Dubus,et al.  The enigmatic catalytic mechanism of active-site serine β-lactamases , 1995 .

[31]  Kevin Cowtan,et al.  research papers Acta Crystallographica Section D Biological , 2005 .

[32]  J Davies,et al.  Inactivation of antibiotics and the dissemination of resistance genes. , 1994, Science.

[33]  B. Shoichet,et al.  Thermodynamic cycle analysis and inhibitor design against beta-lactamase. , 2003, Biochemistry.

[34]  R. Bonomo,et al.  Inhibition of class A and class C beta-lactamases by penems: crystallographic structures of a novel 1,4-thiazepine intermediate. , 2003, Biochemistry.

[35]  B. Shoichet,et al.  The deacylation mechanism of AmpC beta-lactamase at ultrahigh resolution. , 2006, Journal of the American Chemical Society.