Deciphering the Evolution of Cephalosporin Resistance to Ceftolozane-Tazobactam in Pseudomonas aeruginosa

The presence of β-lactamases (e.g., PDC-3) that have naturally evolved and acquired the ability to break down β-lactam antibiotics (e.g., ceftazidime and ceftolozane) leads to highly resistant and potentially lethal Pseudomonas aeruginosa infections. We show that wild-type PDC-3 β-lactamase forms an acyl enzyme complex with ceftazidime, but it cannot accommodate the structurally similar ceftolozane that has a longer R2 side chain with increased basicity. A single amino acid substitution from a glutamate to a lysine at position 221 in PDC-3 (E221K) causes the tyrosine residue at 223 to adopt a new position poised for efficient hydrolysis of both cephalosporins. The importance of the mechanism of action of the E221K variant, in particular, is underscored by its evolutionary recurrences in multiple bacterial species. Understanding the biochemical and molecular basis for resistance is key to designing effective therapies and developing new β-lactam/β-lactamase inhibitor combinations. ABSTRACT Pseudomonas aeruginosa produces a class C β-lactamase (e.g., PDC-3) that robustly hydrolyzes early generation cephalosporins often at the diffusion limit; therefore, bacteria possessing these β-lactamases are resistant to many β-lactam antibiotics. In response to this significant clinical threat, ceftolozane, a 3′ aminopyrazolium cephalosporin, was developed. Combined with tazobactam, ceftolozane promised to be effective against multidrug-resistant P. aeruginosa. Alarmingly, Ω-loop variants of the PDC β-lactamase (V213A, G216R, E221K, E221G, and Y223H) were identified in ceftolozane/tazobactam-resistant P. aeruginosa clinical isolates. Herein, we demonstrate that the Escherichia coli strain expressing the E221K variant of PDC-3 had the highest minimum inhibitory concentrations (MICs) against a panel of β-lactam antibiotics, including ceftolozane and ceftazidime, a cephalosporin that differs in structure largely in the R2 side chain. The kcat values of the E221K variant for both substrates were equivalent, whereas the Km for ceftolozane (341 ± 64 µM) was higher than that for ceftazidime (174 ± 20 µM). Timed mass spectrometry, thermal stability, and equilibrium unfolding studies revealed key mechanistic insights. Enhanced sampling molecular dynamics simulations identified conformational changes in the E221K variant Ω-loop, where a hidden pocket adjacent to the catalytic site opens and stabilizes ceftolozane for efficient hydrolysis. Encouragingly, the diazabicyclooctane β-lactamase inhibitor avibactam restored susceptibility to ceftolozane and ceftazidime in cells producing the E221K variant. In addition, a boronic acid transition state inhibitor, LP-06, lowered the ceftolozane and ceftazidime MICs by 8-fold for the E221K-expressing strain. Understanding these structural changes in evolutionarily selected variants is critical toward designing effective β-lactam/β-lactamase inhibitor therapies for P. aeruginosa infections. IMPORTANCE The presence of β-lactamases (e.g., PDC-3) that have naturally evolved and acquired the ability to break down β-lactam antibiotics (e.g., ceftazidime and ceftolozane) leads to highly resistant and potentially lethal Pseudomonas aeruginosa infections. We show that wild-type PDC-3 β-lactamase forms an acyl enzyme complex with ceftazidime, but it cannot accommodate the structurally similar ceftolozane that has a longer R2 side chain with increased basicity. A single amino acid substitution from a glutamate to a lysine at position 221 in PDC-3 (E221K) causes the tyrosine residue at 223 to adopt a new position poised for efficient hydrolysis of both cephalosporins. The importance of the mechanism of action of the E221K variant, in particular, is underscored by its evolutionary recurrences in multiple bacterial species. Understanding the biochemical and molecular basis for resistance is key to designing effective therapies and developing new β-lactam/β-lactamase inhibitor combinations.

[1]  G. Sutton,et al.  Characterization of the AmpC β-Lactamase from Burkholderia multivorans , 2018, Antimicrobial Agents and Chemotherapy.

[2]  A. Oliver,et al.  Mechanisms leading to in vivo ceftolozane/tazobactam resistance development during the treatment of infections caused by MDR Pseudomonas aeruginosa , 2018, The Journal of antimicrobial chemotherapy.

[3]  R. Bonomo,et al.  Inhibition of Acinetobacter-Derived Cephalosporinase: Exploring the Carboxylate Recognition Site Using Novel β-Lactamase Inhibitors. , 2017, ACS infectious diseases.

[4]  R. Bonomo,et al.  Structure-Based Analysis of Boronic Acids as Inhibitors of Acinetobacter-Derived Cephalosporinase-7, a Unique Class C β-Lactamase. , 2017, ACS infectious diseases.

[5]  Brad Spellberg,et al.  Klebsiella pneumoniae Carbapenemase-2 (KPC-2), Substitutions at Ambler Position Asp179, and Resistance to Ceftazidime-Avibactam: Unique Antibiotic-Resistant Phenotypes Emerge from β-Lactamase Protein Engineering , 2017, mBio.

[6]  B. Kreiswirth,et al.  Emergence of Ceftolozane-Tazobactam-Resistant Pseudomonas aeruginosa during Treatment Is Mediated by a Single AmpC Structural Mutation , 2017, Antimicrobial Agents and Chemotherapy.

[7]  R. Bonomo,et al.  Multicenter Evaluation of Ceftolozane/Tazobactam for Serious Infections Caused by Carbapenem-Resistant Pseudomonas aeruginosa , 2017, Clinical infectious diseases : an official publication of the Infectious Diseases Society of America.

[8]  V. Cooper,et al.  Ceftolozane-Tazobactam for the Treatment of Multidrug-Resistant Pseudomonas aeruginosa Infections: Clinical Effectiveness and Evolution of Resistance , 2017, Clinical infectious diseases : an official publication of the Infectious Diseases Society of America.

[9]  M. Page,et al.  What we may expect from novel antibacterial agents in the pipeline with respect to resistance and pharmacodynamic principles , 2017, Journal of Pharmacokinetics and Pharmacodynamics.

[10]  L. M. Gangcuangco,et al.  Persistent Bacteremia from Pseudomonas aeruginosa with In Vitro Resistance to the Novel Antibiotics Ceftolozane-Tazobactam and Ceftazidime-Avibactam , 2016, Case reports in infectious diseases.

[11]  Margaret A Dudeck,et al.  Antimicrobial-Resistant Pathogens Associated With Healthcare-Associated Infections: Summary of Data Reported to the National Healthcare Safety Network at the Centers for Disease Control and Prevention, 2011–2014 , 2016, Infection Control & Hospital Epidemiology.

[12]  R. Bonomo,et al.  Ceftazidime/Avibactam and Ceftolozane/Tazobactam: Second-generation β-Lactam/β-Lactamase Inhibitor Combinations. , 2016, Clinical infectious diseases : an official publication of the Infectious Diseases Society of America.

[13]  F. Noé,et al.  HTMD: High-Throughput Molecular Dynamics for Molecular Discovery. , 2016, Journal of chemical theory and computation.

[14]  R. Bonomo,et al.  Boronic Acid Transition State Inhibitors Active against KPC and Other Class A β-Lactamases: Structure-Activity Relationships as a Guide to Inhibitor Design , 2016, Antimicrobial Agents and Chemotherapy.

[15]  R. Bonomo,et al.  Activity of ceftazidime/avibactam against isogenic strains of Escherichia coli containing KPC and SHV β-lactamases with single amino acid substitutions in the Ω-loop. , 2015, The Journal of antimicrobial chemotherapy.

[16]  Michael J. Rybak,et al.  The β‐Lactams Strike Back: Ceftazidime‐Avibactam , 2015, Pharmacotherapy.

[17]  I. Broutin,et al.  Mutations in β-Lactamase AmpC Increase Resistance of Pseudomonas aeruginosa Isolates to Antipseudomonal Cephalosporins , 2015, Antimicrobial Agents and Chemotherapy.

[18]  Robert A Bonomo,et al.  Click Chemistry in Lead Optimization of Boronic Acids as β-Lactamase Inhibitors. , 2015, Journal of medicinal chemistry.

[19]  R. Alm,et al.  Selection and molecular characterization of ceftazidime/avibactam-resistant mutants in Pseudomonas aeruginosa strains containing derepressed AmpC. , 2015, The Journal of antimicrobial chemotherapy.

[20]  R. Bonomo,et al.  Inhibiting the β-Lactamase of Mycobacterium tuberculosis (Mtb) with Novel Boronic Acid Transition-State Inhibitors (BATSIs). , 2015, ACS infectious diseases.

[21]  R. Bonomo,et al.  Variants of β-Lactamase KPC-2 That Are Resistant to Inhibition by Avibactam , 2015, Antimicrobial Agents and Chemotherapy.

[22]  R. Bonomo,et al.  Unexpected Challenges in Treating Multidrug-Resistant Gram-Negative Bacteria: Resistance to Ceftazidime-Avibactam in Archived Isolates of Pseudomonas aeruginosa , 2014, Antimicrobial Agents and Chemotherapy.

[23]  S. Solomon,et al.  Antibiotic resistance threats in the United States: stepping back from the brink. , 2014, American family physician.

[24]  A. Oliver,et al.  Pseudomonas aeruginosa Ceftolozane-Tazobactam Resistance Development Requires Multiple Mutations Leading to Overexpression and Structural Modification of AmpC , 2014, Antimicrobial Agents and Chemotherapy.

[25]  S. Mangani,et al.  Structural Insight into Potent Broad-Spectrum Inhibition with Reversible Recyclization Mechanism: Avibactam in Complex with CTX-M-15 and Pseudomonas aeruginosa AmpC β-Lactamases , 2013, Antimicrobial Agents and Chemotherapy.

[26]  R. Bonomo,et al.  Design and exploration of novel boronic acid inhibitors reveals important interactions with a clavulanic acid-resistant sulfhydryl-variable (SHV) β-lactamase. , 2013, Journal of medicinal chemistry.

[27]  R. Bonomo,et al.  Exploring the Role of a Conserved Class A Residue in the Ω-Loop of KPC-2 β-Lactamase , 2012, The Journal of Biological Chemistry.

[28]  D. Ehmann,et al.  Avibactam is a covalent, reversible, non–β-lactam β-lactamase inhibitor , 2012, Proceedings of the National Academy of Sciences.

[29]  Robert A. Bonomo,et al.  Understanding the Molecular Determinants of Substrate and Inhibitor Specificities in the Carbapenemase KPC-2: Exploring the Roles of Arg220 and Glu276 , 2012, Antimicrobial Agents and Chemotherapy.

[30]  Sumudu P. Leelananda,et al.  The importance of slow motions for protein functional loops , 2012, Physical biology.

[31]  R. Bonomo,et al.  Exploring sequence requirements for C3/C4 carboxylate recognition in the Pseudomonas aeruginosa cephalosporinase: Insights into plasticity of the AmpC β‐lactamase , 2011, Protein science : a publication of the Protein Society.

[32]  R. Bonomo,et al.  Ligand-Dependent Disorder of the Ω Loop Observed in Extended-Spectrum SHV-Type β-Lactamase , 2011, Antimicrobial Agents and Chemotherapy.

[33]  Clsi Performance Standards for Antimicrobial Susceptibility Testing: Twenty-First Informational Supplement , 2010 .

[34]  R. Bonomo,et al.  Substrate Selectivity and a Novel Role in Inhibitor Discrimination by Residue 237 in the KPC-2 β-Lactamase , 2010, Antimicrobial Agents and Chemotherapy.

[35]  B. Shoichet,et al.  Structural bases for stability-function tradeoffs in antibiotic resistance. , 2010, Journal of molecular biology.

[36]  R. Bonomo,et al.  Three Decades of β-Lactamase Inhibitors , 2010, Clinical Microbiology Reviews.

[37]  Massimiliano Bonomi,et al.  Reconstructing the equilibrium Boltzmann distribution from well‐tempered metadynamics , 2009, J. Comput. Chem..

[38]  P. Nordmann,et al.  Extended-Spectrum Cephalosporinases in Pseudomonas aeruginosa , 2009, Antimicrobial Agents and Chemotherapy.

[39]  M J Harvey,et al.  ACEMD: Accelerating Biomolecular Dynamics in the Microsecond Time Scale. , 2009, Journal of chemical theory and computation.

[40]  George A. Jacoby,et al.  AmpC β-Lactamases , 2009, Clinical Microbiology Reviews.

[41]  A. Laio,et al.  Metadynamics: a method to simulate rare events and reconstruct the free energy in biophysics, chemistry and material science , 2008 .

[42]  A. Hidrón,et al.  Antimicrobial-Resistant Pathogens Associated With Healthcare-Associated Infections: Annual Summary of Data Reported to the National Healthcare Safety Network at the Centers for Disease Control and Prevention, 2006–2007 , 2008, Infection Control & Hospital Epidemiology.

[43]  K. Itoh,et al.  Synthesis and SAR of novel parenteral anti-pseudomonal cephalosporins: discovery of FR264205. , 2008, Bioorganic & medicinal chemistry letters.

[44]  D. van der Spoel,et al.  GROMACS 4:  Algorithms for Highly Efficient, Load-Balanced, and Scalable Molecular Simulation. , 2008, Journal of chemical theory and computation.

[45]  K. Tateda,et al.  Stability of FR264205 against AmpC β-lactamase of Pseudomonas aeruginosa , 2007 .

[46]  A. Oliver,et al.  Molecular Epidemiology and Mechanisms of Carbapenem Resistance in Pseudomonas aeruginosa Isolates from Spanish Hospitals , 2007, Antimicrobial Agents and Chemotherapy.

[47]  P. Nordmann,et al.  Extended-spectrum cephalosporinases: structure, detection and epidemiology. , 2007, Future microbiology.

[48]  N. Greenfield Using circular dichroism collected as a function of temperature to determine the thermodynamics of protein unfolding and binding interactions , 2006, Nature Protocols.

[49]  Holger Gohlke,et al.  The Amber biomolecular simulation programs , 2005, J. Comput. Chem..

[50]  E. Pérez-Inestrosa,et al.  Cephalosporin chemical reactivity and its immunological implications , 2005, Current opinion in allergy and clinical immunology.

[51]  D. J. Price,et al.  A modified TIP3P water potential for simulation with Ewald summation. , 2004, The Journal of chemical physics.

[52]  M. Page,et al.  Development of a Sensitive and Specific Enzyme-Linked Immunosorbent Assay for Detecting and Quantifying CMY-2 and SHV β-Lactamases , 2002, Journal of Clinical Microbiology.

[53]  Emil Alexov,et al.  Rapid grid‐based construction of the molecular surface and the use of induced surface charge to calculate reaction field energies: Applications to the molecular systems and geometric objects , 2002, J. Comput. Chem..

[54]  Barry Honig,et al.  Extending the Applicability of the Nonlinear Poisson−Boltzmann Equation: Multiple Dielectric Constants and Multivalent Ions† , 2001 .

[55]  L K Pannell,et al.  Role of the omega-loop in the activity, substrate specificity, and structure of class A beta-lactamase. , 1998, Biochemistry.

[56]  S. Mitsuhashi,et al.  Sequences of Homologous β-Lactamases from Clinical Isolates of Serratia marcescens with Different Substrate Specificities , 1998, Antimicrobial Agents and Chemotherapy.

[57]  J. Petrosino,et al.  Systematic mutagenesis of the active site omega loop of TEM-1 beta-lactamase , 1996, Journal of bacteriology.

[58]  A. Laws,et al.  The chemistry and structure-activity relationships of C3-quaternary ammonium cephem antibiotics. , 1996, Journal of chemotherapy.

[59]  K Schulten,et al.  VMD: visual molecular dynamics. , 1996, Journal of molecular graphics.

[60]  Ruben Abagyan,et al.  ICM—A new method for protein modeling and design: Applications to docking and structure prediction from the distorted native conformation , 1994, J. Comput. Chem..

[61]  Pratt Rf,et al.  Mechanism of inhibition of the PC1 .beta.-lactamase of Staphylococcus aureus by cephalosporins: importance of the 3'-leaving group , 1985 .

[62]  H. Berendsen,et al.  Molecular dynamics with coupling to an external bath , 1984 .

[63]  R. Pratt,et al.  ELIMINATION OF A GOOD LEAVING GROUP FROM THE 3′-POSITION OF A CEPHALOSPORIN NEED NOT BE CONCERTED WITH β-LACTAM RING OPENING: TEM-2 β-LACTAMASE-CATALYZED HYDROLYSIS OF PYRIDINE-2-AZO-4′-(N′,N′-DIMETHYLANILINE) CEPHALOSPORIN (PADAC) AN , 1984 .

[64]  R. Pratt,et al.  Elimination of a good leaving group from the 3'-position of a cephalosporin need not be concerted with .beta.-lactam ring opening: TEM-2 .beta.-lactamase-catalyzed hydrolysis of pyridine-2-azo-4'-(N',N'-dimethylaniline) cephalosporin (PADAC) and of cephaloridine , 1984 .

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

[66]  R. Pratt,et al.  Mechanism of inhibition of the PC1 beta-lactamase of Staphylococcus aureus by cephalosporins: importance of the 3'-leaving group. , 1985, Biochemistry.