4rva Citations

A triple mutant in the Ω-loop of TEM-1 β-lactamase changes the substrate profile via a large conformational change and an altered general base for catalysis.

Stojanoski V, Chow DC, Hu L, Sankaran B, Gilbert HF, Prasad BV, Palzkill T
J Biol Chem 290 10382-94 (2015)
Related entries: 4rx2, 4rx3

Cited: 29 times
EuropePMC logo PMID: 25713062

Abstract

β-Lactamases are bacterial enzymes that hydrolyze β-lactam antibiotics. TEM-1 is a prevalent plasmid-encoded β-lactamase in Gram-negative bacteria that efficiently catalyzes the hydrolysis of penicillins and early cephalosporins but not oxyimino-cephalosporins. A previous random mutagenesis study identified a W165Y/E166Y/P167G triple mutant that displays greatly altered substrate specificity with increased activity for the oxyimino-cephalosporin, ceftazidime, and decreased activity toward all other β-lactams tested. Surprisingly, this mutant lacks the conserved Glu-166 residue critical for enzyme function. Ceftazidime contains a large, bulky side chain that does not fit optimally in the wild-type TEM-1 active site. Therefore, it was hypothesized that the substitutions in the mutant expand the binding site in the enzyme. To investigate structural changes and address whether there is an enlargement in the active site, the crystal structure of the triple mutant was solved to 1.44 Å. The structure reveals a large conformational change of the active site Ω-loop structure to create additional space for the ceftazidime side chain. The position of the hydroxyl group of Tyr-166 and an observed shift in the pH profile of the triple mutant suggests that Tyr-166 participates in the hydrolytic mechanism of the enzyme. These findings indicate that the highly conserved Glu-166 residue can be substituted in the mechanism of serine β-lactamases. The results reveal that the robustness of the overall β-lactamase fold coupled with the plasticity of an active site loop facilitates the evolution of enzyme specificity and mechanism.

Articles - 4rva mentioned but not cited (2)

  1. A triple mutant in the Ω-loop of TEM-1 β-lactamase changes the substrate profile via a large conformational change and an altered general base for catalysis. Stojanoski V, Chow DC, Hu L, Sankaran B, Gilbert HF, Prasad BV, Palzkill T. J Biol Chem 290 10382-10394 (2015)
  2. The Drug-Resistant Variant P167S Expands the Substrate Profile of CTX-M β-Lactamases for Oxyimino-Cephalosporin Antibiotics by Enlarging the Active Site upon Acylation. Patel MP, Hu L, Stojanoski V, Sankaran B, Prasad BVV, Palzkill T. Biochemistry 56 3443-3453 (2017)


Reviews citing this publication (2)

  1. Structural and Mechanistic Basis for Extended-Spectrum Drug-Resistance Mutations in Altering the Specificity of TEM, CTX-M, and KPC β-lactamases. Palzkill T. Front Mol Biosci 5 16 (2018)
  2. The Role of the Ω-Loop in Regulation of the Catalytic Activity of TEM-Type β-Lactamases. Egorov A, Rubtsova M, Grigorenko V, Uporov I, Veselovsky A. Biomolecules 9 E854 (2019)

Articles citing this publication (25)

  1. Natural Variants of the KPC-2 Carbapenemase have Evolved Increased Catalytic Efficiency for Ceftazidime Hydrolysis at the Cost of Enzyme Stability. Mehta SC, Rice K, Palzkill T. PLoS Pathog 11 e1004949 (2015)
  2. 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. Barnes MD, Winkler ML, Taracila MA, Page MG, Desarbre E, Kreiswirth BN, Shields RK, Nguyen MH, Clancy C, Spellberg B, Papp-Wallace KM, Bonomo RA. mBio 8 e00528-17 (2017)
  3. Structural Basis for Different Substrate Profiles of Two Closely Related Class D β-Lactamases and Their Inhibition by Halogens. Stojanoski V, Chow DC, Fryszczyn B, Hu L, Nordmann P, Poirel L, Sankaran B, Prasad BV, Palzkill T. Biochemistry 54 3370-3380 (2015)
  4. Crystallographic Snapshots of Class A β-Lactamase Catalysis Reveal Structural Changes That Facilitate β-Lactam Hydrolysis. Pan X, He Y, Lei J, Huang X, Zhao Y. J Biol Chem 292 4022-4033 (2017)
  5. Removal of the Side Chain at the Active-Site Serine by a Glycine Substitution Increases the Stability of a Wide Range of Serine β-Lactamases by Relieving Steric Strain. Stojanoski V, Adamski CJ, Hu L, Mehta SC, Sankaran B, Zwart P, Prasad BV, Palzkill T. Biochemistry 55 2479-2490 (2016)
  6. Cryptic β-Lactamase Evolution Is Driven by Low β-Lactam Concentrations. Fröhlich C, Gama JA, Harms K, Hirvonen VHA, Lund BA, van der Kamp MW, Johnsen PJ, Samuelsen Ø, Leiros HS. mSphere 6 e00108-21 (2021)
  7. The hydrolytic water molecule of Class A β-lactamase relies on the acyl-enzyme intermediate ES* for proper coordination and catalysis. He Y, Lei J, Pan X, Huang X, Zhao Y. Sci Rep 10 10205 (2020)
  8. Antagonism between substitutions in β-lactamase explains a path not taken in the evolution of bacterial drug resistance. Brown CA, Hu L, Sun Z, Patel MP, Singh S, Porter JR, Sankaran B, Prasad BVV, Bowman GR, Palzkill T. J Biol Chem 295 7376-7390 (2020)
  9. Enzymatic protein switches built from paralogous input domains. Tullman J, Nicholes N, Dumont MR, Ribeiro LF, Ostermeier M. Biotechnol Bioeng 113 852-858 (2016)
  10. Machine Learning Classification Model for Functional Binding Modes of TEM-1 β-Lactamase. Wang F, Shen L, Zhou H, Wang S, Wang X, Tao P. Front Mol Biosci 6 47 (2019)
  11. Evolving Bacterial Fitness with an Expanded Genetic Code. Tack DS, Cole AC, Shroff R, Morrow BR, Ellington AD. Sci Rep 8 3288 (2018)
  12. High adaptability of the omega loop underlies the substrate-spectrum-extension evolution of a class A β-lactamase, PenL. Yi H, Choi JM, Hwang J, Prati F, Cao TP, Lee SH, Kim HS. Sci Rep 6 36527 (2016)
  13. ΔFlucs: Brighter Photinus pyralis firefly luciferases identified by surveying consecutive single amino acid deletion mutations in a thermostable variant. Halliwell LM, Jathoul AP, Bate JP, Worthy HL, Anderson JC, Jones DD, Murray JAH. Biotechnol Bioeng 115 50-59 (2018)
  14. Multitarget selection of catalytic antibodies with β-lactamase activity using phage display. Shahsavarian MA, Chaaya N, Costa N, Boquet D, Atkinson A, Offmann B, Kaveri SV, Lacroix-Desmazes S, Friboulet A, Avalle B, Padiolleau-Lefèvre S. FEBS J 284 634-653 (2017)
  15. A topological data analytic approach for discovering biophysical signatures in protein dynamics. Tang WS, da Silva GM, Kirveslahti H, Skeens E, Feng B, Sudijono T, Yang KK, Mukherjee S, Rubenstein B, Crawford L. PLoS Comput Biol 18 e1010045 (2022)
  16. C6 Hydroxymethyl-Substituted Carbapenem MA-1-206 Inhibits the Major Acinetobacter baumannii Carbapenemase OXA-23 by Impeding Deacylation. Stewart NK, Toth M, Alqurafi MA, Chai W, Nguyen TQ, Quan P, Lee M, Buynak JD, Smith CA, Vakulenko SB. mBio 13 e0036722 (2022)
  17. Glutamate residues at positions 162 and 164 influence the beta-lactamase activity of SHV-14 obtained from Klebsiella pneumoniae. Kumar G, Biswal S, Nathan S, Ghosh AS. FEMS Microbiol Lett 365 (2018)
  18. An in vivo selection system with tightly regulated gene expression enables directed evolution of highly efficient enzymes. Nearmnala P, Thanaburakorn M, Panbangred W, Chaiyen P, Hongdilokkul N. Sci Rep 11 11669 (2021)
  19. Evaluation of Tebipenem Hydrolysis by β-Lactamases Prevalent in Complicated Urinary Tract Infections. Sun Z, Su L, Cotroneo N, Critchley I, Pucci M, Jain A, Palzkill T. Antimicrob Agents Chemother 66 e0239621 (2022)
  20. Mapping the determinants of catalysis and substrate specificity of the antibiotic resistance enzyme CTX-M β-lactamase. Judge A, Hu L, Sankaran B, Van Riper J, Venkataram Prasad BV, Palzkill T. Commun Biol 6 35 (2023)
  21. Pareto Optimization of Combinatorial Mutagenesis Libraries. Verma D, Grigoryan G, Bailey-Kellogg C. IEEE/ACM Trans Comput Biol Bioinform 16 1143-1153 (2019)
  22. Revisiting the hydrolysis of ampicillin catalyzed by Temoneira-1 β-lactamase, and the effect of Ni(II), Cd(II) and Hg(II). Nafaee ZH, Egyed V, Jancsó A, Tóth A, Gerami AM, Dang TT, Heiniger-Schell J, Hemmingsen L, Hunyadi-Gulyás É, Peintler G, Gyurcsik B. Protein Sci 32 e4809 (2023)
  23. Toho-1 β-lactamase: backbone chemical shift assignments and changes in dynamics upon binding with avibactam. Sakhrani VV, Ghosh RK, Hilario E, Weiss KL, Coates L, Mueller LJ. J Biomol NMR 75 303-318 (2021)
  24. A novel strategy to characterize the pattern of β-lactam antibiotic-induced drug resistance in Acinetobacter baumannii. Hillyer T, Benin BM, Sun C, Aguirre N, Willard B, Sham YY, Shin WS. Sci Rep 13 9177 (2023)
  25. Natural protein engineering in the Ω-loop: the role of Y221 in ceftazidime and ceftolozane resistance in Pseudomonas-derived cephalosporinase. Mack AR, Kumar V, Taracila MA, Mojica MF, O'Shea M, Schinabeck W, Silver G, Hujer AM, Papp-Wallace KM, Chen S, Haider S, Caselli E, Prati F, van den Akker F, Bonomo RA. Antimicrob Agents Chemother 67 e0079123 (2023)


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