5gld Citations

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)
Related entries: 5gl9, 5gla, 5glb, 5glc

Cited: 8 times
EuropePMC logo PMID: 27827433

Abstract

The omega loop in β-lactamases plays a pivotal role in substrate recognition and catalysis, and some mutations in this loop affect the adaptability of the enzymes to new antibiotics. Various mutations, including substitutions, deletions, and intragenic duplications resulting in tandem repeats (TRs), have been associated with β-lactamase substrate spectrum extension. TRs are unique among the mutations as they cause severe structural perturbations in the enzymes. We explored the process by which TRs are accommodated in order to test the adaptability of the omega loop. Structures of the mutant enzymes showed that the extra amino acid residues in the omega loop were freed outward from the enzyme, thereby maintaining the overall enzyme integrity. This structural adjustment was accompanied by disruptions of the internal α-helix and hydrogen bonds that originally maintained the conformation of the omega loop and the active site. Consequently, the mutant enzymes had a relaxed binding cavity, allowing for access of new substrates, which regrouped upon substrate binding in an induced-fit manner for subsequent hydrolytic reactions. Together, the data demonstrate that the design of the binding cavity, including the omega loop with its enormous adaptive capacity, is the foundation of the continuous evolution of β-lactamases against new drugs.

Articles - 5gld mentioned but not cited (1)

  1. 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)


Reviews citing this publication (1)

  1. Predicting allostery and microbial drug resistance with molecular simulations. Cortina GA, Kasson PM. Curr Opin Struct Biol 52 80-86 (2018)

Articles citing this publication (6)

  1. KPC Beta-Lactamases Are Permissive to Insertions and Deletions Conferring Substrate Spectrum Modifications and Resistance to Ceftazidime-Avibactam. Hobson CA, Bonacorsi S, Jacquier H, Choudhury A, Magnan M, Cointe A, Bercot B, Tenaillon O, Birgy A. Antimicrob Agents Chemother 64 e01175-20 (2020)
  2. Structure-function analysis of Lactiplantibacillus plantarum DltE reveals D-alanylated lipoteichoic acids as direct cues supporting Drosophila juvenile growth. Nikolopoulos N, Matos RC, Ravaud S, Courtin P, Akherraz H, Palussiere S, Gueguen-Chaignon V, Salomon-Mallet M, Guillot A, Guerardel Y, Chapot-Chartier MP, Grangeasse C, Leulier F. Elife 12 e84669 (2023)
  3. Increased Antimicrobial Resistance in a Novel CMY-54 AmpC-Type Enzyme with a GluLeu217-218 Insertion in the Ω-Loop. Pérez-Llarena FJ, Vázquez-Ucha JC, Kerff F, Zamorano L, Miró E, Cabral MP, Fleites A, Lantero M, Martínez-Martínez L, Oliver A, Galleni M, Navarro F, Beceiro A, Bou G. Microb Drug Resist 24 527-533 (2018)
  4. Inhibition of the Clostridioides difficile Class D β-Lactamase CDD-1 by Avibactam. Stewart NK, Toth M, Stasyuk A, Lee M, Smith CA, Vakulenko SB. ACS Infect Dis 7 1164-1176 (2021)
  5. Heterogeneity in M. tuberculosis β-lactamase inhibition by Sulbactam. Malla TN, Zielinski K, Aldama L, Bajt S, Feliz D, Hayes B, Hunter M, Kupitz C, Lisova S, Knoska J, Martin-Garcia JM, Mariani V, Pandey S, Poudyal I, Sierra RG, Tolstikova A, Yefanov O, Yoon CH, Ourmazd A, Fromme P, Schwander P, Barty A, Chapman HN, Stojkovic EA, Batyuk A, Boutet S, Phillips GN, Pollack L, Schmidt M. Nat Commun 14 5507 (2023)
  6. Non-catalytic-Region Mutations Conferring Transition of Class A β-Lactamases Into ESBLs. Cao TP, Yi H, Dhanasingh I, Ghosh S, Choi JM, Lee KH, Ryu S, Kim HS, Lee SH. Front Mol Biosci 7 598998 (2020)


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