2018
DOI: 10.1038/s41598-018-31176-0
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Defining the architecture of KPC-2 Carbapenemase: identifying allosteric networks to fight antibiotics resistance

Abstract: The rise of multi-drug resistance in bacterial pathogens is one of the grand challenges facing medical science. A major concern is the speed of development of β-lactamase-mediated resistance in Gram-negative species, thus putting at risk the efficacy of the most recently approved antibiotics and inhibitors, including carbapenems and avibactam, respectively. New strategies to overcome resistance are urgently required, which will ultimately be facilitated by a deeper understanding of the mechanisms that regulate… Show more

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Cited by 33 publications
(49 citation statements)
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“…In simulations of carbapenem acylenzyme complexes, committor analysis identifies the conformation of the Trp105 loop as one factor differentiating so-called “permissive” conformations (in which the β-lactam acylenzyme carbonyl occupies the oxyanion hole and the deacylating water is present) from “non-permissive” conformations with the carbonyl outside the oxyanion hole and the deacylating water absent [74]. In multiple-replica parallel tempering metadynamics simulations, that access timescales not available through conventional methodologies, unliganded KPC is shown to undergo motions of active site regions, including Trp105 and the omega-loop containing Glu166, that are related to hydrophobic networks in the individual α and α/β domains and that direct interactions with substrates [75]. Experimental studies of site-directed mutants support these findings by identifying Trp105 as a determinant of KPC activity [71].…”
Section: Class a β-Lactamasesmentioning
confidence: 99%
“…In simulations of carbapenem acylenzyme complexes, committor analysis identifies the conformation of the Trp105 loop as one factor differentiating so-called “permissive” conformations (in which the β-lactam acylenzyme carbonyl occupies the oxyanion hole and the deacylating water is present) from “non-permissive” conformations with the carbonyl outside the oxyanion hole and the deacylating water absent [74]. In multiple-replica parallel tempering metadynamics simulations, that access timescales not available through conventional methodologies, unliganded KPC is shown to undergo motions of active site regions, including Trp105 and the omega-loop containing Glu166, that are related to hydrophobic networks in the individual α and α/β domains and that direct interactions with substrates [75]. Experimental studies of site-directed mutants support these findings by identifying Trp105 as a determinant of KPC activity [71].…”
Section: Class a β-Lactamasesmentioning
confidence: 99%
“…Thus, ESBLs confer multiresistance to these antibiotics and related oxyimino-beta lactams, which play an important role in antibiotic resistance in E. coli . KPC is another key enzyme in MDR, due to its ability to hydrolyze a broad variety of β-lactams, including carbapenems, cephalosporins and penicillins [26]. Interestingly, ESBL gene were not detected by VITEK 2 Compact System, highlighting its flaws in clinical setting.
Fig.
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Section: Resultsmentioning
confidence: 99%
“…Nosocomial pathogens having multidrug resistance (MDR) or pandemic drug resistance (PDR) traits usually represent a paradigm in pathogenesis and responsible for life-threatening diseases in human 54,55 . The non-judicial usage of available antibiotics remains as the main reason for the crisis of having significant and effective antibiotic against resistance pathogens [8][9][10] .…”
Section: Discussionmentioning
confidence: 99%