Penicillin's catalytic mechanism revealed by inelastic neutrons and quantum chemical theory

Zoltán Mucsi; Gregory A. Chass; Péter Ábrányi-Balogh; Balázs Jójárt; De Cai Fang; Annibal J. Ramirez-Cuesta; Béla Viskolcz; Imre G. Csizmadia

doi:10.1039/c3cp50868d

Penicillin's catalytic mechanism revealed by inelastic neutrons and quantum chemical theory

Zoltán Mucsi
, Gregory A. Chass
, Péter Ábrányi-Balogh
, Balázs Jójárt
, De Cai Fang
, Annibal J. Ramirez-Cuesta
, Béla Viskolcz
, Imre G. Csizmadia

Research output: Contribution to journal › Article › peer-review

27 Scopus citations

Abstract

Penicillin, travels through bodily fluids, targeting and acylatively inactivating enzymes responsible for cell-wall synthesis in gram-positive bacteria. Somehow, it avoids metabolic degradation remaining inactive en route. To resolve this ability to switch from a non-active, to a highly reactive form, we investigated the dynamic structure-activity relationship of penicillin by inelastic neutron spectroscopy, reaction kinetics, NMR and multi-scale theoretical modelling (QM/MM and post-HF ab initio). Results show that by a self-activating physiological pH-dependent two-step proton-mediated process, penicillin changes geometry to activate its irreversibly reactive acylation, facilitated by systemic intramolecular energy management and cooperative vibrations. This dynamic mechanism is confirmed by the first ever reported characterisation of an antibiotic by neutrons, achieved on the TOSCA instrument (ISIS facility, RAL, UK).

Original language	English
Pages (from-to)	20447-20455
Number of pages	9
Journal	Physical Chemistry Chemical Physics
Volume	15
Issue number	47
DOIs	https://doi.org/10.1039/c3cp50868d
State	Published - Dec 21 2013
Externally published	Yes

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title = "Penicillin's catalytic mechanism revealed by inelastic neutrons and quantum chemical theory",

abstract = "Penicillin, travels through bodily fluids, targeting and acylatively inactivating enzymes responsible for cell-wall synthesis in gram-positive bacteria. Somehow, it avoids metabolic degradation remaining inactive en route. To resolve this ability to switch from a non-active, to a highly reactive form, we investigated the dynamic structure-activity relationship of penicillin by inelastic neutron spectroscopy, reaction kinetics, NMR and multi-scale theoretical modelling (QM/MM and post-HF ab initio). Results show that by a self-activating physiological pH-dependent two-step proton-mediated process, penicillin changes geometry to activate its irreversibly reactive acylation, facilitated by systemic intramolecular energy management and cooperative vibrations. This dynamic mechanism is confirmed by the first ever reported characterisation of an antibiotic by neutrons, achieved on the TOSCA instrument (ISIS facility, RAL, UK).",

author = "Zolt{\'a}n Mucsi and Chass, \{Gregory A.\} and P{\'e}ter {\'A}br{\'a}nyi-Balogh and Bal{\'a}zs J{\'o}j{\'a}rt and Fang, \{De Cai\} and Ramirez-Cuesta, \{Annibal J.\} and B{\'e}la Viskolcz and Csizmadia, \{Imre G.\}",

year = "2013",

month = dec,

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doi = "10.1039/c3cp50868d",

language = "English",

volume = "15",

pages = "20447--20455",

journal = "Physical Chemistry Chemical Physics",

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publisher = "Royal Society of Chemistry",

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TY - JOUR

T1 - Penicillin's catalytic mechanism revealed by inelastic neutrons and quantum chemical theory

AU - Mucsi, Zoltán

AU - Chass, Gregory A.

AU - Ábrányi-Balogh, Péter

AU - Jójárt, Balázs

AU - Fang, De Cai

AU - Ramirez-Cuesta, Annibal J.

AU - Viskolcz, Béla

AU - Csizmadia, Imre G.

PY - 2013/12/21

Y1 - 2013/12/21

N2 - Penicillin, travels through bodily fluids, targeting and acylatively inactivating enzymes responsible for cell-wall synthesis in gram-positive bacteria. Somehow, it avoids metabolic degradation remaining inactive en route. To resolve this ability to switch from a non-active, to a highly reactive form, we investigated the dynamic structure-activity relationship of penicillin by inelastic neutron spectroscopy, reaction kinetics, NMR and multi-scale theoretical modelling (QM/MM and post-HF ab initio). Results show that by a self-activating physiological pH-dependent two-step proton-mediated process, penicillin changes geometry to activate its irreversibly reactive acylation, facilitated by systemic intramolecular energy management and cooperative vibrations. This dynamic mechanism is confirmed by the first ever reported characterisation of an antibiotic by neutrons, achieved on the TOSCA instrument (ISIS facility, RAL, UK).

AB - Penicillin, travels through bodily fluids, targeting and acylatively inactivating enzymes responsible for cell-wall synthesis in gram-positive bacteria. Somehow, it avoids metabolic degradation remaining inactive en route. To resolve this ability to switch from a non-active, to a highly reactive form, we investigated the dynamic structure-activity relationship of penicillin by inelastic neutron spectroscopy, reaction kinetics, NMR and multi-scale theoretical modelling (QM/MM and post-HF ab initio). Results show that by a self-activating physiological pH-dependent two-step proton-mediated process, penicillin changes geometry to activate its irreversibly reactive acylation, facilitated by systemic intramolecular energy management and cooperative vibrations. This dynamic mechanism is confirmed by the first ever reported characterisation of an antibiotic by neutrons, achieved on the TOSCA instrument (ISIS facility, RAL, UK).

UR - https://www.scopus.com/pages/publications/84887979724

U2 - 10.1039/c3cp50868d

DO - 10.1039/c3cp50868d

M3 - Article

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AN - SCOPUS:84887979724

SN - 1463-9076

VL - 15

SP - 20447

EP - 20455

JO - Physical Chemistry Chemical Physics

JF - Physical Chemistry Chemical Physics

IS - 47

ER -

Penicillin's catalytic mechanism revealed by inelastic neutrons and quantum chemical theory

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