Crystallographic, spectroscopic, and computational analysis of a flavin C4a-oxygen adduct in choline oxidase

Allen M Orville; George T Lountos; Steffan Finnegan; Giovanni Gadda; Rajeev Prabhakar

doi:10.1021/bi801918u

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Crystallographic, spectroscopic, and computational analysis of a flavin C4a-oxygen adduct in choline oxidase

Journal article

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Peer reviewed

Crystallographic, spectroscopic, and computational analysis of a flavin C4a-oxygen adduct in choline oxidase

Allen M Orville, George T Lountos, Steffan Finnegan, Giovanni Gadda and Rajeev Prabhakar

Biochemistry (Easton), Vol.48(4), pp.720-728

2009-02-03

DOI: https://doi.org/10.1021/bi801918u

PMCID: PMC2646362

PMID: 19133805

Abstract

Flavin-Adenine Dinucleotide - chemistry

Flavoproteins - chemistry

Computational Biology - methods

Spectrometry, X-Ray Emission - methods

Flavoproteins - metabolism

Bacterial Proteins - chemistry

Alcohol Oxidoreductases - metabolism

Flavin-Adenine Dinucleotide - analysis

Bacterial Proteins - analysis

Oxygen - metabolism

Oxygen - analysis

Crystallography, X-Ray - methods

Flavin-Adenine Dinucleotide - metabolism

Alcohol Oxidoreductases - chemistry

Alcohol Oxidoreductases - analysis

Binding Sites - physiology

Oxygen - chemistry

Flavins - analysis

Flavoproteins - analysis

Protein Structure, Secondary - physiology

Bacterial Proteins - metabolism

Flavins - chemistry

Arthrobacter - enzymology

Flavins - metabolism

Flavin C4a-OO(H) and C4a-OH adducts are critical intermediates proposed in many flavoenzyme reaction mechanisms, but they are rarely detected even by rapid transient kinetics methods. We observe a trapped flavin C4a-OH or C4a-OO(H) adduct by single-crystal spectroscopic methods and in the 1.86 A resolution X-ray crystal structure of choline oxidase. The microspectrophotometry results show that the adduct forms rapidly in situ at 100 K upon exposure to X-rays. Density functional theory calculations establish the electronic structures for the flavin C4a-OH and C4a-OO(H) adducts and estimate the stabilization energy of several active site hydrogen bonds deduced from the crystal structure. We propose that the enzyme-bound FAD is reduced in the X-ray beam. The aerobic crystals then form either a C4a-OH or C4a-OO(H) adduct, but an insufficient proton inventory prevents their decay at cryogenic temperatures.

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Collaboration types: Domestic collaboration
Citation topics: 3 Agriculture, Environment & Ecology; 3.4 Crop Science; 3.4.1499 Phytochrome
Web Of Science research areas: Biochemistry & Molecular Biology
ESI research areas: Biology & Biochemistry

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Title: Crystallographic, spectroscopic, and computational analysis of a flavin C4a-oxygen adduct in choline oxidase
Creators: Allen M Orville - Biology Department, Brookhaven National Laboratory, Upton, New York 11973-5000, School of Chemistry and Biochemistry, Georgia Institute of Technology, Atlanta, Georgia 30332-0400, USA. amorv@bnl.gov
George T Lountos
Steffan Finnegan
Giovanni Gadda
Rajeev Prabhakar
Publication Details: Biochemistry (Easton), Vol.48(4), pp.720-728
Publisher: United States
Grant note: P30 EB009998 / NIBIB NIH HHS P41 RR012408 / NCRR NIH HHS P41 RR012408-12 / NCRR NIH HHS 2 P41 RR012408 / NCRR NIH HHS
Academic Unit: College of A&S; A&S - Chemistry
Language: English
Resource Type: Journal article
PMID: 19133805
PMCID: PMC2646362
Record Identifier: 991031559007802976