On the Role of Histidine 351 in the Reaction of Alcohol Oxidation Catalyzed by Choline Oxidase

Choline oxidase catalyzes the four-electron, flavin-linked oxidation of choline to glycine betaine with transient formation of an enzyme-bound aldehyde intermediate. The recent determination of the crystal structure of choline oxidase to a resolution of 1.86 Å established the presence of two histidi...

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Bibliographic Details
Published inBiochemistry (Easton) Vol. 47; no. 26; pp. 6762 - 6769
Main Authors Rungsrisuriyachai, Kunchala, Gadda, Giovanni
Format Journal Article
LanguageEnglish
Published United States American Chemical Society 01.07.2008
Subjects
Alcohol Oxidoreductases - chemistry
Alcohol Oxidoreductases - genetics
Alcohol Oxidoreductases - metabolism
Alcohols - metabolism
Arthrobacter - enzymology
Arthrobacter - genetics
Betaine - analogs & derivatives
Betaine - metabolism
Binding Sites
Catalysis
Choline - metabolism
Histidine - genetics
Histidine - metabolism
Hydrogen-Ion Concentration
Kinetics
Models, Molecular
Molecular Structure
Oxidation-Reduction
Substrate Specificity
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Summary:Choline oxidase catalyzes the four-electron, flavin-linked oxidation of choline to glycine betaine with transient formation of an enzyme-bound aldehyde intermediate. The recent determination of the crystal structure of choline oxidase to a resolution of 1.86 Å established the presence of two histidine residues in the active site, which may participate in catalysis. His466 was the subject of a previous study [Ghanem, M., and Gadda, G. (2005) Biochemistry 44, 893−904]. In this study, His351 was replaced with alanine using site-directed mutagenesis, and the resulting mutant enzyme was purified and characterized in its mechanistic properties. The results presented establish that His351 contributes to substrate binding and positioning and stabilizes the transition state for the hydride transfer reaction to the flavin, as suggested by anaerobic substrate reduction stopped-flow data. Furthermore, His351 contributes to the overall polarity of the active site by modulating the pK a of the group that deprotonates choline to the alkoxide species, as indicated by pH profiles of the steady-state kinetic parameters with the substrate or a competitive inhibitor. Surprisingly, His351 is not involved in the activation of the reduced flavin for reaction with oxygen. The latter observation, along with previous mutagenesis data on His466, allow us to conclude that choline oxidase must necessarily utilize a strategy for oxygen reduction different from that established for glucose oxidase, where other authors showed that the catalytic effect almost entirely arises from a protonated histidine residue.
Bibliography:ark:/67375/TPS-S5GDCDQZ-N
Figure S1 shows the UV−visible absorbance spectrum of the His351Ala enzyme as purified. Table S1 shows the observed rates and amplitudes of the changes at 453 nm associated with the anaerobic flavin reduction of the His351Ala enzyme with choline or betaine aldehyde as substrate at pH 10, 25 °C. Table S2 shows the steady-state kinetic parameters with choline as a substrate for the data presented in Figure A,B. Table S3 shows the apparent steady-state kinetic parameters for the data presented in Figure C. This material is available free of charge via the Internet at http://pubs.acs.org.
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ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:0006-2960
1520-4995
1520-4995
DOI:10.1021/bi800650w