Electron Transfer in Acetohydroxy Acid Synthase as a Side Reaction of Catalysis. Implications for the Reactivity and Partitioning of the Carbanion/Enamine Form of (α-Hydroxyethyl)thiamin Diphosphate in a “Nonredox” Flavoenzyme

Acetohydroxy acid synthases (AHAS) are thiamin diphosphate- (ThDP-) and FAD-dependent enzymes that catalyze the first common step of branched-chain amino acid biosynthesis in plants, bacteria, and fungi. Although the flavin cofactor is not chemically involved in the physiological reaction of AHAS, i...

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Published in	Biochemistry (Easton) Vol. 43; no. 27; pp. 8652 - 8661
Main Authors	Tittmann, Kai, Schröder, Kathrin, Golbik, Ralph, McCourt, Jennifer, Kaplun, Alexander, Duggleby, Ronald G, Barak, Ze'ev, Chipman, David M, Hübner, Gerhard
Format	Journal Article
Language	English
Published	United States American Chemical Society 13.07.2004
Subjects	Acetolactate Synthase - chemistry Acetolactate Synthase - metabolism Catalysis Electron Transport Flavin-Adenine Dinucleotide - metabolism Kinetics Magnetic Resonance Spectroscopy Models, Molecular Molecular Structure Oxygen - metabolism Pyruvic Acid - metabolism Spectrum Analysis Thiamine Pyrophosphate - analogs & derivatives Thiamine Pyrophosphate - chemistry Thiamine Pyrophosphate - metabolism
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Abstract	Acetohydroxy acid synthases (AHAS) are thiamin diphosphate- (ThDP-) and FAD-dependent enzymes that catalyze the first common step of branched-chain amino acid biosynthesis in plants, bacteria, and fungi. Although the flavin cofactor is not chemically involved in the physiological reaction of AHAS, it has been shown to be essential for the structural integrity and activity of the enzyme. Here, we report that the enzyme-bound FAD in AHAS is reduced in the course of catalysis in a side reaction. The reduction of the enzyme-bound flavin during turnover of different substrates under aerobic and anaerobic conditions was characterized by stopped-flow kinetics using the intrinsic FAD absorbance. Reduction of enzyme-bound FAD proceeds with a net rate constant of k‘ = 0.2 s-1 in the presence of oxygen and approximately 1 s-1 under anaerobic conditions. No transient flavin radicals are detectable during the reduction process while time-resolved absorbance spectra are recorded. Reconstitution of the binary enzyme−FAD complex with the chemically synthesized intermediate 2-(hydroxyethyl)-ThDP also results in a reduction of the flavin. These data provide evidence for the first time that the key catalytic intermediate 2-(hydroxyethyl)-ThDP in the carbanionic/enamine form is not only subject to covalent addition of 2-keto acids and an oxygenase side reaction but also transfers electrons to the adjacent FAD in an intramolecular redox reaction yielding 2-acetyl-ThDP and reduced FAD. The detection of the electron transfer supports the idea of a common ancestor of acetohydroxy acid synthase and pyruvate oxidase, a homologous ThDP- and FAD-dependent enzyme that, in contrast to AHASs, catalyzes a reaction that relies on intercofactor electron transfer.
AbstractList	Acetohydroxy acid synthases (AHAS) are thiamin diphosphate- (ThDP-) and FAD-dependent enzymes that catalyze the first common step of branched-chain amino acid biosynthesis in plants, bacteria, and fungi. Although the flavin cofactor is not chemically involved in the physiological reaction of AHAS, it has been shown to be essential for the structural integrity and activity of the enzyme. Here, we report that the enzyme-bound FAD in AHAS is reduced in the course of catalysis in a side reaction. The reduction of the enzyme-bound flavin during turnover of different substrates under aerobic and anaerobic conditions was characterized by stopped-flow kinetics using the intrinsic FAD absorbance. Reduction of enzyme-bound FAD proceeds with a net rate constant of k' = 0.2 s(-1) in the presence of oxygen and approximately 1 s(-1) under anaerobic conditions. No transient flavin radicals are detectable during the reduction process while time-resolved absorbance spectra are recorded. Reconstitution of the binary enzyme-FAD complex with the chemically synthesized intermediate 2-(hydroxyethyl)-ThDP also results in a reduction of the flavin. These data provide evidence for the first time that the key catalytic intermediate 2-(hydroxyethyl)-ThDP in the carbanionic/enamine form is not only subject to covalent addition of 2-keto acids and an oxygenase side reaction but also transfers electrons to the adjacent FAD in an intramolecular redox reaction yielding 2-acetyl-ThDP and reduced FAD. The detection of the electron transfer supports the idea of a common ancestor of acetohydroxy acid synthase and pyruvate oxidase, a homologous ThDP- and FAD-dependent enzyme that, in contrast to AHASs, catalyzes a reaction that relies on intercofactor electron transfer. Acetohydroxy acid synthases (AHAS) are thiamin diphosphate- (ThDP-) and FAD-dependent enzymes that catalyze the first common step of branched-chain amino acid biosynthesis in plants, bacteria, and fungi. Although the flavin cofactor is not chemically involved in the physiological reaction of AHAS, it has been shown to be essential for the structural integrity and activity of the enzyme. Here, we report that the enzyme-bound FAD in AHAS is reduced in the course of catalysis in a side reaction. The reduction of the enzyme-bound flavin during turnover of different substrates under aerobic and anaerobic conditions was characterized by stopped-flow kinetics using the intrinsic FAD absorbance. Reduction of enzyme-bound FAD proceeds with a net rate constant of k‘ = 0.2 s-1 in the presence of oxygen and approximately 1 s-1 under anaerobic conditions. No transient flavin radicals are detectable during the reduction process while time-resolved absorbance spectra are recorded. Reconstitution of the binary enzyme−FAD complex with the chemically synthesized intermediate 2-(hydroxyethyl)-ThDP also results in a reduction of the flavin. These data provide evidence for the first time that the key catalytic intermediate 2-(hydroxyethyl)-ThDP in the carbanionic/enamine form is not only subject to covalent addition of 2-keto acids and an oxygenase side reaction but also transfers electrons to the adjacent FAD in an intramolecular redox reaction yielding 2-acetyl-ThDP and reduced FAD. The detection of the electron transfer supports the idea of a common ancestor of acetohydroxy acid synthase and pyruvate oxidase, a homologous ThDP- and FAD-dependent enzyme that, in contrast to AHASs, catalyzes a reaction that relies on intercofactor electron transfer. Acetohydroxy acid synthases (AHAS) are thiamin diphosphate- (ThDP-) and FAD-dependent enzymes that catalyze the first common step of branched-chain amino acid biosynthesis in plants, bacteria, and fungi. Although the flavin cofactor is not chemically involved in the physiological reaction of AHAS, it has been shown to be essential for the structural integrity and activity of the enzyme. Here, we report that the enzyme-bound FAD in AHAS is reduced in the course of catalysis in a side reaction. The reduction of the enzyme-bound flavin during turnover of different substrates under aerobic and anaerobic conditions was characterized by stopped-flow kinetics using the intrinsic FAD absorbance. Reduction of enzyme-bound FAD proceeds with a net rate constant of k' = 0.2 s(-1) in the presence of oxygen and approximately 1 s(-1) under anaerobic conditions. No transient flavin radicals are detectable during the reduction process while time-resolved absorbance spectra are recorded. Reconstitution of the binary enzyme-FAD complex with the chemically synthesized intermediate 2-(hydroxyethyl)-ThDP also results in a reduction of the flavin. These data provide evidence for the first time that the key catalytic intermediate 2-(hydroxyethyl)-ThDP in the carbanionic/enamine form is not only subject to covalent addition of 2-keto acids and an oxygenase side reaction but also transfers electrons to the adjacent FAD in an intramolecular redox reaction yielding 2-acetyl-ThDP and reduced FAD. The detection of the electron transfer supports the idea of a common ancestor of acetohydroxy acid synthase and pyruvate oxidase, a homologous ThDP- and FAD-dependent enzyme that, in contrast to AHASs, catalyzes a reaction that relies on intercofactor electron transfer.Acetohydroxy acid synthases (AHAS) are thiamin diphosphate- (ThDP-) and FAD-dependent enzymes that catalyze the first common step of branched-chain amino acid biosynthesis in plants, bacteria, and fungi. Although the flavin cofactor is not chemically involved in the physiological reaction of AHAS, it has been shown to be essential for the structural integrity and activity of the enzyme. Here, we report that the enzyme-bound FAD in AHAS is reduced in the course of catalysis in a side reaction. The reduction of the enzyme-bound flavin during turnover of different substrates under aerobic and anaerobic conditions was characterized by stopped-flow kinetics using the intrinsic FAD absorbance. Reduction of enzyme-bound FAD proceeds with a net rate constant of k' = 0.2 s(-1) in the presence of oxygen and approximately 1 s(-1) under anaerobic conditions. No transient flavin radicals are detectable during the reduction process while time-resolved absorbance spectra are recorded. Reconstitution of the binary enzyme-FAD complex with the chemically synthesized intermediate 2-(hydroxyethyl)-ThDP also results in a reduction of the flavin. These data provide evidence for the first time that the key catalytic intermediate 2-(hydroxyethyl)-ThDP in the carbanionic/enamine form is not only subject to covalent addition of 2-keto acids and an oxygenase side reaction but also transfers electrons to the adjacent FAD in an intramolecular redox reaction yielding 2-acetyl-ThDP and reduced FAD. The detection of the electron transfer supports the idea of a common ancestor of acetohydroxy acid synthase and pyruvate oxidase, a homologous ThDP- and FAD-dependent enzyme that, in contrast to AHASs, catalyzes a reaction that relies on intercofactor electron transfer.
Author	Tittmann, Kai Schröder, Kathrin Duggleby, Ronald G Chipman, David M Golbik, Ralph Kaplun, Alexander Hübner, Gerhard Barak, Ze'ev McCourt, Jennifer
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Cites_doi	10.1074/jbc.273.21.12929 10.1016/0263-7855(96)00018-5 10.1016/S0167-4838(98)00083-1 10.1021/ja01554a078 10.1016/S0021-9258(18)99205-7 10.1016/S0021-9258(19)86441-4
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Notes	ark:/67375/TPS-HQ7RCHC4-1 This work was supported by the Fonds der chemischen Industrie (Halle), Grant 660/01 from the Israel Science Foundation (Beer-Sheva), and Grant A09937067 from the Australian Research Council (Brisbane). istex:F53291E53E26A23B1E5C610E881E3790C00775E8 ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23
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References	Abbreviations AHAS (bi049897tn00001/bi049897tn00001_1) Koland J. G. (bi049897tb00029/bi049897tb00029_1) 1984 Gruys K. J. (bi049897tb00031/bi049897tb00031_1) 1989 Tittmann K. (bi049897tb00011/bi049897tb00011_1) 2000 Bradford M. M. (bi049897tb00021/bi049897tb00021_1) 1976 Schloss J. V. (bi049897tb00003/bi049897tb00003_1) 1988 Jordan F. (bi049897tb00032/bi049897tb00032_1) 2003 Schloss J. V. (bi049897tb00030/bi049897tb00030_1) 1996 Tittmann K. (bi049897tb00012/bi049897tb00012_1) 2003 Gibson Q. H. (bi049897tb00023/bi049897tb00023_1) 1964; 239 Humphrey W. (bi049897tb00036/bi049897tb00036_1) 1996; 14 Pang S. S. (bi049897tb00008/bi049897tb00008_1) 2003 Chipman D. M. (bi049897tb00001/bi049897tb00001_1) 1998; 1385 Chung S. T. (bi049897tb00005/bi049897tb00005_1) 1971 Pang S. S. (bi049897tb00020/bi049897tb00020_1) 2004; 279 Abell L. M. (bi049897tb00014/bi049897tb00014_1) 1991 Ciskanik L. M. (bi049897tb00013/bi049897tb00013_1) 1985; 24 Schloss J. V. (bi049897tb00002/bi049897tb00002_1) 1985 Krampitz L. (bi049897tb00017/bi049897tb00017_1) 1958; 80 Palfey B. A. (bi049897tb00006/bi049897tb00006_1) 1998 Park H. S. (bi049897tb00022/bi049897tb00022_1) 1995; 1245 Tittmann K. (bi049897tb00025/bi049897tb00025_1) 1998; 273 Menon S. (bi049897tb00033/bi049897tb00033_1) 1997 Muller Y. A. (bi049897tb00009/bi049897tb00009_1) 1993 Davidson V. L. (bi049897tb00024/bi049897tb00024_1) 2002 Ibdah M. (bi049897tb00034/bi049897tb00034_1) 1996 Tittmann K. (bi049897tb00026/bi049897tb00026_1) 2000 Bornemann S. (bi049897tb00007/bi049897tb00007_1) 2002 Bar-Ilan A. (bi049897tb00019/bi049897tb00019_1) 2001 Chang Y.-Y. (bi049897tb00016/bi049897tb00016_1) 1988; 170 Jordan F. (bi049897tb00028/bi049897tb00028_1) 1999 Jorns M. S. (bi049897tb00004/bi049897tb00004_1) 1979; 254 Tittmann K. (bi049897tb00035/bi049897tb00035_1) 2004 Chiu C. C. (bi049897tb00027/bi049897tb00027_1) 1995; 117 Hill C. M. (bi049897tb00018/bi049897tb00018_1) 1997 Bertagnolli B. L. (bi049897tb00010/bi049897tb00010_1) 1991; 266 Tse J. M. T. (bi049897tb00015/bi049897tb00015_1) 1993
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SubjectTerms	Acetolactate Synthase - chemistry Acetolactate Synthase - metabolism Catalysis Electron Transport Flavin-Adenine Dinucleotide - metabolism Kinetics Magnetic Resonance Spectroscopy Models, Molecular Molecular Structure Oxygen - metabolism Pyruvic Acid - metabolism Spectrum Analysis Thiamine Pyrophosphate - analogs & derivatives Thiamine Pyrophosphate - chemistry Thiamine Pyrophosphate - metabolism
Title	Electron Transfer in Acetohydroxy Acid Synthase as a Side Reaction of Catalysis. Implications for the Reactivity and Partitioning of the Carbanion/Enamine Form of (α-Hydroxyethyl)thiamin Diphosphate in a “Nonredox” Flavoenzyme
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