Abstract
Recent evidence from isotope studies supports the view that catalysis by trimethylamine dehydrogenase (TMADH) proceeds from a Michaelis complex involving trimethylamine base and not, as thought previously, trimethylammonium cation. In native TMADH reduction of the flavin by substrate (perdeuterated trimethylamine) is influenced by two ionizations in the Michaelis complex with pK(a) values of 6.5 and 8.4; maximal activity is realized in the alkaline region. The latter ionization has been attributed to residue His-172 and, more recently, the former to the ionization of substrate itself. In the Michaelis complex, the ionization of substrate (pK(a) approximately 6.5 for perdeuterated substrate) is perturbed by approximately -3.3 to -3.6 pH units compared with that of free trimethylamine (pK(a) = 9.8) and free perdeuterated trimethylamine (pK(a) = 10.1), respectively, thus stabilizing trimethylamine base by approximately 2 kJ mol(-1). We show, by targeted mutagenesis and stopped-flow studies that this reduction of the pK(a) is a consequence of electronic interaction with residues Tyr-60 and His-172, thus these two residues are key for optimizing catalysis in the physiological pH range. We also show that residue Tyr-174, the remaining ionizable group in the active site that we have not targeted previously by mutagenesis, is not implicated in the pH dependence of flavin reduction. Formation of a Michaelis complex with trimethylamine base is consistent with a mechanism of amine oxidation that we advanced in our previous computational and kinetic studies which involves nucleophilic attack by the substrate nitrogen atom on the electrophilic C4a atom of the flavin isoalloxazine ring. Stabilization of trimethylamine base in the Michaelis complex over that in free solution is key to optimizing catalysis at physiological pH in TMADH, and may be of general importance in the mechanism of other amine dehydrogenases that require the unprotonated form of the substrate for catalysis.
Highlights
That the lower ionization seen in the k3 versus pH plots for Y60F TMADH is attributable to the ionization of substrate bound in the ES complex, and the upper ionization is attributable to His-172
Confirmation that this ionization represents substrate was obtained by performing reactions with perdeuterated trimethylamine; in this case the pKa value is perturbed by ϳϩ0.8 pH units, consistent with force constant effects on the ionization of substrate which have been discussed previously in the context of the H172Q mutant TMADH (7)
Concluding Remarks—Our analyses of the reductive halfreaction of mutant forms of TMADH indicate that the trimethylamine base (and not, as previously thought (8), the protonated cation) is the catalytically relevant form of the substrate in the ES complex
Summary
IDENTIFICATION OF INTERACTIONS THAT PERTURB THE IONIZATION OF SUBSTRATE AND FACILITATE CATALYSIS WITH TRIMETHYLAMINE BASE*. In native TMADH reduction of the flavin by substrate (perdeuterated trimethylamine) is influenced by two ionizations in the Michaelis complex with pKa values of 6.5 and 8.4; maximal activity is realized in the alkaline region. The latter ionization has been attributed to residue His-172 and, more recently, the former to the ionization of substrate itself. Formation of a Michaelis complex with trimethylamine base is consistent with a mechanism of amine oxidation that we advanced in our previous computational and kinetic studies which involves nucleophilic attack by the substrate nitrogen atom on the electrophilic C4a atom of the flavin isoalloxazine ring.
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