In several reactions, including that of pyruvate dehydrogenase, alpha-ketoglutarate dehydrogenase, and transketolase, TPP catalyses the reversible decarboxylation reaction (aka cleavage of a substrate compound at a carbon-carbon bond connecting a
carbonyl group to an adjacent reactive group—usually a
carboxylic acid or an
alcohol). It achieves this in four basic steps: • The carbanion of the TPP ylid
nucleophilically attacks the carbonyl group on the substrate. (This forms a single bond between the TPP and the substrate.) • The target bond on the substrate is broken, and its electrons are pushed towards the TPP. This creates a double bond between the substrate carbon and the TPP carbon and pushes the electrons in the N-C double bond in TPP entirely onto the nitrogen atom, reducing it from a positive to neutral form. • In what is essentially the reverse of step two, the electrons push back in the opposite direction forming a new bond between the substrate carbon and another atom. (In the case of the decarboxylases, this creates a new carbon-hydrogen bond. In the case of transketolase, this attacks a new substrate molecule to form a new carbon-carbon bond.) • In what is essentially the reverse of step one, the TPP-substrate bond is broken, reforming the TPP ylid and the substrate carbonyl. The TPP thiazolium ring can be deprotonated at C2 to become an
ylid: : A full view of TPP. The arrow indicates the acidic proton. : ==See also==