Synthesis of pyrrothiamine, a novel thiamine analogue, and evaluation of derivatives as potent and selective inhibitors of pyruvate dehydrogenase.

Inhibition of thiamine pyrophosphate (TPP)-dependent enzymes with thiamine/TPP analogues that have the central thiazolium ring replaced with other rings is well established, but a limited number of central rings have been reported. We report a novel analogue, pyrrothiamine, with a central pyrrole ring. We further develop pyrrothiamine derivatives as potent and selective inhibitors of pyruvate dehydrogenase, which might have anti-cancer potential.

Probing riboswitch-ligand interactions using thiamine pyrophosphate analogues.

The Escherichia coli thiM riboswitch forms specific contacts with its natural ligand, thiamine pyrophosphate (TPP or thiamine diphosphate), allowing it to generate not only nanomolar binding affinity, but also a high degree of discrimination against similar small molecules. A range of synthetic TPP analogues have been used to probe each of the riboswitch-ligand interactions. The results show that the pyrimidine-sensing helix of thiM is exquisitely tuned to select for TPP by recognising the H-bonding donor and acceptors around its aminopyrimidine ring and also by forming π-stacking interactions that may be sensitive to the electronics of the ring. The central thiazolium ring of TPP appears to be more important for ligand recognition than previously thought. It may contribute to binding via long-range electrostatic interactions and/or by exerting an electron withdrawing effect on the pyrimidine ring, allowing its presence to be sensed indirectly and thereby allowing discrimination between thiamine (and its phosphate esters) and other aminopyrimidines found in vivo. The pyrophosphate moiety is essential for submicromolar binding affinity, but unexpectedly, it does not appear to be strictly necessary for modulation of gene expression.

Thiamin diphosphate in biological chemistry: analogues of thiamin diphosphate in studies of enzymes and riboswitches.

The role of thiamin diphosphate (ThDP) as a cofactor for enzymes has been known for many decades. This minireview covers the progress made in understanding the catalytic mechanism of ThDP-dependent enzymes through the use of ThDP analogues. Many such analogues have been synthesized and have provided information on the functional groups necessary for the binding and catalytic activity of the cofactor. Through these studies, the important role of hydrophobic interactions in stabilizing reaction intermediates in the catalytic cycle has been recognized. Stable analogues of intermediates in the ThDP-catalysed reaction mechanism have also been synthesized and crystallographic studies using these analogues have allowed enzyme structures to be solved that represent snapshots of the reaction in progress. As well as providing mechanistic information about ThDP-dependent enzymes, many analogues are potent inhibitors of these enzymes. The potential of these compounds as therapeutic targets and as important herbicidal agents is discussed. More recently, the way that ThDP regulates the genes for its own biosynthesis through the action of riboswitches has been discovered. This opens a new branch of thiamin research with the potential to provide new therapeutic targets in the fight against infection.