A large collection of structural snapshots along a full catalytic cycle of Escherichia coli thioredoxin reductase (TrxR) has been generated and characterized using a combination of theoretical methods. Molecular models were built starting from the available X-ray crystallographic structures of dimeric wild-type TrxR in the flavin-oxidizing conformation and a C135S TrxR mutant enzyme in a flavin-reducing conformation "trapped" by a cross-link between Cys138 of TrxR and Cys32 of C35S mutant thioredoxin (Trx). The transition between these two extreme states, which is shown to be reproduced in a normal mode analysis, as well as natural cofactor binding and dissociation, were simulated for the wild-type species using unrestrained and targeted molecular dynamics following docking of oxidized Trx to reduced TrxR. The whole set of simulations provides a comprehensive structural framework for understanding the mechanism of disulfide reduction in atomic detail and identifying the most likely intermediates that facilitate entry of NADPH and exit of NADP(+). The crucial role assigned to Arg73 and Lys36 of Trx in substrate binding and complex stabilization was ascertained when R73G, R73D, and K36A site-directed mutants of Trx were shown to be impaired to different extents in their ability to be reduced by TrxR. On the basis of previous findings and the results reported herein, E. coli TrxR appears as a beautifully engineered molecular machine that is capable of synchronizing cofactor capture and ejection with substrate binding and redox activity through an interdomain twisting motion.
(c) 2009 Wiley-Liss, Inc.