13C-, 15N- and 31P-NMR studies of oxidized and reduced low molecular mass thioredoxin reductase and some mutant proteins.

ABSTRACT

Thioredoxin reductase (TrxR) from Escherichia coli, the mutant proteins E159Y and C138S, and the mutant protein C138S treated with phenylmercuric acetate were reconstituted with [U-(13)C(17),U-(15)N(4)]FAD and analysed, in their oxidized and reduced states, by (13)C-, (15)N- and (31)P-NMR spectroscopy. The enzymes studied showed very similar (31)P-NMR spectra in the oxidized state, consisting of two peaks at -9.8 and -11.5 p.p.m. In the reduced state, the two peaks merge into one apparent peak (at -9.8 p.p.m.). The data are compared with published (31)P-NMR data of enzymes closely related to TrxR. (13)C and (15)N-NMR chemical shifts of TrxR and the mutant proteins in the oxidized state provided information about the electronic structure of the protein-bound cofactor and its interactions with the apoproteins. Strong hydrogen bonds exist between protein-bound flavin and the apoproteins at C(2)O, C(4)O, N(1) and N(5). The N(10) atoms in the enzymes are slightly out of the molecular plane of the flavin. Of the ribityl carbon atoms C(10alpha,gamma,delta) are the most affected upon binding to the apoprotein and the large downfield shift of the C(10gamma) atom indicates strong hydrogen bonding with the apoprotein. The hydrogen bonding pattern observed is in excellent agreement with X-ray data, except for the N(1) and the N(3) atoms where a reversed situation was observed. Some chemical shifts observed in C138S deviate considerably from those of the other enzymes. From this it is concluded that C138S is in the FO conformation and the others are in the FR conformation, supporting published data. In the reduced state, strong hydrogen bonding interactions are observed between C(2)O and C(4)O and the apoprotein. As revealed by the (15)N chemical shifts and the N(5)H coupling constant the N(5) and the N(10) atom are highly sp(3) hybridized. The calculation of the endocyclic angles for the N(5) and the N(10) atoms shows the angles to be approximately 109 degrees, in perfect agreement with X-ray data showing that the flavin assumes a bent conformation along the N(10)/N(5) axis of the flavin. In contrast, the N(1) is highly sp(2) hybridized and is protonated, i.e. in the neutral state. Upon reduction of the enzymes, the (13)C chemical shifts of some atoms of the ribityl side chain undergo considerable changes also indicating conformational rearrangements of the side-chain interactions with the apoproteins. The chemical shifts between native TrxR and C138S are now rather similar and differ from those of the two other mutant proteins. This strongly indicates that the former enzymes are in the FO conformation and the other two are in the FR conformation. The data are discussed briefly in the context of published NMR data obtained with a variety of flavoproteins.