Indirect determination of magnetic susceptibility tensors in peroxidases: a novel approach to structure elucidation by NMR

Abstract

 The chemical shifts of several ¹³C nuclei positioned α to the haems in oxidised cyanide complexes of horseradish peroxidase and lignin peroxidase are reported and analysed in terms of π molecular orbitals with perturbed D_4h symmetry. The additional contributions to the paramagnetic shifts of ¹³C nuclei in the vinyl groups which arise from conjugation with the porphyrin π molecular orbitals are discussed, and an empirical correction factor is derived from a number of other compounds which contain haems b. The orbital mixing parameter which is obtained from the analysis of the experimental ¹³C shifts is compared with the orientation of the axial histidine ligands in X-ray structures of related compounds and found to be close to the orientation of the normal to the histidine ring. Comparison with the magnetic axes determined by fitting the dipolar shifts of several protons which have been assigned previously also shows close agreement with the negative in-plane rotation of the magnetic y axis. It is therefore possible to obtain the approximate orientation of the magnetic axes from ¹³C resonances of the haem and hence to determine the dipolar shifts at any point in space with respect to the haem by using these axes together with the anisotropy of the magnetic susceptibility, which can be obtained by extrapolation from EPR g values. Excellent agreement is found between dipolar shifts obtained by fitting an empirical magnetic susceptibility tensor and predictions based on ¹³C NMR and EPR in the case of lignin peroxidase. The agreement is less good in the case of horseradish peroxidase, in which the empirical magnetic z axis appears to be tilted significantly away from the haem normal, though this may be due in part to the lack of accurate atomic coordinates. It is concluded that useful estimates of the magnetic susceptibility tensor may be obtained from ¹³C NMR and EPR studies even in large mammalian peroxidases for which no structural models are available.