Proton NMR studies of myohemerythrin from Themiste zostericola

Abstract

One- and two-dimensional NMR experiments have been carried out on different forms of myohemerythrin (MHr), a monomeric 13.9-kDa oxygen carrier, focusing on paramagnetically shifted proton resonances. Compared to the corresponding forms of octameric hemerythrin (Hr), all of the MHr forms exhibit spectra with better resolution and signal-to-noise ratios. The metMHr spectra allow the differentiation of the signals from the Nδ-H protons of the five Ne-coordinated His ligands and those from the bridging Asp and Glu ligands. The 1D spectra of deoxyMHr exhibit a number of relatively sharp features including three solvent-exchangeable peaks that account for five protons. One of these His N-H protons exchanges more slowly with solvent than the other four and is assigned to His 54, which, by analogy to the crystal structure of deoxyHr, is the only His ligand that is hydrogen-bonded to an amino acid residue, Glu24 in this case. One-dimensional NOE results on the non-exchangeable signals clearly show the connectivities among the α and β protons of the bridging Asp111, and the α, β, and γ protons of the bridging Glu58 ligands. One-dimensional NOE experiments performed on the N-H proton signals of the coordinated His ligands, together with the COSY results, help to identify the geminal β protons of the His ligands. Upon the binding of N3– to one of the Fe(II) sites in deoxyMHr, the overlapping His Nδ-H proton signals observed in the deoxyMHr spectrum are resolved into individual signals; these have been correlated to the corresponding signals in deoxyMHr by saturation transfer experiments. Similarly, all five His N-H protons are resolved in the 1H NMR spectrum of the deoxy form of the single point mutant L103N MHr. However, all five N-H protons readily exchange with solvent, indicating that the mutation affects the hydrogen-bonding interaction between His54 and Glu24.