Role of tryptophan in the spectral and catalytic properties of the copper enzyme, galactose oxidase.

Previous results indicate that a tryptophan residue(s) may interact with the sugar substrate and Cu(II) atom of galactose oxidase (Ettinger, M. J., and Kosman, D. J. (1974), Biochemistry 13, 1248). We now show that N-bromosuccinimide (NBS) reduces enzymatic activity to 2% as two tryptophans are oxidized; only four residues are easily oxidized in the holoenzyme. An enzymatic activity vs. number of residues oxidized profile suggests that this inactivation is probably associated with only one of the first 2 residues oxidized. There is no evidence for chain cleavage or modification of amino acids other than tryptophan. While substrate protection is not afforded by the sugar substrate, the activity-related tryptophan is placed within the active-site locus by spectral evidence. NBS oxidation of two tryptophans results in a marked diminution of the large copper optical-activity transition at 314 nm. Under some reaction conditions, a doubling of ellipticity in the 600-nm region of copper CD is also observed. The effects of the NBS oxidation on the CD spectra of galactose oxidase permit the assignment of the 314-nm CD band to a charge-transfer transition and the 229-nm extremum to a specific tryptophan contribution. The AZZ parameter from electron spin resonance spectra is also markedly reduced by the NBS oxidation. Moreover, while cyanide binds to the native enzyme without reducing the Cu(II) atom, cyanide rapidly reduces the Cu(II) atom to Cu(I) in the NBS-oxidized enzyme. These CD and ESR results are taken to suggest that one aspect of the inactivation by NBS oxidation may be a conversion of the pseudosquare planar copper complex in the native enzyme to a more distorted, towards tetrahedral, complex in the inactivated enzyme. Since the inactivation can be accomplished without affecting binding of the sugar substrate, tryptophan oxidation must affect catalysis per se.