Evidence for the involvement of more than one metal cation in the Schiff base deprotonation process during the photocycle of bacteriorhodopsin

摘要

The removal of metal cations inhibits the deprotonation process of the protonated Schiff base during the photocycle of bacteriorhodopsin. To understand the nature of the involvement of these cations, a spectroscopic and kinetic study was carried out on bacteriorhodopsin samples in which the native Ca²⁺ and Mg²⁺ were replaced by Eu³⁺, a luminescent cation. The decay of Eu³⁺ emission in bacteriorhodopsin can be fitted to a minimum of three decay components, which are assigned to Eu³⁺ emission from three different sites. This is supported by the response of the decay components to the presence of ²H2O and to the changes in the Eu³⁺/bR molar ratio. The number of water molecules coordinated to Eu³⁺ in each site is determined from the change in its emission lifetime when ²H2O replaces H2O. Most of the emission originates from two “wet” sites of low crystal-field symmetry—e.g., surface sites. Protonated Schiff base deprotonation has no discernable effect on the emission decay of protein-bound Eu³⁺, suggesting an indirect involvement of metal cations in the deprotonation process. Adding Eu³⁺ to deionized bacteriorhodopsin increases the emission intensity of each Eu³⁺ site linearly, but the extent of the deprotonation (and color) changes sigmoidally. This suggests that if only the emitting Eu³⁺ ions cause the deprotonation and bacteriorhodopsin color change, ions in more than one site must be involved—e.g., by inducing protein conformation changes. The latter could allow deprotonation by the interaction between the protonated Schiff base and a positive field of cations either on the surface or within the protein.