The Predischarge Chromophore in Bacteriorhodopsin: A 15N Solid-State NMR Study of the L Photointermediate

Abstract

The L₅₅₀ intermediate in the bacteriorhodopsin (bR) photocycle has drawn much attention with respect to the mechanism of light-driven proton transport because it selectively releases the Schiff base (SB) proton to the extracellular proton channel in the L→M transition. Here we extend our solid-state NMR studies of bR photocycle intermediates to the L state. Under conditions that stabilize L₅₅₀, a new SB signal is detected in the ¹⁵N NMR spectrum which disappears upon thermal relaxation. This signal is in the range for a protonated SB, but downfield from the SB signals of bR₅₆₈ and N₅₂₀. Since steric interactions would have the opposite effect on shielding, the data argue against a 13,14-dicis chromophore in L₅₅₀. Comparison with the ¹⁵N chemical shifts of halide salts of protonated Schiff bases (pSB's) of retinal suggests that the interaction of the SB with its counterion is significantly stronger in L₅₅₀ than in N₅₂₀ (which in turn is stronger than in bR₅₆₈). This is consistent with models of the early photocycle in which the electrostatic interaction between the SB and its counterion constitutes an important constraint. Although the L counterion interaction is comparable to that of a 6-s-trans,13-cis chloride salt, the visible spectrum is strongly red-shifted from the λ_max = 491 nm of the chloride. This suggests some double bond strain in L₅₅₀, particularly about the CN bond. This strain is apparently gone in the N intermediate, which has a normal relationship between the ¹⁵N chemical shift and λ_max. Such a relaxed chromophore is consistent with orientation of the SB proton toward the cytoplasmic surface in the N intermediate.