On the nature of the primary light-induced events in bacteriorhodopsin: Ultrafast spectroscopy of native and C-13=C-14 locked pigments

The primary light-induced events in the photosynthetic retinal protein bact eriorhodopsin (bR) are investigated by ultrafast optical spectroscopy over the 440-1000 nm spectral range. The study compares the early dynamics of th e native all-trans pigment bR(570) with those of two synthetic analogues, b R5.12 and bR5.13, in which isomerization around the critical C-13=C-14 bond is blocked by a five-membered ring into all-trans and 13-cis configuration s, respectively. Nearly identical spectral evolution is observed in both na tive and artificial systems over the first 100-200 fs of probe delay. Durin g this period stimulated near-IR (similar to 900 nm) emission, and intense similar to 460 nm absorption bands, due to analogous fluorescent I states ( denoted as I-460, I5.12 and I5.13, respectively), appear concurrently withi n 30 fs. in all systems continuous spectral shifting over tens of femtoseco nds is observed in the 500-700 nm range. Native bR goes on to produce the J (625) absorption band within similar to 1 ps, which is accompanied by disap pearance of the I-460 emission and absorption features. In bR5.12 and bR5.1 3, aside from minor spectral modifications, the analogous dramatic changes associated with I5.12 and I5.13 are arrested beyond the first similar to 10 0 fs, reverting uniformly to the initial ground state with exponential time constants of 19 ps and 11 ps, respectively. Analysis of the data calls for a major revision of models previously put forward for the primary events i n bacteriorhodopsin. The close likeness of initial transient spectral evolu tion in both native and artificial pigments, despite the locking of the act ive isomerization coordinate in the synthetic chromophores, demonstrates th at in bR570 the ultrafast changes in transmission leading to I-460, previou sly believed to involve C-13=C-14 torsion, must be associated with ether mo des. The detailed comparison conducted here also identifies which of the la ter spectral changes in the native system requires torsional flexibility in C-13=C-14. Similarity of 660 nm probing data in both synthetic and native chromophores demonstrates that the sub-picosecond dynamic features uncovere d at this probing wavelength commonly attributed to the evolution of J(625) , are not, as previously thought, reliable measures of all-trans double lef t right arrow 13-cis isomerization dynamics.