Abstract
Sub-microsecond time-resolved step-scan FT-IR spectroscopy is applied to the study of the molecular changes and their dynamics occurring during the KL-L transition of bacteriorhodopsin. The time-resolved difference spectra are compared to the static low-temperature BR → K and BR → L difference spectra. Our data show that the protein part in KL is similar to that in K. However, the chromophore is more relaxed and is differently twisted. A strong hydrogen-out-of-plane (HOOP) mode in KL is assigned to the 15-HOOP. As is the case for L, a strong deformation of the C<sub>14</sub>-C<sub>15</sub> single bond is deduced for KL. Evidence of a KL ↔ L equilibrium is presented. In N, a 15-HOOP mode similar to that in L is observed, indicating very similar twists of the C<sub>14</sub>-C<sub>15</sub> single bond. This observation excludes major contributions of this deformation to the reduction of the pK<sub>a</sub> of the Schiff base in L. From the spectral changes, important molecular events are deduced that occur in the transitions to KL, L, and N.
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