INFLUENCE OF THE 9-METHYL GROUP OF THE RETINAL ON THE PHOTOCYCLE OF BACTERIORHODOPSIN STUDIED BY TIME-RESOLVED RAPID-SCAN AND STATIC LOW-TEMPERATURE FOURIER-TRANSFORM INFRARED DIFFERENCE SPECTROSCOPY

The photocycle of bacteriorhodopsin (BR) regenerated with all-trans-9- demethylretinal was investigated by time-resolved rapid-scan Fourier t ransform infrared difference spectroscopy, by static low-temperature d ifference spectroscopy at 80, 170, and 213 K and by static steady-stat e difference spectroscopy at 278 K. In addition, the formation and dec ay of M intermediate was monitored at 412 nm with conventional flash p hotolysis experiments. Our data show that the removal of the 9-methyl group strongly changes the photocycle of BR. The reaction cycle is slo wed down about 250-fold. The photoreaction is characterized by a slow rise of the M intermediate and by a very long-lived N intermediate. No O intermediate could be observed. The low-temperature spectra indicat e that already at 80 K a KL-like photoproduct is formed. L can be obta ined as in native BR at 170 K, but its decay appears to be inhibited, since it can still be observed at 213 K and high pH, in addition to th e M intermediate. As in native BR, the 15-hydrogen out-of-plane modes of the L and N intermediates (observed in (H2O)-H-2) are very similar. Evidence for the existence of three N substates which differ in the p rotonation state of Asp96 and in the amide I bands is presented. This is explained by the extremely slowed-down reisomerization of the chrom ophore. The results are discussed with respect to alterations in the c hromophore-protein interaction, caused by the removal of the 9-methyl group.