The structural alterations which occur in bacteriorhodopsin (bR) during dark adaptation (BR570----BR548) and the primary phototransition of the dark photocycle (BR548----KD610) have been investigated by Fourier transform infrared and UV difference spectroscopy. Possible contributions of tyrosine to the Fourier transform infrared difference spectra of these transitions were assigned by incorporating ring per-deuterated tyrosine into bR. Based on these data and UV difference measurements, we conclude that a stable tyrosinate exists in BR570 at physiological temperature and that it protonates during formation of BR548. A tyrosinate protonation has also been observed at low temperature during the primary phototransition of BR570 to the red-shifted photoproduct K630 (1). However, we now find that no tyrosine protonation change occurs during the primary phototransition of BR548 to the red-shifted intermediate KD610. Through analysis of bR containing isotopically labeled retinals, it was also determined that the chromophore of KD610 exits in a 13-trans, 15-cis configuration. On the basis of this evidence and previous studies on the structure of the chromophore in BR570, BR548, and K630, it appears that only the 13-trans,15-trans configuration of the protonated chromophore leads to a stable tyrosinate group. It is proposed that a tyrosinate residue is stabilized due to its interaction with the Schiff base positive charge in the BR570 chromophore. Isomerization of the chromophore about either the C13 = C14 or C = N bond disrupts this interaction causing a protonation of the tyrosinate.