The individual resonance Raman spectra of the PM568 and M412 forms of light-adapted purple membrane from Halobacterium halobium have been measured using the newly developed flow technique. For comparison purposes, the Raman spectra of the model chromophores, all-trans- and 13-cis retinal n-butylamine, both as protonated and unprotonated Schiff bases, have also been obtained. In agreement with previous work, the Raman data indicate that the retinal chromophore is linked to the purple membrane protein via a protonated. Schiff base in the case of the PM568 and an unprotonated Schiff base for the M412 form. The basic mechanism for color regulation in both forms appears to be electron delocalization. The spectral features of the two forms are different from each other and different from the model compound spectra.
Techniques for purifying teh purple membrane of Halobacterium halobium are given. This purple membrane contains a chromoprotein with a retinal prosthetic group similar to rhodopsin, the chromprotein found in the visual systems of higher invertebrates and vertebrates. The described purple membrane isolation procedures yield a highly purified preparation as determined by transmitting electron microscopy and gel electrophoresis. Critical analysis of the absorption spectra of the purple membrane was also employed to establish criteria of purity for the preparation. The visible absorption spectra of the purified purple membrane preparation in buffer was found to have a maximum at 559 nm which shifted to 567 nm on light exposure. No indication of any spectral perturbation arising from bacterioruberin-containing membrane, the major contaminant in purple membrane preparations, was found. Furthermore, the ratio of protein aromatic amino acid absorbance at 280 nm to chromophore absorbance at 567 nm was found to be 1.5 in light-exposed preparations compared to the previously reported ratio of 2.3.-3 The decrease in the value of this ratio is also indicative of an increase in the purity of the purple membrane preparation.
Absorption, circular dichroism and optical rotatory dispersion of the bacteriorhodopsin containing purple membrane form Halobacterium halobium were studied in regard to the structural stability of this membrane during the photoisomerization of the retinal of the bacteriorhodopsin from the 13-cis to the all-trans configuration. The following conclusions were reached: (a) the macromolecular structure (protein-protein interaction which may result in the possible exciton interaction of the retinal pi-pi* (NV1) transition moments and protein-lipid interaction) are not significantly altered, (b) possibilities of delocalized conformation changes of the apoprotein involving secondary and/or tertiary structure can be ruled out, (c) localized secondary structure conformation changes of the apoprotein must be limited to the involvement of no more than one or two amino acid residues and localized tertiary structure conformation changes of the apoprotein must be limited to a very short segment of the protein chain containing only a few aromatic amino acid residues, and (d) the interaction between the apoprotein and retinal seems to be relatively more pronounced when the retinal is in the all-trans form than the 13-cis from and also the apoprotein seems to impose a more pronounced dissymmetric constraint on the retinal in the all-trans form than in the 13-cis form.
Sequential bleaching in the presence of hydroxylamine and subsequent regeneration of the purple membrane of Halobacterium halobium was studied by concomitant monitoring of its absorption and circular dichroic spectra in order to ascertain its effects on protein interaction(s) (which may result in possible excitonic interaction between the retinal chromophores), chromophore-apoprotein interaction(s), and protein conformational stability in the membrane. It was concluded that (a) although experimental results are consistent with an exciton mechanism for the interaction between retinal pi - pi* (NV(1)) transition movements in the purple membrane, no evidence for such a mechanism for interaction between retinaloxime transition moments is apparent in the case of the bleached membrane; (b) the bacteriorhodopsin molecules organized in clusters of three in the membrane appear to bleach simultaneously; (c) the retinaloxime produced on bleaching the purple membrane in the presence of hydroxylamine is strongly optically active, because of dissymmetry-inducing and/or -selecting constraints on the chromophore by a component of the membrane (most likely the apoprotein), and when the membrane is regenerated by the addition of retinal, these constraints are lost; and (d) evidence from ultraviolet absorption and circular dichroic spectra suggests that the membrane apoprotein undergoes appreciable conformational changes involving tertiary structure on bleaching with no significant secondary structure involvement. These results are compared with recently reported results from this laboratory on the effects of bleaching on the bovine rod outer segment disk membrane structure.
The quantum efficiency for the formation of M(412), an intermediate product in the photoconversion of the purple membrane protein of Halobacterium halobium, was determined to be 0.30 +/- 0.03 at -40 degrees C. This photochemical reaction was photoreversible to the original pigment and the ratio of the quantum efficiencies gamma PM(568 leads to M(412)/gamma M(412) leads to PM(568) was 0.39 +/- 0.02. No change was seen in either value when exciton interaction between chromophores was eliminated. The sum of gamma PM(568) leads to M(412) plus gamma M(412) leads to PM(568) was 1.07 +/- 0.10, approximately 1, suggesting that the pigment and its primary photoproduct share a common excited state.
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