THE ROLE OF SULFHYDRYL GROUPS IN THE BLEACHING AND SYNTHESIS OF RHODOPSIN

doi:10.1085/jgp.35.5.797

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ARTICLE

THE ROLE OF SULFHYDRYL GROUPS IN THE BLEACHING AND SYNTHESIS OF RHODOPSIN

George Wald ¹ and Paul K. Brown ¹

¹ From the Biological Laboratories of Harvard University, Cambridge

The condensation of retinene₁ with opsin to form rhodopsinis optimal at pH about 6, a pH which favors the condensationof retinene₁ with sulfhydryl rather than with amino groups.The synthesis of rhodopsin, though unaffected by the less powerfulsulfhydryl reagents, monoiodoacetic acid and its amide, is inhibitedcompletely by p-chloromercuribenzoate (PCMB). This inhibitionis reversed in part by the addition of glutathione. PCMB doesnot attack rhodopsin itself, nor does it react with retinene₁.Its action in this system is confined to the —SH groupsof opsin. Under some conditions the synthesis of rhodopsin isaided by the presence of such a sulfhydryl compound as glutathione,which helps to keep the —SH groups of opsin free and reduced.

Bymeans of the amperometric silver titration of Kolthoff and Harris,it is shown that sulfhydryl groups are liberated in the bleachingof rhodopsin, two such groups for each retinene₁ molecule thatappears. This is true equally of rhodopsin from the retinasof cattle, frogs) and squid.

The exposure of new sulfhydrylgroups adds an important element to the growing evidence thatrelates the bleaching of rhodopsin to protein denaturation.The place of sulfhydryl groups in the structure of rhodopsinis still uncertain. They may be concerned directly in bindingthe chromophore to opsin; or alternatively they may furnishhydrogen atoms for some reductive change by which the chromophoreis formed from retinene₁.

In the amperometric silver titration,the bleaching of rhodopsin yields directly an electrical variation.This phenomenon may have some fundamental connection with therole of rhodopsin in visual excitation, and may provide a modelof the excitation process in general.

Submitted on September 25, 1951

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