IODOPSIN

doi:10.1085/jgp.38.5.623

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ARTICLE

IODOPSIN

George Wald ¹, Paul K. Brown ¹, and Patricia H. Smith ¹

¹ From The Biological Laboratories of Harvard University, Cambridge

The iodopsin system found in the cones of the chicken retinais identical with the rhodopsin system in its carotenoids. Itdiffers only in the protein—the opsin —with whichcarotenoid combines. The cone protein may be called photopsinto distinguish it from the scotopsins of the rods.

Iodopsinbleaches in the light to a mixture of photopsin and all-transretinene. The latter is reduced by alcohol dehydrogenase andcozymase to all-trans vitamin A₁. Iodopsin is resynthesizedfrom photopsin and a cis isomer of vitamin A, neovitamin Abor the corresponding neoretinene b, the same isomer that formsrhodopsin. The synthesis of iodopsin from photopsin and neoretineneb is a spontaneous reaction. A second cis retinene, isoretinenea, forms iso-iodopsin ( $lambda$ _max 510 mµ).

The bleaching of iodopsinin moderate light is a first-order reaction (Bliss). The synthesisof iodopsin from neoretinene b and opsin is second-order, likethat of rhodopsin, but is very much more rapid. At 10°C.the velocity constant for iodopsin synthesis is 527 times thatfor rhodopsin synthesis.

Whereas rhodopsin is reasonably stablein solution from pH 4–9, iodopsin is stable only at pH5–7, and decays rapidly at more acid or alkaline reactions.

Thesulfhydryl poison, p-chloromercuribenzoate, blocks the synthesisof iodopsin, as of rhodopsin. It also bleaches iodopsin in concentrationswhich do not attack rhodopsin.

Hydroxylamine also bleaches iodopsin,yet does not poison its synthesis. Hydroxylamine acts by competingwith the opsins for retinene. It competes successfully withchicken, cattle, or frog scotopsin, and hence blocks rhodopsinsynthesis; but it is less efficient than photopsin in trappingretinene, and hence does not block iodopsin synthesis.

Thoughiodopsin has not yet been prepared in pure form, its absorptionspectrum has been computed by two independent procedures. Thisexhibits an $alpha$ -band with $lambda$ _max 562 mµ, a minimum at about 435mµ, and a small ß-band in the near ultraviolet atabout 370 mµ.

The low concentration of iodopsin in thecones explains to a first approximation their high threshold,and hence their status as organs of daylight vision.

The relativelyrapid synthesis of iodopsin compared with rhodopsin parallelsthe relatively rapid dark adaptation of cones compared withrods. A theoretical relation is derived which links the logarithmof the visual sensitivity with the concentration of visual pigmentin the rods and cones. Plotted in these terms, the course ofrod and cone dark adaptation resembles closely the synthesisof rhodopsin and iodopsin in solution.

The spectral sensitivitiesof rod and cone vision, and hence the Purkinje phenomenon, havetheir source in the absorption spectra of rhodopsin and iodopsin.In the chicken, for which only rough spectral sensitivity measurementsare available, this relation can be demonstrated only approximately.In the pigeon the scotopic sensitivity matches the spectrumof rhodopsin; but the photopic sensitivity is displaced towardthe red, largely or wholly through the filtering action of thecolored oil globules in the pigeon cones. In cats, guinea pigs,snakes, and frogs, in which no such colored ocular structuresintervene, the scotopic and photopic sensitivities match quantitativelythe absorption spectra of rhodopsin and iodopsin. In man thescotopic sensitivity matches the absorption spectrum of rhodopsin;but the photopic sensitivity, when not distorted by the yellowpigmentations of the lens and macula lutea, lies at shorterwave lengths than iodopsin. This discrepancy is expected, forthe human photopic sensitivity represents a composite of atleast three classes of cone concerned with color vision.

Submitted on November 10, 1954

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