Biochemical aspects of the visual process. XXIII. Sulfhydryl groups and rhodopsin photolysis

1. The number of exposed sulfhydryl groups in cattle rod photoreceptor membranes has been determined in suspension and after solubilization in various detergents both before and after illumination.2. In suspensions, two sulfhydryl groups are modified per mole of rhodopsin, both by Ellman's reagent 5,5′-dithiobis-(2-nitrobenzoic acid) (DTNB) and N-ethylmaleimide, while no extra SH groups are uncovered upon illumination. Neither reagent affects the spectral integrity of rhodopsin at 500 nm and the recombination capacity is retained upon modification of both rhodopsin and opsin.3. However, in detergents (digitonin, Triton X-100 and cetyltrimethylammonium bromide (CTAB)) 2–3 additional sulfhydryl groups appear upon illumination, in agreement with earlier reports.4. A total number of six sulfhydryl groups and two disulfide bridges are found in rod photoreceptor membranes, expressed per mole of rhodopsin.5. DTNB reacts somewhat faster with membrane suspensions after than before illumination. The less reactive sulfhydryl modifying agents O-methylisourea and methyl-p-nitrobenzene sulfonate show a similar behavior.6. It is concluded that illumination of rhodopsin in vivo will not uncover additional SH groups, although the reactivity of one exposed SH group may increase somewhat. These findings also exclude a role of SH groups in the covalent binding of the chromophore.     

Biochemical aspects of the visual process XXVIII. Classification of sulfhydryl groups in rhodopsin and other photoreceptor membrane proteins

Reaction of isolated bovine rod outer segment membrane with radioactiveN-ethylmaleimide, both in the presence and absence of 1% dodecyl sulfate followed by dodecyl sulfate-polyacrylamide gel electrophoresis, shows that six sulfhydryl groups (96% of total sulfhydryl in this membrane) are located on the rhodopsin molecule.On the basis of their reactivity towardsp-chloromercuribenzoate andp-chloromercuribenzene sulfonate in suspensions of outer segment membranes, the sulfhydryl groups of rhodopsin can be divided into three pairs. One pair is rapidly modified, both in light and darkness. This modification does not impair the recombination capacity of opsin with 11-cis retinaldehyde under regeneration of rhodopsin. A second pair is modified upon prolonged interaction with thep-chloromercuriderivatives in darkness. Modification of this pair leaves the typical rhodopsin absorbance at 500 nm intact, but a proportional loss of recombination capacity does occur. The third pair is only modified after illumination and is probably located in the vicinity of the chromophoric center.The difference between these results and those obtained by modification with dithiobis-(2-nitrobenzoic acid) orN-ethylmaleimide in suspension, where even upon prolonged exposure to light as well as in darkness only two sulfhydryl groups of rhodopsin are modified, is explained by the detergent-like character of thep-chloromercuri-derivatives.     

Biochemical aspects of the visual process. XIX. Formation of isorhodopsin from photolyzed rhodopsin by bacterial action

A washed and concentrated suspension of bacteria (e.g. Proteus mirabilis) causes a rapid and almost complete conversion of photolyzed rhodopsin to isorhodopsin. Upon ultrasonication of the bacteria the activity is retained in the supernatant. The isorhodopsin formation is very sensitive to oxygen. This suggests that an easily oxidized bacterial product is able to isomerize in darkness all-trans-retinaldehyde present in a photolyzed rhodopsin preparation to the 9-cis-isomer.     

Biochemical aspects of the visual process. XXXVIII. Effects of lateral aggregation on rhodopsin in phospholipase C-treated photoreceptor membranes

Treatment of bovine rod outer segments with phospholipase C leads to largely lipid-depleted membranous structures. Under these conditions rhodopsin remains spectrally intact, but its thermal stability and regeneration capacity are decreased, whereas upon illumination the metarhodopsin I to II transition is blocked. These observations can be explained on the basis of the previously demonstrated lateral aggregation of rhodopsin molecules which, on the one hand leads to a (partial) shielding of these molecules and, on the other hand, might impose constraints on the flexibility of the molecule to undergo light-induced conformational changes.Upon reconstitution of these lipid-depleted preparations with amphipathic lipids by means of a detergent dialysis procedure, the aggregates are apparently rearranged to lipid bilayer structures with complete recovery of the original rhodopsin properties. Under our conditions the nature of the polar head groups and the fatty acids is not critical in this respect. Simple addition of amphipathic lipids, without the use of detergent, restores the rhodopsin properties only in the case of rod outer segment lipids and of didecanoylphosphatidylcholine, and even then only occasionally.These results are discussed in the light of the strong analogy in properties between phospholipase C-treated rod outer segment membranes and lipid- and detergent-free rhodopsin obtained by affinity chromatography. It is concluded that rhodopsin must be in a freely dispersed state in order to function properly. Apparently, a non-specific lipid bilayer fulfills this condition for the regeneration capacity, whereas normal photolytic behaviour requires, in addition, a minimal membrane fluidity according to the observations of other investigators. Presumably, the uniquely high phospholipid unsaturation of rod outer segment membranes is important for another, as yet unassessed, function of rhodopsin or the photoreceptor membrane.     

Biochemical aspects of the visual process. XXXVII. Evidence for lateral aggregation of rhodopsin molecules in phospholipase C-treated bovine photoreceptor membranes

Photoreceptor membranes derived from isolated bovine rod outer segments, are subjected to treatment with phospholipase C (Bacillus cereus). This results in varying degrees of hydrolysis of the membrane phospholipids into diglycerides and water soluble phosphate esters without loss of rhodopsin. Electron microscopic observations of thin sections and freeze-fractured preparations indicate extrusion of diglycerides from the membranes and their coalescence to lipid droplets, beginning at 20% hydrolysis of phospholipids. After 90% hydrolysis of phospholipids membranous structures are still present. The rhodopsin is located in these structures, presumably in the form of two-dimensional lateral aggregates. This explains the cross-fracturing of the membranous structures, regularly observed upon freeze-fracturing of the phospholipase-treated photoreceptor membranes.     

Biochemical aspects of the visual process. XXVIII. Classification of sulfhydryl groups in phodopsin and other photoreceptor membrane proteins.

Reaction of isolated bovine rod outer segment membrane with radioactive N-ethylmaleimide, both in the presence and absence of 1% dodecyl sulfate followed by dodecyl sulfate-polyacrylamide gel electrophoresis, shows that six sulfhydryl groups (96% of total sulfhydryl in this membrane) are located on the rhodopsin molecule. On the basis of their reactivity towards rho-chloromercuribenzoate and rho-chloromercuribenzene sulfonate in suspensions of outer segment membranes, the sulfhydryl groups of rhodopsin can be divided into three pairs. One pair is rapidly modified, both in light and darkness. This modification does not impair the recombination capacity of opsin with 11-cis retinaldehyde under regeneration of rhodopsin. A second pair is modified upon prolonged interaction with the rho-chloromercuriderivatives in darkness. Modification of this pair leaves the typical rhodopsin absorbance at 500 nm intact, but a proportional loss of recombination capacity does occur. The third pair is only modified after illumination and isprobably located in the vicinity of the chromophoric center. The differences between these results and those obtained by modification with dithiobis-(2-nitrobenzoic acid) or N-ethylmaleimide in suspension, where even upon prolonged exposure to light as well as in darkness only two sulfhydryl groups of rhodopsin are modified, is explained by the detergent-like character of the rho-chloromercuri-derivatives.     

Biochemical aspects of the visual process. XXV. Light-induced calcium movements in isolated frog rod outer segments

Suspensions of isolated rod outer segments are shown to have a high calcium content of up to 11 moles calcium per mole rhodopsin. Osmotic lysis of the outer segments demonstrates the presence of two calcium fractions, a soluble one and a particulate one. The particulate fraction apparently coincides with the rod disks or with disk fragments. Illumination of intact rod outer segments in calcium-free ATP-containing Ringer solution has no measurable effect upon their total caclium content, but causes a significant shift of calcium from the particulate to the soluble fraction. This light effect is retained in lysed outer segments resuspended in calcium-free ATP-containing Ringer. These results support a function of calcium as a transmitter in light transduction in rod outer segments.     

Biochemical aspects of the visual process XXIV. Adenylate cyclase and rod photoreceptor membranes: A critical appraisal

Adenylate cyclase was found to be present in rod outer segment preparations, but its specific activity was only about 1% of activities reported in earlier studies. In frog activities ranged from 0.015 to 1.1 nmoles 3′,5′ cyclic AMP/mg protein per 10 min depending on the method of preparation and homogenization. In cattle, the rod outer segment layer obtained after sucrose density gradient centrifugation, had an activity of 0.22 nmole 3′,5′ cyclic AMP/mg protein per 10 min. Furthermore a second (more dense) layer obtained in this procedure possessed a 10 times higher specific activity.Light decreased the adenylate cyclase activity in the rod outer segment suspensions of both frog and cattle, but the maximal inhibition was about 50% at extensive illumination. Light did not affect the activity in the second layer, unless rod outer segment layer material was present, indicating that an inhibitory diffusible factor is released from outer segments during illumination. Evidence that either Ca²⁺ or free all-trans retinaldehyde constitutes this factor could not be obtained.The activities of some marker enzymes in the two layers and in whole retina homogenates from cattle were determined. Comparison of some properties of the adenylate cyclase activities in the two layers and consideration of these enzyme activities do not exclude the possibilty that the activity in the rod outer segment material is due to contamination with other retinal material.The available evidence does not support a direct role for 3′,5′ cyclic AMP in the visual excitation process.     

Biochemical aspects of the visual process. XL. Spectral and chemical analysis of metarhodopsin III in photoreceptor membrane suspensions

The late photointermediates of rhodopsin photolysis have been analyzed spectrally and chemically in bovine rod outer segment membrane suspension at 25 degrees C and pH 6.5. The decay of metarhodopsin II follows two spectrally distinct routes, resulting 40 min after illumination in a stable mixture of photo-products with absorbance maxima around 380 and 452 nm, free retinal and metarhodopsin III, respectively. Chemical analysis shows that three different products are involved: free retinal (approx. 34%), protein-bound retinal (approx. 51%) and lipid-bound retinal (approx. 15%). The latter fraction consists of retinylidene-phosphatidylethanolamine exclusively. Photolysis of membranes reconstituted with various phospholipids gives a qualitatively normal spectral picture, but the production of metarhodopsin III may vary with the phospholipid composition, i.e. with the percent of phosphatidylethanolamine present. Chemical analysis shows that with increasing phosphaatidylethanolamine content of the membrane, the retinylidene phosphatidylethanolamine fraction increases proportionally at the expense of free retinal, while the fraction of protein-bound retinal remains unaffected. The results indicate that under these conditions metarhodopsin III (defined as a long wavelength product of metarhodopsin II decay) is composed of two chemically distinct components: opsin-bound retinal and retinylidene phosphatidylethanolamine.