Studies on the effects of bleaching amphibian rod pigments in situ II. the kinetics of the slow bleaching reactions in axolotl red rods

Retinol kinetics in the isolated retina determined by retinoid extraction and HPLC

Suzuki et al. [Vis. Res. 26, 425-9 (1986); Vis. Res. 28, 1061-70 (1988)] have described a formaldehyde-based (HCHO-based) extraction procedure that efficiently recovers 11-cis retinal initially present as rhodopsin chromophore in photoreceptor membranes. Using the isolated retina of the toad (Bufo marinus), we tested whether this procedure ('HCHO' method), in combination with a formaldehyde-free extraction procedure ('i/h' method) and the analysis of extracted retinoids by high performance liquid chromatography (HPLC), can account quantitatively for light-induced changes in retinoid levels and thus serve as an alternative to spectrophotometry for tracking the formation of all-trans retinol in this intact rod preparation. Initially dark-adapted retinas were incubated in bright light or in darkness and then analysed by homogenization and extraction using the HCHO and i/h methods. Combined data obtained using the two extraction procedures indicated a near-conservation of total retinoid recovered from dark-incubated and illuminated retinas, and thus accounted for light-induced changes in retinoid levels. The HCHO procedure, employing formaldehyde, isopropanol and hexane, was similar to that described by Suzuki et al. and recovered retinaldehydes including chromophoric 11-cis retinal. The i/h procedure utilized isopropanol and hexane and, unlike the HCHO method, efficiently recovered all-trans retinol. Illumination (onset at time zero) that produced an approximately exponential decline of 11-cis retinal (time constant of 24 s) led to an increase and then a gradual decline in all-trans retinal. The normalized peak level of all-trans retinal, representing about 0.54 of the total molar quantity of recovered retinoid, developed with illumination periods of 10-80 s. The normalized level of all-trans retinol reached approximately 0.3 in retinas illuminated for 1 min and, with longer illuminations (up to 30 min), exhibited an approximately exponential further growth to approximately 0.9 with a time constant of 9.2 min. The results indicate the workability of the HCHO and i/h extraction procedures for tracking the in situ conversion of all-trans retinal to all-trans retinol, a reaction thought to be important for both operation of the retinoid visual cycle and shut-off of the phototransduction cascade.

The distribution and kinetics of visual pigments in the owl monkey retina

An imaging fundus reflectometer has been used to study the distribution and regeneration of visual pigments in the retina of the owl monkey, Aotes trivirgatus. Measurements were made over an area of retina from 10 degrees nasal to 30 degrees temporal on the horizontal meridian, and from 5 degrees inferior to 30 degrees superior on the vertical meridian. The measured density differences vary with retinal location, with values in the central retina higher than those in more peripheral regions. The area of high density differences is roughly circular, with the highest values (approximately 0.3 log units) centred on or near the area centralis. Spectral measurements are consistent with a rod visual pigment absorbing maximally at about 518 nm, and indicate that the contribution of cone pigments to the imaging fundus reflectometer (IFR) data is negligible everywhere within the retinal area studied. The distribution of density differences is shown to correlate well with anatomical data for receptor and ganglion cell populations. Bleaching the visual pigment with brief intense lights leads to the extensive formation of the long-lived photoproduct metarhodopsin 3. Complete regeneration of rhodopsin following a full bleaching exposure (whether of brief or extended duration) takes more than 60 min and the time course of its recovery cannot be described accurately by first order kinetics.

Interaction of visual pigment with G-protein: effects of bleaching in native and reconstituted ROS preparations

Native and reconstituted preparations of bullfrog rod outer segment (ROS) membranes were analysed for the binding of the alpha and beta subunits of G-protein. Following incubation at 22-28 degrees C under varying conditions of illumination and chemical treatment, preparations were chilled and extracted with hypotonic medium lacking-vs.-containing GTP (H and HG extracts, respectively). The extent of binding of G alpha,beta ('percentage G bound') was determined by measurement of the relative abundance of G alpha, beta in the H and HG extracts. The addition of G to unbleached, G-depleted membranes (D-ROS) yielded relatively little binding of the G (14 +/- 13%). G reintroduced at congruent to 1 min vs. congruent to 90 min after major bleaching yielded, respectively, levels of binding of 88 +/- 8% and 24 +/- 8%. Native G, extracted at congruent to 90 min post-bleach and added to freshly bleached D-ROS, exhibited binding exceeding that in the parent (bleached +90 min) sample. Supplementation of reconstituted suspensions with all-trans retinal, and subsequent incubation in darkness, yielded 30-35% G-binding; similar treatment with 11-cis retinal yielded binding in the range of 0-32%. Upon irradiation, suspensions previously supplemented with either isomer exhibited approximately 60% binding. Incubation with 11-cis retinal had no substantial effect on the condition of tight binding observed shortly after bleaching. The data are discussed in relation to previous studies of visual pigment bleaching and regeneration.

Pathways in the hydrolysis of vertebrate rhodopsin

A direct method for measuring the amount of retinal 387 was used along with spectral techniques to measure each of the intermediates in the photolysis of rhodopsin and to unequivocally determine the pathways in solution extracts of bovine rhodopsin and excised toad and skate retinas. Metarhodopsin II 380 was the earliest intermediate which hydrolyzed to retinal 387 plus opsin. In excised toad retinas three approaches were used to show that Meta III 465 decayed directly to retinal 387 plus opsin. The only pathway consistent with the data was: (Formula: See text). In solution extracts the formation and hydrolysis of N-Retinylidene-Opsin was also observed.

Effect of pH on the formation and decay of the metarhodopsins of the frog

1. Suspensions of membrane vesicles were prepared by sonication of dark-adapted frog rod outer segments. The pH was adjusted to one of twelve values between 5.0 and 9.8; the temperature was 15 degrees C. Each preparation was exposed to a single yellow flash of 120 microseconds duration, and rapid slow changes of absorbance were measured at 475 nm wavelength. 2. Rapid changes consist of a transient rise followed by a diphasic decay to a new level of absorbance which is lower than that before the light exposure. The level of absorbance reached at the end of the rapid changes is lower at lower pH. 3. Kinetic analysis reveals that three reactants take part in the rapid reactions, viz. metarhodopsin I and two isochromic forms of metarhodopsin II named metarhodopsin II' and metarhodopsin II". The kinetics of the reversible transition from metarhodopsin I to metarhodopsin II' are not measurably influenced by the pH of the medium. However, the reversible reaction of metarhodopsin II' with metarhodopsin II" is dependent on pH because metarhodopsin II" is encountered either as a protonated or as a deprotonated compound. 4. Slow reactions are due to metarhodopsin I and to metarhodopsin III. A combined quantitative analysis of both rapid and slow reactions involves a reversible reaction between metarhodopsin II' and metarhodopsin III and a hydrolysis of metarhodopsin II' to retinal and opsin. The scheme employed accounts for the pH dependence of all equilibria although only one of the metarhodopsins reacts directly with protons.