Neural and Photochemical Mechanisms of Visual Adaptation in the Rat

The effects of light adaptation on the increment threshold, rhodopsin content, and dark adaptation have been studied in the rat eye over a wide range of intensities. The electroretinogram threshold was used as a measure of eye sensitivity. With adapting intensities greater than 1.5 log units above the absolute ERG threshold, the increment threshold rises linearly with increasing adapting intensity. With 5 minutes of light adaptation, the rhodopsin content of the eye is not measurably reduced until the adapting intensity is greater than 5 log units above the ERG threshold. Dark adaptation is rapid (i.e., completed in 5 to 10 minutes) until the eye is adapted to lights strong enough to bleach a measurable fraction of the rhodopsin. After brighter light adaptations, dark adaptation consists of two parts, an initial rapid phase followed by a slow component. The extent of slow adaptation depends on the fraction of rhodopsin bleached. If all the rhodopsin in the eye is bleached, the slow fall of threshold extends over 5 log units and takes 2 to 3 hours to complete. The fall of ERG threshold during the slow phase of adaptation occurs in parallel with the regeneration of rhodopsin. The slow component of dark adaptation is related to the bleaching and resynthesis of rhodopsin; the fast component of adaptation is considered to be neural adaptation.     

Improving parameter estimation for cell surface FRAP data

Fluorescence Recovery After Photobleaching (FRAP) using the confocal laser scanning microscope has become a standard method used to determine the diffusion coefficient and mobile fraction of cell surface proteins. A common experimental approach is to bleach a stripe on the cell surface and fit the ensuing FRAP curve to a 1D diffusion model. This model is derived from the time course of recovery to an infinitely long stripe bleached on an infinite flat plane. This choice of model dictates the use of a long bleach stripe. We demonstrate that, in the case of a long bleach stripe, the finite extent of the cell leads to significant errors in parameter estimation. We further show that these errors are reduced when a relatively small stripe is bleached. Unfortunately, diffusion to such a region is fundamentally two dimensional and therefore applying the 1D model of diffusion leads to significant errors. We derive an equation suitable for fitting to FRAP data acquired from small bleach regions and analyze its accuracy using simulated data. We propose that the use of a small bleach region along with a two dimensional diffusion model is the ideal protocol for cell surface FRAP.     

Hydrogen exchange study of membrane-bound rhodopsin. II. Light-induced protein structure change.

Hydrogen exchange studies of rhodopsin in disc membranes demonstrated that photolysis induces changes in the protein itself. Two different altered forms were detected. A late photointermediate in the bleaching sequence, which can be identified with metarhodopsin II, displays accelerated exchange. Subsequently, at the stage of fully bleached opsin, exchange becomes even slower than in rhodopsin. These changes involve only a small fraction of the protein's internally hydrogen-bonded peptide groups. The unusually large fraction of exposed peptide hydrogens observed previously for rhodopsin is unaltered in the photolyzed forms.     

Illumination of bovine photoreceptor membranes causes phosphorylation of both bleached and unbleached rhodopsin molecules

Bovine rod outer segments were given a series of flashes, each bleaching from 0.1% to 0.4% of the rhodopsin present. 9-cis-Retinal was then added, regenerating the bleaching pigment to isorhodopsin. The phosphorylated pigment species having either four and five or six and eight phosphates were isolated by chromatofocusing. The amounts of rhodopsin and isorhodopsin present in the phosphorylated species were determined spectrally. The species with four and five phosphates per rhodopsin were approximately 50% rhodopsin-50% isorhodopsin. The more highly phosphorylated species were almost entirely isorhodopsin. Presumably, the phosphorylated rhodopsin was phosphorylated without having been bleached. At a 4% bleach level, approximately 0.5 rhodopsin was phosphorylated with four to five phosphates for each rhodopsin that was bleached and phosphorylated.     

Amplitude, kinetics, and reversibility of a light-induced decrease in guanosine 3'',5''-cyclic monophosphate in frog photoreceptor membranes

The concentration of guanosine 3',5'-cyclic monophosphate (cyclic GMP) has been examined in suspensions of freshly isolated frog rod outer segments using conditions which previously have been shown to maintain the ability of outer segments to perform a light-induced permeability change (presence of calf serum, anti-oxidant, and low calcium concentration). Illumination causes a rapid decrease in cyclic GMP levels which has a half-time approximately 125 ms. With light exposures that bleach less than 100 rhodopsin molecules in each rod outer segment, at least 10(4)-10(5) molecules of cyclic GMP are hydrolyzed for each rhodopsin molecule bleached. Half of the total cyclic GMP in each outer segment, approximately 2 X 10(7) molecules, is contained in the light-sensitive pool. If outer segments are exposed to continuous illumination, using intensities which bleach between 5.0 X 10(1) and 5.0 X 10(4) rhodopsin molecules/outer segment per second, cyclic GMP levels fall to a value characteristic for the intensity used. This suggests that a balance between synthesis and degradation of cyclic GMP is established. This constant level appears to be regulated by the rate of bleaching rhodopsin molecules (by the intensity of illumination), not the absolute number of rhodopsin molecules bleached...     

Axial gradients of rhodopsin in light-exposed retinal rods of the toad

Exposure of an intact vertebrate eye to light bleaches the rhodopsin in the photoreceptor outer segments in spatially nonuniform patterns. Some axial bleaching patterns produced in toad rods were determined using microspectrophotometric techniques. More rhodopsin was bleached at the base of the outer segment than at the distal tip. The shape of the bleaching gradient varied with the extent of bleach and with the spectral content of the illuminant. Monochromatic light at the lambda max of the rhodopsin gave rise to the steepest bleaching gradients and induced the greatest changes in the form of the gradient with increasing extent of bleach. These results were consistent with a mathematical model for pigment bleaching in an unstirred sample. The model did not fit bleaching patterns resulting from special lighting conditions that promoted the photoregeneration of rhodopsin from the intermediates of bleaching. Prolonged light adaptation of toads could also produce axial rhodopsin gradients that were not fit by the bleaching model. Under certain conditions the axial gradient of rhodopsin in a rod outer segment reversed with time in the light: the rhodopsin content became highest at the base. This result could be explained by an interaction between the pattern of bleaching and the intracellular topography of regeneration.     

Lateral diffusion of rhodopsin in photoreceptor cells measured by fluorescence photobleaching and recovery.

Frog rod outer segments were labeled with the sulfhydryl-reactive label iodoacetamido tetramethylrhodamine. The bulk of the label reacted with the major disk membrane protein, rhodopsin. Fluorescence photobleaching and recovery (FPR) experiments on labeled rods showed that the labeled proteins diffused rapidly in the disk membranes. In these FPR experiments we observed both the recovery of fluorescence in the bleached spot and the loss of fluorescence from nearby, unbleached regions of the photoreceptor. These and previous experiments show that the redistribution of the fluorescent labeled proteins after bleaching was due to diffusion. The diffusion constant, D, was (3.0 +/- 10(-9) cm2 s-1 if estimated from the rate of recovery of fluorescence in the bleached spot, and (5.3 +/- 2.4) x 10(-9) cm2 s-1 if estimated from the rate of depletion of fluorescence from nearby regions. The temperature coefficient, Q10, for diffusion was 1.7 +/- 0.5 over the range 10 degrees--29 degrees C. These values obtained by FPR are in good agreement with those previously obtained by photobleaching rhodopsin in fresh, unlabeled rods. This agreement indicates that the labeling and bleaching procedures required by the FPR method did not significantly alter the diffusion rate of rhodopsin. Moreover, the magnitude of the diffusion constant for rhodopsin is that to be expected for an object of its diameter diffusing in a bilayer with the viscosity of the disk membrane. In contrast to the case of rhodopsin, FPR methods applied to other membrane proteins have yielded much smaller diffusion constants. The present results help indicate that these smaller diffusion constants are not artifacts of the method but may instead be due to interactions the diffusing proteins have with other components of the membrane in addition to the viscous drag imposed by the lipid bilayer.     

The action of enzymes on rhodopsin

The effects have been examined of chymotrypsin, pepsin, trypsin, and pancreatic lipase on cattle rhodopsin in digitonin solution. The digestion of rhodopsin by chymotrypsin was measured by the hydrolysis of peptide bonds (formol titration), changes in pH, and bleaching. The digestion proceeds in two stages: an initial rapid hydrolysis which exposes about 30 amino groups per molecule, without bleaching; superimposed on a slower hydrolysis which exposes about 50 additional amino groups, with proportionate bleaching. The chymotryptic action begins at pH about 6.0 and increases logarithmically in rate to pH 9.2. Trypsin and pepsin also bleach rhodopsin in solution. A preparation of pancreatic lipase bleached it slightly, but no more than could be explained by contamination with proteases. In digitonin solution each rhodopsin molecule is associated in a micelle with about 200 molecules of digitonin; yet the latter do not appear to hinder enzyme action. It is suggested that the digitonin sheath is sufficiently fluid to be penetrated on collision with an enzyme molecule; and that once together the enzyme and substrate are held together by intermolecular attractive forces, and by the "cage effect" of bombardment by surrounding solvent molecules. The two stages of chymotryptic digestion of rhodopsin may correspond to an initial rapid fragmentation, such as has been observed with many proteinases and substrates; superimposed upon a slower digestion of the fragments. Since the first phase involves no bleaching, this may mean that rhodopsin can be broken into considerably smaller fragments without loss of optical properties.     

The contribution of a sensitizing pigment to the photosensitivity spectra of fly rhodopsin and metarhodopsin.

Most of the photoreceptors of the fly compound eye have high sensitivity in the ultraviolet (UV) as well as in the visible spectral range. This UV sensitivity arises from a photostable pigment that acts as a sensitizer for rhodopsin. Because the sensitizing pigment cannot be bleached, the classical determination of the photosensitivity spectrum from measurements of the difference spectrum of the pigment cannot be applied. We therefore used a new method to determine the photosensitivity spectra of rhodopsin and metarhodopsin in the UV spectral range. The method is based on the fact that the invertebrate visual pigment is a bistable one, in which rhodopsin and metarhodopsin are photointerconvertible. The pigment changes were measured by a fast electrical potential, called the M potential, which arises from activation of metarhodopsin. We first established the use of the M potential as a reliable measure of the visual pigment changes in the fly. We then calculated the photosensitivity spectrum of rhodopsin and metarhodopsin by using two kinds of experimentally measured spectra: the relaxation and the photoequilibrium spectra. The relaxation spectrum represents the wavelength dependence of the rate of approach of the pigment molecules to photoequilibrium. This spectrum is the weighted sum of the photosensitivity spectra of rhodopsin and metarhodopsin. The photoequilibrium spectrum measures the fraction of metarhodopsin (or rhodopsin) in photoequilibrium which is reached in the steady state for application of various wavelengths of light. By using this method we found that, although the photosensitivity spectra of rhodopsin and metarhodopsin are very different in the visible, they show strict coincidence in the UV region. This observation indicates that the photostable pigment acts as a sensitizer for both rhodopsin as well as metarhodopsin.     

Isolation and recombination of bovine rod outer segment cGMP phosphodiesterase and its regulators

cGMP phosphodiesterase extracted from rod outer segments can be activated by GTP in the presence of phospholipid vesicles containing bleached rhodopsin. I have separated the phosphodiesterase from a phosphodiesterase inhibitory protein and a GTPase also present in the crude extracts from rods. The GTPase can be activated by bleached rhodopsin. However, in the absence of the GTPase and inhibitor, the phosphodiesterase was not activated by GTP in the presence of bleached rhodopsin. Recombination with these proteins partially restored the activation by GTP and bleached rhodopsin.     

Measurement of fast light-induced disc shrinkage within bovine rod outer segments by means of a light-scattering transient

A fast light-induced light-scattering transient, previously found in rod outer segment suspension, the so-called P-signal (Hofmann, K.P., Uhl, R., Hoffmann, W. and Kreutz, W. (1976) Biophys. Struct. Mechanism 2, 61–77), is described in more detail.The effect has the same action spectrum as rhodopsin bleaching. It is not regenerated with 11-cis retinal.The response is not linear with light-intensity for flashes which bleach more than 2.0% of rhodopsin; it saturates at an intensity corresponding to 15% rhodopsin bleaching.The wavelength- and scattering angle dependence lead to the conclusion that the change in light-scattering reflects a shrinkage of an osmotic compartment of the rod outer segment.The only compartment which we found to be intact in our rod outer segment preparations was the disc or rod sac; therefore, the effect must be attributed to a light-induced shrinkage of the rhodopsin-containing disc organelles.The overall effect (15% of rhodopsin is bleached) is in the range of 0.5–1.5% of the original volume.A light-induced passive cation-efflux from the disc, e.g. of Ca²⁺, can be ruled out as a possible molecular origin of the disc-shrinkage in our preparations.     

Extraction,regeneration after bleaching,and ion-exchange chromatography of rhodopsin in Tween 80

Rhodopsin can be readily and somewhat, selectively extracted into Tween 80 solutions from the isolated photoreceptor particulate fraction of bovine retinal tissue. Approximately 80% of the rhodopsin is recovered from the particulate fraction with A₄₉₈ values of approximately 6 and spectral ratios (A₂₇₈:A₄₉₈) of 1.8-1.9. The solutions are estimated to be approximately 97% pure based upon assay of protein and rhodopsin content and 98% pure based upon chromatography on DEAE-cellulose. The bulk of the rhodopsin can be regenerated after bleaching in Tween 80. Partial regenerability is retained when solutions of unbleached or bleached rhodopsin in Tween 80 are further purified by DEAE-cellulose chromatography.     

Dark Ionic Flux and the Effects of Light in Isolated Rod Outer Segments

We have determined the permeability properties of freshly isolated frog rod outer segments by observing their osmotic behavior in a simple continuous flow apparatus. Outer segments obtained by gently shaking a retina are sensitive but nonideal osmometers; a small restoring force prevents them from shrinking or swelling quite as much as expected for ideal behavior. We find that Na⁺, Cl^-, No₃^-, glycerol, acetate, and ammonium rapidly enter the outer segment, but K⁺, SO₄⁼, and melezitose appear impermeable. The Na flux is rectified; for concentration gradients in the physiological range, 2 x 10⁹ Na⁺ ions/sec enter the outer segment, but we detect no efflux of Na⁺, under our conditions, when the gradient is reversed. Illumination of the outer segment produces a specific increase in the resistance to Na⁺ influx, but has no effect on the flux of other solutes. This light-dependent Na⁺ resistance increases linearly with the number of rhodopsin molecules bleached. We find that excitation of a single rhodopsin molecule produces a transient (~1 sec) "photoresistance" which reduces the Na⁺ influx by about 1%, thus preventing the entry of about 10⁷ Na⁺ ions. At considerably higher light levels, a stable afterimage resistance appears which reduces the Na influx by one-half when 10⁶ rhodopsin molecules are bleached per rod. We have incorporated these findings into a model for the electrophysiological characteristics of the receptor.     

Polarized sorting of rhodopsin on post-Golgi membranes in frog retinal photoreceptor cells

We have isolated a subcellular fraction of small vesicles (mean diameter, 300 nm) from frog photoreceptors, that accumulate newly synthesized rhodopsin with kinetics paralleling its appearance in post-Golgi membranes in vivo. This fraction is separated from other subcellular organelles including Golgi and plasma membranes and synaptic vesicles that are sorted to the opposite end of the photoreceptor cell. The vesicles have very low buoyant density in sucrose gradients (rho = 1.09 g/ml), a relatively simple protein content and an orientation of rhodopsin expected of transport membranes. Reversible inhibition of transport by brefeldin A provides evidence that these vesicles are exocytic carriers. Specific immunoadsorption bound vesicles whose protein composition was indistinguishable from the membranes sedimented from the subcellular fraction. Some of these proteins may be cotransported with rhodopsin to the rod outer segment; others may be involved in vectorial transport.     

Continuation of sexual reproduction in <Emphasis Type="Italic">Montipora capitata</Emphasis> following bleaching

Bleaching is generally expected to produce detrimental impacts on coral reproduction. This study compared the fecundity of bleached and unbleached colonies of the Hawaiian coral Montipora capitata. It was hypothesized that bleaching would have no effect on reproduction because previous studies have shown that Montipora capitata can increase heterotrophic feeding following bleaching. Reproductive parameters, total reproductive output (bundles released ml⁻¹ coral colony), number of eggs bundle⁻¹, and egg size, measured in the summer of 2005 did not differ between colonies that bleached or did not bleach during 2004. These data were collected following a single bleaching event and cannot be used to predict the outcome should bleaching episodes become more frequent or severe.     

In vitro identification of rhodopsin in the green alga Chlamydomonas

The unicellular alga Chlamydomonas can detect both intensity and direction of the ambient light and adjust its swimming speed and direction accordingly. On the basis of physiological experiments, the functional photoreceptor for this visual process has recently shown to be a rhodopsin. We here report the in vitro identification of endogenous retinal and a rhodopsin in Chlamydomonas cell extracts and purified membrane preparations. The rhodopsin absorption spectrum has fine structure with the maximum at 495 nm and matches the action spectra for the behavioral light responses. The rhodopsin can be bleached and subsequently reconstituted with exogenous retinal. Labeling with [3H]retinal occurs in the final preparation only with a single protein with a molecular weight of 32,000. We conclude that this protein is the visual photoreceptor in Chlamydomonas.     

On a soluble system for studying light activation of rod outer segment cyclic GMP phosphodiesterase

Bovine rod outer segment (ROS) cyclic GMP phosphodiesterase (PDE) could be activated about 6-fold by light, an effect that could be simulated by isolated bleached rhodopsin. About 90% of PDE activity in ROS could be extracted with 10 mM Tris-HCl, pH 7.5, but light is ineffective in activating the soluble enzyme. However, bleached rhodopsin could activate it in the presence of a very low concentration of ATP, strongly suggesting the mediation of rhodopsin in the light activation of the enzyme in ROS. Direct evidence is presented to suggest that the phosphorylation of opsin (bleached rhodopsin) is unrelated to the activation of PDE by bleached rhodopsin and ATP. The reconstitution of the light activation of PDE in a soluble system presented here opens up a new direction to future investigations on the mechanism of light regulation of cyclic GMP levels in retina and its implication in the photoreceptor function.     

Inactivation of photoexcited rhodopsin in retinal rods: the roles of rhodopsin kinase and 48-kDa protein (arrestin)

The inactivation of excited rhodopsin in the presence of ATP, rhodopsin kinase, and/or arrestin has been studied from its effect on the two subsequent steps in the light-induced enzymatic cascade: metarhodopsin II catalyzed activation of G-protein and G-protein-dependent activation of cGMP phosphodiesterase. The inactivation of G-protein (from light-scattering measurements) and that of phosphodiesterase (from measurements of cGMP hydrolysis) have been studied and compared in reconstituted systems containing various combinations of the proteins involved (rhodopsin, G-protein, phosphodiesterase, kinase, and arrestin). Our results show that rhodopsin kinase alone can terminate the activation of G-protein and that arrestin speeds up the process at a relative concentration similar to that reported in the rod (half-maximal effect at 50 nM for 4.4 microM rhodopsin). Measurements of rhodopsin phosphorylation under identical conditions show that in the presence of arrestin total metarhodopsin II inactivation is achieved when only 0.5-1.4 phosphates are bound per bleached rhodopsin, whereas in the absence of arrestin it requires binding of 12-16 phosphates per bleached rhodopsin. Phosphodiesterase activity can similarly be turned off by kinase, and the process is similarly accelerated by arrestin.     

Cyclic nucleotide dependent protein kinase and the phosphorylation of endogenous proteins of retinal rod outer segments.

Cyclic nucleotide dependent protein kinase has been extracted wiht Tris or Lubrol PX from purified rod outer segments (ROS) of bovine retina. The activity of the enzyme is unaffected by light but is stimulated by either cyclic guanosine 3',5'-monophosphate (cGMP) or cyclic adenosine 3',5'-monophosphate (cAMP). Most of the solubilized enzyme elutes from DEAE-cellulose with about 0.18 M NaCl (type II protein kinase). An endogenous 30,000 molecular weight protein of the soluble fraction of ROS as well as exogenous histone are phosphorylated by the protein kinase in a cyclic nucleotide dependent manner. The Tris-extracted enzyme can be reassociated in the presence of Mg2+ with ROS membranes that are depleted of protein kinase activity. The reassociated protein kinase is insensitive to exogenous cyclic nucleotides, and it catalyzes the phosphorylation of the membrane protein, bleached rhodopsin. While the soluble and membrane-associated protein kinases may be interchangeable, they appear to be modulated by different biological signals; soluble protein kinase activity is increased by cyclic nucleotides whereas membrane-bound activity is enhanced when rhodopsin is bleached by light.     

A method improving the accuracy of fluorescence recovery after photobleaching analysis

Fluorescence recovery after photobleaching has been an established technique of quantifying the mobility of molecular species in cells and cell membranes for more than 30 years. However, under nonideal experimental conditions, the current methods of analysis still suffer from occasional problems; for example, when the signal/noise ratio is low, when there are temporal fluctuations in the illumination, or when there is bleaching during the recovery process. We here present a method of analysis that overcomes these problems, yielding accurate results even under nonideal experimental conditions. The method is based on circular averaging of each image, followed by spatial frequency analysis of the averaged radial data, and requires no prior knowledge of the shape of the bleached area. The method was validated using both simulated and experimental fluorescence recovery after photobleaching data, illustrating that the diffusion coefficient of a single diffusing component can be determined to within ∼1%, even for small signal levels (100 photon counts), and that at typical signal levels (5000 photon counts) a system with two diffusion coefficients can be analyzed with <10% error.