A light scattering study on the ion permeabilities of dark-adapted bovine rod outer segment disk membranes

Light-induced proton permeability changes in retinal rod photoreceptor disk membranes

We have used the membrane-permeant charged fluorescent dye, 3,3'-dipropylthiadicarbocyanine iodide (diS-C3[5]), to monitor electrical potentials across the membranes of isolated bovine disks. Calibration curves obtained from experiments where a potential was created across the disk membrane by a potassium concentration gradient and valinomycin showed an approximately linear relation between dye fluorescence and calculated membrane potential from 0 to -120 mV. Light exposure in the presence of the permeant buffer, imidazole, caused a rapid decay of the membrane potential to a new stable level. Addition of CCCP, a proton ionophore, in the dark produced the same effect as illumination. When the permeant buffer, imidazole, was replaced by the impermeant buffer, Hepes, neither light nor CCCP discharged the gradient. We interpret the changes in membrane potential measured upon illumination to be the result of a light-induced increase in the permeability of the disk membrane to protons. A permeant buffer is required to prevent the build-up of a pH gradient which would inhibit the sustained proton flow needed for an observable change in membrane potential.

Optical probes of intradiskal processes in rod photoreceptors. II: Light-scattering study of ATP-dependent light reactions

Rod outer segment (ROS) disks, either stacked or freely floating, respond to flash illumination to yield a specific, ATP-dependent, light-scattering signal AL. In broken ROS AL signals occur only when AD signals have preceded them. The degree to which the preceding AD signal has been completed determines the amplitude of the following AL signal. However, in freshly detached ROS from dark-adapted frogs Al signals with maximal size can be obtained without pre-incubation with exogenous ATP. The energized state, which is restored in broken ROS with the help of ATP, appears to prevail in the living retina and must therefore be considered to be "physiological". AL signals require structurally intact disks. Neither peripheral ROS proteins nor connecting filaments between adjacent disks are necessary. Their structural origin is the same as that of the preceding AD signal, i.e. osmotic disk swelling. AL signals consist of a single slow kinetic component (half-life 10 s at room temperature) and multiphase fast kinetic component (70 ms). The slow phase corresponds to a light-stimulated resumption of ATPase activity (this has been dealt with in a previous paper) whereas the fast component reflects an immediate response of the energized disk to the metarhodopsin I to metarhodopsin II transition. The latter effect is the subject of this paper. A variety of experiments, using different ATPase inhibitors, ionophores and membrane-permeable salts, have been carried out; they are all consistent with notion that AL originates in the disk interior and probes the existence of a proton electrochemical potential difference delta mu (H+) across the disk membrane. A model is presented which can explain all given properties of AL satisfactorily. According to this model the photolysis of rhodopsin causes a proton release in the disk lumen. This, in turn, results in osmotic swelling of the disks, provided that the internal buffer sites have been (at least partially) titrated with protons prior to the flash. Such conditions, i.e. a low internal pH, are provided by the proton transport across the disk membrane, which presumably takes place during the course of the preceding AD signal.

Optical probes of intradiskal processes in rod photoreceptors. I: Light-scattering study of ATP-dependent dark reactions

ATP can cause dramatic structural changes in the outer segment of rod photoreceptors. These changes can be visualized by means of a concomitant light-scattering signal AD, a decrease in scattered light intensity of over 20%. The large size of the signal suggests that major structural changes occur. The underlying molecular events may reflect an important, yet still unknown, part of the photoreceptor machinery. AD signals reflect ATPase-driven transmembrane events which occur in and at the disk membrane. Their only structural prerequisite is the structural integrity of the disk compartment. The angular dependence of AD, which can be mimicked by an osmotically-induced disk-swelling, suggests that the disk compartment swells during the production of the AD signal. AD signals proceed with first-order kinetics (half-life = 1 min at 20 degrees C and ATP concentrations of greater than 100 microM) and are accompanied by the hydrolysis of approximately 4 mol ATP (mol rhodopsin)-1. The AD signal is inhibited by a number of transport ATPase inhibitors (quercetin, NBD.Cl, vanadate, DCCD), but not by oligomycin, azide and ouabain. The sensitivity to DCCD, together with the fact that except magnesium no other cation has to be present, points to a proton translocation. This proton transport appears to be electrogenic, since AD signals require the presence of a permeant anion. In physiological saline this is chloride, and the chloride flux is facilitated by a DIDS-sensitive anion transport unit in the disk membrane.

The influence of carbohydrates on the binding of rod outer-segment (ROS) disc membranes and intact ROS by the cells of the retinal pigment epithelium of the embryonic chick

The role of carbohydrates in mediating the interaction of rhodopsin-containing membranes with retinal pigment epithelium (RPE) cells was investigated by studying the influence of various monosaccharides on their binding by RPE cells of the embryonic chick maintained in cell culture. Rod outer-segment (ROS) disc membranes were selected as a model rhodopsin-containing membrane system for these studies in view of their high concentration of rhodopsin and the relative purity with which they can be isolated. Disc membranes, frozen and thawed in order to expose the carbohydrate groups of rhodopsin which are oriented intraluminally in situ, were incubated with monolayers of RPE cells under various conditions, and the binding of the membranes by the cells was quantitated by radioimmunoassay for rhodopsin. Cell-membrane association was also verified by indirect immunofluorescence microscopy. The surface accessibility of the sugars in frozen-thawed discs was verified by succinyl concanavalin A-binding studies. From 15- to 20-fold increase in carbohydrate-reactive sites was obtained after freezing and thawing the discs. The RPE cell-membrane binding process was saturable, and time- and temperature-dependent. By means of competition studies carried out in the presence of high concentrations of various monosaccharides, and also by comparing the binding of disc membranes whose carbohydrate groups were either exposed (frozen-thawed) on the surface or inaccessible (native), it was concluded that the carbohydrates of rhodopsin, mannose and N-acetylglucosamine, were not involved in the interaction with the RPE. The possibility was also examined that enzymatically galactosylated rhodopsin might serve as a site for recognition by the RPE cell. The binding of ROS disc membranes modified in this manner was not enhanced, indicating that the presence of galactose groups on rhodopsin did not serve as a site for recognition by the RPE. The influence of monosaccharides on the binding of intact ROS by the RPE cells was also investigated. Similar to the results with the disc membranes, the process was not blocked by the presence in the incubation medium of high concentrations (up to 30,000-fold higher than that of rhodopsin) of mannose or GlcNAc, as with the disc membranes, or by glucose or galactose. Thus, from these studies it is concluded that a lectin-like carbohydrate-recognition process may not be involved in the interaction between rhodopsin-containing membranes and the RPE cells.

A functional link between the dark Mg-ATPase activity and the light-induced enzymatic cascade in rod outer segments

The characterization of a light-induced scattering change in suspensions of rod fragments, which requires previous swelling of the disks by the dark Mg-ATPase described by Uhl et al. [FEBS Lett. 107, 317-322 (1979)] is reported here. Reconstitution experiments demonstrate that this signal is dependent on the presence of G-protein, GTP and cGMP phosphodiesterase. Fast reversal associated with regenerability requires in addition the presence of some protein(s) of the cytoplasm (probably the rhodopsin kinase) and ATP. The amount of excited rhodopsin which saturates the signal is the same as that which saturates the previously described 'dissociation signal' [Kühn et al. (1981) Proc. Natl Acad. Sci. USA 78, 6873-6877] associated with the formation of the phosphodiesterase activator G alpha GTP (alpha subunit of the G-protein with GTP bound). The kinetics of the signal is slightly slower than that of the dissociation signal and its amplitude is proportional to the extent of swelling of the disks. These results suggest that the interaction between G alpha GTP and the phosphodiesterase modifies some structural feature of the disks and provide evidence for the existence of a functional link between the dark Mg-ATPase and the light-induced enzymatic cascade.

Permeability of rod outer segment disk membranes as probed by Ficoll density gradient centrifugation and by turbidimetry

Osmotic volume changes of isolated disks prepared from bovine rod outer segments were investigated utilizing the capacity of osmotically intact disks to float on 2.5% (w/v) Ficoll under hypotonic conditions. The amount of floating disks decreases steadily and approximately linearly when the osmolarity is increased stepwise with an osmotically active solute. The slope of the decrease becomes smaller for partially permeable substances and no decrease in observed for fully permeable solutes. All ions assayed by this method as well as sucrose were osmotically fully active to disk membranes. The buffer molecules Tris and imidazole partially penetrated the disk membranes at pH 7, whereas the zwitterionic buffer Hepes was impermeable. Ethanol showed absolutely no osmotic activity to disk membranes and, therefore, can easily penetrate these membranes. concurrent turbidimetric measurements and, therefore, can easily penetrate these membranes. Concurrent turbidimetric measurements confirmed these results. Upon prolonged exposure of disk membranes to 5% (w/v) Ficoll, a considerable modification of the osmotic properties of disk membranes is observed, indicating a significant interaction of 5% (w/v) Ficoll with disk membranes. No influence of 2.5% (w/v) Ficoll on the osmotic properties of disk membranes was detected. The restriction of the use of Ficoll for disk membrane preparative purposes will be discussed.

Separation and characterisation of light scattering transients from rod outer segments of vertebrate photoreceptors: design and performance of a Multi Angle Flash Photolysis Apparatus (MAFPA)

A device was built for the simple computer-controlled routine determination of the angular dependence of light scattering transients obtained from biological material. It was called Multi Angle Flash Photolysis Apparatus (MAFPA). The MAFPA allows the simultaneous registration of rapid, light-induced light scattering transients at eight scattering angles between 0 degree and 28 degrees. In typical applications changes in scattered light intensity as small as delta I/I = 4 X 10(-5) can be resolved at scattering angles less than 24 degrees, while at 28 degrees the resolution drops to delta I/I = 2 X 10(-4). The time resolution is 32 microseconds. The MAFPA was designed for high accuracy, ease of use and ruggedness. It is made from relatively inexpensive parts and can be copied fairly easily by a good machine/electronics shop. In this communication we describe the design of the MAFPA and how it was used for the characterisation of four structurally distinct light-induced light scattering signals from photoreceptor rod outer segments. These signals are known as P (or binding) signal, G- (or dissociation) signal, N (or rhodopsin) signal and as the ATP-dependent signal AL. The signals have been separated by means of their different angular dependence, their different saturation behavior and nucleotide requirement. A great number of detailed studies will have to be carried out before one can fully understand the physical and biochemical origin of these signals. At this point, however, it can be stated that the so-called 'dissociation signal', showing an angular dependence indicative of a change in refractive index or scattering mass, is not merely an inversion of the preceding 'binding signal', the latter clearly reflecting a gross structural change, i.e. a shrinkage of the disks. Moreover, there are conditions where P signals are observed to persist even after the completion of the subsequent dissociation signals. The two remaining signals N and AL show a pronounced angular dependence which is not easily interpreted. The fact that both exhibit a maximal amplitude at relatively small angles seems to indicate the participation of rather large structural domains.

Light changes the membrane potential and ion balances of retinal rod disks

Light stimulation of rod cells in vertebrate eyes may cause Ca2+ release from the intracellular disks. Radiolabelled tracers show that light causes a small hyperpolarization of intact disk stacks and redistribution of the ions Ca2+ and Cl-.

Elemental distribution in Rana pipiens retinal rods: quantitative electron probe analysis

The composition of dark-adapted and illuminated retinal rod outer and inner segments and mitochondria was determined with electron probe X-ray micro-analysis of cryosections. The concentration of Ca in the outer segment was 0.4 mmol/kg dry wt. (0.1 Ca/rhodopsin) and did not measurably change upon illumination with saturating light for 5 min. The non-mitochondrial regions of the inner segment contained the highest concentrations (up to 13 mmol/kg dry wt.) of Ca in rods; these regions probably represent the endoplasmic reticulum. The equilibrium potentials estimated from the measured elemental concentrations and the known water content of dark-adapted outer segments were (mV): ENa = +17, EK = -83, ECl = -27. The respective values in the inner segment were: ENa = +20, EK = -89, ECl = -26. The above values were obtained in frog rods bathed in 0.18 mM-Ca Ringer solution. In the outer segment of toad rods bathed in 1.8 mM-Ca Ringer, ENa = +33 mV. The Mg content of the rods was high. The (computed) concentration in the dark-adapted retinae was 11 mM in the outer segment and 24 mM in the inner segment. Illumination caused a reduction in Mg to 9 mM (outer segment) and 16 mM (inner segment). Illumination caused a highly significant reduction in Na and Cl concentrations, and an increase in K concentration in both outer and inner segments. Exposure to Na-free (choline Ringer) solution resulted in reduction in Na to just-detectable levels (3 +/- 1 mmol/kg dry wt.) in the outer segment and to 5 +/- 1 mM in the inner segment. This was associated with a significant loss of Cl and decrease in ECl to -50 mV. The low Na content of the outer segment in the Na-depleted rods is not compatible with an extracellular concentration (105 mM) of inexchangeable Na in the intradiskal space. Mitochondrial Na and Mg paralleled the changes in the cytoplasmic concentrations: both mitochondrial Na and Mg were significantly decreased in illuminated, compared to dark-adapted rods. There was no detectable Ca (0 +/- 0.2 mmol/kg dry wt.) in mitochondria of dark-adapted rods containing high concentrations of Na; mitochondrial Ca was slightly higher (0.5 +/- 0.2 mmol/kg dry wt.) in the mitochondria that contained low Na following illumination.

Incorporation of ion channels from bovine rod outer segments into planar lipid bilayers

Membranes vesicles, prepared from bovine rod outer segments were fused with planar lipid bilayers. Two different ion channels were identified by recording currents from single channels. Both types of channels were selective for sodium rather than potassium and were impermeable to chloride ions. Unit conductances were 20 and 120 pS, respectively, in 150 mM sodium chloride. The channel with the larger unit conductance was sensitive to the transmembrane potential. This channel rapidly activated within less than 10 ms after a voltage jump to a more negative membrane potential and then inactivated after several seconds. The duration of the active period and the properties of the channel depended on the amplitude of the voltage jump. The channel of smaller unit conductance did not show any voltage-dependent activation or inactivation. Both types of channels were insensitive to light in the planar bilayer system. Channels incorporated into planar bilayers on a Teflon sandwich septum or on the tip of a glass micropipette gave similar results.

ATP causes a structural change in retinal rod outer segments: disc swelling is not involved

Mg2+-ATP was found to produce a 15 to 30% drop in the turbidity of suspensions of broken retinal rod outer segments from the toad Bufo marinus, prepared by washing or flotation in sucrose. This in vitro process has a half-time of about two minutes and appears to be irreversible. It is not affected by the bleaching of rhodopsin. Direct measurements show that the drop in turbidity is not due to swelling of the disc internal space measured in outer segments recovered by centrifugation. Instead, the total packed volume of the outer segments increases following incubation in Mg2+-ATP. Under the specific conditions of these experiments, the total pellet volume increase was 26 +/- 22% (13 experiments) when corrected for the percent of rhodopsin recovered in the centrifugal pellet. The magnitude of the ATP effect on turbidity suggests that the majority of the discs are involved in some kind of structural change. Vanadium in the +5 oxidation state (vanadate) is an inhibitor of the Mg2+-ATP effect on turbidity at a half-maximal concentration of 0.2 to 0.4 microM, and inhibition is rapidly reversed by norepinephrine, which complexes vanadate. A Mg2+-ATPase activity in extensively washed outer segment membranes, previously shown to be activated as much as twofold following light exposure of the membranes, is not sensitive to vanadate at the concentrations which block the ATP-dependent change of turbidity.

Calcium metabolism in vertebrate photoreceptors

So far all attempts to demonstrate a rapid, light-stimulated release of calcium from disks into the cytosol at a sufficiently high stoichiometry have failed. Either the release stoichiometry was too small or the velocity too slow to account for the amplification in visual transduction. The multitude of failures demonstrate that regulation of intracellular calcium is a very delicate process and the idea of a robust calcium channel in the disk membrane that is opened by rhodopsin itself is certainly an oversimplification. The strongest evidence in favour of the "calcium transmitter hypothesis" is the large calcium efflux from rods in a retina. However as long as the source of the calcium efflux inside the rod cells is unknown conclusions about the role of this calcium efflux are premature. Unfortunately, measurements of intracellular calcium, such as those by Brown and coworkers (93,94) in their pioneering work on photoreceptors in the ventral eye of Limulus, have not yet been feasible in vertebrates.

ESR spin-label studies of lipid-protein interactions in membranes

Lipid spin labels have been used to study lipid-protein interactions in bovine and frog rod outer segment disc membranes, in (Na+, K+)-ATPase membranes from shark rectal gland, and in yeast cytochrome oxidase-dimyristoyl phosphatidylcholine complexes. These systems all display a two component ESR spectrum from 14-doxyl lipid spin-labels. One component corresponds to the normal fluid bilayer lipids. The second component has a greater degree of motional restriction and arises from lipids interacting with the protein. For the phosphatidylcholine spin label there are effectively 55 +/- 5 lipids/200,000-dalton cytochrome oxidase, 58 +/- 4 mol lipid/265,000 dalton (Na+, K+)-ATPase, and 24 +/- 3 and 22 +/- 2 mol lipid/37,000 dalton rhodopsin for the bovine and frog preparations, respectively. These values correlate roughly with the intramembrane protein perimeter and scale with the square root of the molecular weight of the protein. For cytochrome oxidase the motionally restricted component bears a fixed stoichiometry to the protein at high lipid:protein ratios, and is reduced at low lipid:protein ratios to an extent which can be quantitatively accounted for by random protein-protein contacts. Experiments with spin labels of different headgroups indicate a marked selectivity of cytochrome oxidase and the (Na+, K+)-ATPase for stearic acid and for cardiolipin, relative to phosphatidylcholine. The motionally restricted component from the cardiolipin spin label is 80% greater than from the phosphatidylcholine spin label for cytochrome oxidase (at lipid:protein = 90.1), and 160% greater for the (Na+, K+)-ATPase. The corresponding increases for the stearic acid label are 20% for cytochrome oxidase and 40% for (Na+, K+)-ATPase. The effective association constant for cardiolipin is approximately 4.5 times greater than for phosphatidylcholine, and that for stearic acid is 1.5 times greater, in both systems. Almost no specificity is found in the interaction of spin-labeled lipids (including cardiolipin) with rhodopsin in the rod outer segment disc membrane. The linewidths of the fluid spin-label component in bovine rod outer segment membranes are consistently higher than those in bilayers of the extracted membrane lipids and provide valuable information on the rate of exchange between the two lipid components, which is suggested to be in the range of 10(6)-10(7) s-1.

Rapid calcium release and proton uptake at the disk membrane of isolated cattle rod outer segments. 1. Stoichiometry of light-stimulated calcium release and proton uptake

We reported a rapid, light-stimulated release of calcium from isolated rod outer segments that is apparent only when both the disk membrane and the plasma membrane are made permeable to calcium by adding the ionophore A23187 [Kaupp, U. B., Schnetkamp, P. P. M., & Junge, W. (1979) Biochim. Biophys. Acta 552, 390-403]. In this paper, we have investigated the light-sensitive diskal binding sites and the calcium release mechanism in their dependence on the pH and the presence of mono- and divalent cations, including calcium itself. We have observed now that several different rod outer segment preparations (i.e., rod outer segments with an intact plasma membrane, broken cells, and sonicated material) possess a similar dependence of their calcium release on the ionic conditions, however, only if manipulated in a way that gives access to the outer conditions of sites within disks (namely, ionophore added in the case of intact rod outer segments). Monovalent cations, at concentrations between 20 and 40 mM, suppress light-induced calcium release. Divalent and trivalent cations are more efficient inhibitors by 1-2 and 2-3 orders of magnitude, respectively. These results suggest that calcium release is controlled by an interfacial potential. The optimum pH for calcium release is pH 6.3, and virtually no release occurs beyond pH 4.5 and 9. The drop for acidic pH is attributed to the pH dependence of calcium binding to disk membranes, and the drop for alkaline pH is attributed to the pH dependence of the metarhodopsin I/metarhodopsin II transition and the light-stimulated proton uptake. In general, calcium release parallels calcium binding as a function of pH and calcium concentrations, although the release saturates at lower calcium concentrations ((KDapp = 5 microM) than would be expected from the amount of calcium bound (KD = 30-60 microM). The maximum stoichiometry is approximately 1 mol of calcium release per mol of rhodopsin bleached. Concomitant measurements of the light-stimulated uptake of protons by the disk membrane revealed a maximal stoichiometry of 2.8 mol of protons taken up per mol of rhodopsin bleached. We present an integrated description of light-stimulated calcium release, proton uptake, and changes of the interfacial potential at the disk membrane.

Permeability to ions of bovine retinal disk membrane vesicles in the bleached state

The permeability of the bleached disk membrane of retinal rod outer segments to univalent and divalent ions is studied by light scattering. The membranes are isolated from frozen dark-adapted bovine retinae, swollen into spherical vesicles in a hypotonic medium and bleached in dilute suspension and their size is determined by elastic and quasi-elastic light scatterings. Various electrolytes are then added to the suspending medium in order to examine their osmotic activity relative to the vesicles deformation characteristics. By following the deformation behavior of the membrane vesicles by elastic light scattering in terms of the oblate ellipsoidal shell model, the osmotic activity of a given electrolyte is qualitatively deduced and thereby the permeability of the membrane to the electrolyte is ranked in reference to a chosen standard, i.e., sucrose. By this method, we show that the permeabilities to Na+, K+, Mg2+ and Ca2+ are all alike, and those to halides (F-, Cl-, Br-, I-), nitrate and phosphates (HPO4(2-)/H2PO4-) are similar. Acetate, however, is about 3-times more permeative, while sulfate is less permeative than the other anions by about the same factor. The viability of our method is checked with use of an ionophore, lasolocid (X-537A), by establishing partial recovery from the osmotic deformation through the suppression of the cation osmotic effect. Ion-induced aggregation and pH-dependent size and shape changes are both found to be insignificant.