Activation of phosphodiesterase in frog rod outer segment by an intermediate of rhodopsin photolysis. I.

Guanosine 3′,5′-cyclic monophosphate phosphodiesterase (EC 3.1.4.1) in frog rod outer segment prepared by a sucrose stepwise density gradient method was activated by light in the presence of GTP. Rhodopsin in rod outer segment was solubilized with sucrose laurylmonoester and then purified by concavanalin A-Sepharose column. Addition of photo-bleached preparation of the purified rhodopsin to the rod outer segment, which had been prepared by 43% (w/w) sucrose floatation, caused the activation of phosphodiesterase in the dark, while each component of the photo-product eluted from the column (all-trans retinal and opsin) did not. Regenerated rhodopsin prepared from 11-cis retinal and purified opsin activated phosphosdiesterase when it was bleached. From these facts it is suggested that an intermediate or a process of photolysis of rhodopsin causes activation of phosphodiesterase.     

Activation of phosphodiesterase by rhodopsin and its analogues

Activation of guanosine 3,5-cyclic monophosphate (cGMP) phosphodiesterase (EC 3.1.4.35.) in frog rod outer segment membrane by rhodopsin and its analogues was investigated. The Schiff-base linkage between opsin and retinal in rhodopsin was not always necessary for the phosphodiesterase activation. The binding of -ionone ring of retinal to a hydrophobic region of opsin was not enough to induce the enzyme activation. A striking photo-activation of the enzyme was induced by photo-isomerization of rhodopsin analogues from cis to trans form. It seems probable that an expanded conformation of opsin around the retinylidene chromophore induced by the cis to trans isomerization may be the trigger for the activation of phosphodiesterase. On the other hand, the phosphodiesterase in frog rod outer segment was activated by warming of bathorhodopsin to –12 C and then incubating it at the same temperature. Thus, metarhodopsin II or an earlier intermediate than metarhodopsin II should be a direct intermediate for the enzyme activation.Based on material presented at the Fifth International Congress of Eye Research, Eindhoven, October 1982     

Light-enhanced cross-linking of rhodopsin in rod outer segment membranes as detected by chemical probes

Bovine rod outer segment membranes were treated with cross-linking reagents before and after light exposure. Bleached membranes showed enhanced cross-linking with difluorodinitrobenzene or methyl acetimidate compared to dark-adapted membranes. The light-induced enhancement of cross-linking may be due to increased association of rhodopsin monomers in the light and/or due to increased reactivity of amino and sulfhydryl groups of bleached rhodopsin. In some instances, the band ascribed to the rhodopsin monomer in gel electrophoresis appears as a partially resolved doublet. Treatment of bleached rod outer segment membranes with methyl acetimidate improved the resolution of the doublet into two closely migrating bands.     

Two forms of intermediates of frog rhodopsin in rod outer segments

Using frog rod outer segments, we measured changes of the absorption spectrum during the conversion of rhodopsin to a photosteady-state mixture composed of rhodopsin, isorhodopsin and bathorhodopsin by irradiation with blue light (440 nm) at ? 190°C and during the reversion of bathorhodopsin to a mixture of rhodopsin and isorhodopsin by irradiation with red light (718 nm) at ? 190°C. The reaction kinetics was expressed by one exponential in the former case and by two exponentials in the latter. These results suggest that rhodopsin is composed of a single molecular species, while bathorhodopsin is composed of two kinds of molecular species designated as batho₁-rhodopsin and batho₂-rhodopsin. On warming the two forms of bathorhodopsin, each bathorhodopsin converted to its own lumirhodopsin, metarhodopsin I and finally a free all-trans-retinal plus opsin. The absorption spectra of the two forms of bathorhodopsin, lumirhodopsin and metarhodopsin I were measured at ? 190°C. We infer that a rhodopsin molecule in the excited state relaxes to either batho₁-rhodopsin or batho₂-rhodopsin, and then converts to its own intermediates through one of the two parallel pathways.     

Isolation of rhodopsin by the combined action of cardiotoxin and phospholipase A2 on rod outer segment membranes

Freeze-fracture electron microscopy was used to follow morphological changes induced by Naja mossambica mossambica venom V₄^II cardiotoxin in rod outer segment membrane preparations. The extent of the morphological changes depended on the purity of the cardiotoxin. Pure cardiotoxin had no detectable effect upon the preparation, but, when contaminated with venom phospholipase A₂, let to a rapid disintegration of the membrane vesicles. With trace amounts (up to about 0.5% of the cardiotoxin) of phospholipase A₂, the membrane vesicles disintegrated into smooth lamellae and particles in solution. These two components were separated by centrifugation. The pellet, which showed the presence of smooth lamellae and aggregated particles, was composed of unbleached rhodopsin, initial membrane lipids, lysolipids and cardiotoxin. The supernatant, which showed only the presence of dispersed particles, was composed of unbleached rhodopsin, lysolipids and cardiotoxin. With cardiotoxin containing larger amounts of phospholipase A₂ (more than 0.5% of the cardiotoxin), membrane vesicles were disintegrated into large aggregates of amorphous material, composed of bleached rhodopsin, initial membrane lipids, lysolipids and cardiotoxin. These results confirm our previous observation on the release of integral membrane proteins from membrane vesicles by the action of cardiotoxin containing traces of phospholipase A₂ (Gulik-Krzywicki, T., Balerna, M., Vincent, J.P. and Lazdunski, M. (1981) Biochim. Biophys. Acta 643, 101–114) and suggest its possible use for isolation and purification of integral membrane proteins.     

Disaturated and dipolyunsaturated phospholipids in the bovine retinal rod outer segment disk membrane

Thin-layer chromatography was used to separate the major phospholipid headgroup classes of the rod outer segment disk membrane into subfractions which differ markedly in fatty acid composition. At least 18% of the rod outer segment phosphatidylcholine must contain two saturated fatty acids. Furthermore, two unsaturated fatty acids are found in at least 43% of the phosphatidylserine, 24% of the phosphatidylcholine, and 24% of the phosphatidylethanolamine. The unsaturated acids are predominantly polyunsaturated in all cases. A similar separation, but with less resolution, was achieved with silicic acid column chromatography.The temperature dependence of the polarization of the fluorescence of trans-parinaric acid (9,11,13,15-all-trans-octadecatetraenoic acid) showed that the thermal behavior of aqueous dispersions of the phosphatidylcholine subfractions was consistent with their fatty acid compositions.     

Can metarhodopsin I activate rod outer segment phosphodiesterase?

The rod photoreceptors of vertebrate retinas contain a cGMP phosphodiesterase (PDE) that is activated by light. The light is absorbed by rhodopsin that activates an intermediate GTP-binding protein; this species then activates the PDE. Photo-excited rhodopsin passes through a series of transient states, and the purpose of this study is to identify the earliest state that interacts with the GTP-binding protein and thus activate the PDE. The majority of evidence points to this state being metarhodopsin II (MII), but PDE activation is seen at low temperatures where the rhodopsin reaction sequence is not expected to pass beyond the metarhodopsin I (MI) stage. Light thresholds for PDE activation have been determined under conditions where little MII is generated, and these are compared with the concentration of MII. The conclusion is that for a criterion threshold of PDE activity, the MII concentration is constant, irrespective of the amount of MI present, which suggests that MI cannot activate the PDE system.     

X-ray diffraction analysis of wet isolated bovine rod outer segment disks. A dehydration study

Sequences of X-ray diffraction patterns were obtained from dehydrating, artificially oriented multilayers of isolated, bovine rod outer segment disks. A direct-phase analysis was applied to highly hydrated specimens to determine sequences of low resolution (approx. 30 Å) electron density profiles of the disks as dehydration proceeded. The profiles were found to evolve smoothly as the multilayer lattice simultaneously shrank and became increasingly ordered. The bilayer profiles were largely invariant under dehydration and the evolution of the diffraction consistent with simple decreases in fluid spacings. The specimens were observed to phase separate into characteristic primary and a secondary lattices when the multi-layer became too dehydrated. The small unit cell size of the secondary lattice was suggestive of a lipid phase. Large changes in the diffraction patterns from phase separated specimens were observed upon bleaching of the specimen. The changes were consistent with a reversible disordering of the primary lattice.     

Activation of phosphodiesterase by chicken iodopsin

Activation of guanosine 3',5'-cyclic monophosphate phosphodiesterase in outer-segment membrane of chicken retina was investigated. Irradiation of dark-adapted chicken outer segment membrane for bleaching of iodopsin increased the enzyme activity twice as much as that in the dark in the presence of GTP. Further irradiation of the sample for bleaching of rhodopsin in the membrane induced some additional activation of the enzyme. However, chicken iodopsin activated the enzyme in frog rod outer segment membrane without irradiation, while chicken rhodopsin did not. Irradiation of chicken iodopsin increased the enzyme activity twice as much as that in the dark.     

Lipid-protein interaction in the photolysis of octopus rhodopsin

Microvillar membranes of octopus photoreceptor cells were treated with phospholipase A₂, phospholipase C, hexane, or their combinations. By these means, various membrane preparations containing qualitatively and quantitatively different lipids were obtained. The lipid composition and phospholipid content of the membrane preparations obtained by the above methods were determined.Photochemical processes in the digitonin extract of the native and treated membranes have been studied by flash photometry. The results suggest that several different variations in the lipids can affect the rates of the photochemical transformations; these are: the content of phospholipid, the amount of unsaturated hydrocarbon chains and free fatty acids.     

Distinct states of lipid mobility in bovine rod outer segment membranes Resolution of spin label results

Freely diffusable lipid spin labels in bovine rod outer segment disc membranes display an apparent two-component ESR spectrum. One component is markedly more immobilized than that found in fluid lipid bilayers, and is attributed to lipid interacting directly with rhodopsin. For the 14-doxyl stearic acid spin label this more immobilized component has an outer splitting of 59 G at 0°C, with a considerable temperature dependence, the effective outer splitting decreasing to 54 G at 24°C. Spin label lipid chains covalently attached to rhodopsin can also display a two-component spectrum in rod outer segment membranes. In unbleached, non-delipidated membranes the 16-doxyl stearoyl maleimide label shows an immobilized component which has an outer splitting of 59 G at 0°C and a considerable temperature dependence. This component which is not resolved at high temperatures (24–35°C), is attributed to the lipid chains interacting directly with the monomeric protein, as with the diffusable labels. In contrast, in rod outer segment membranes which have been either delipidated or extensively bleached, a strongly immobilized component is observed with the 16-doxyl maleimide label at all temperatures. This immobilized component has an outer splitting of 62–64 G at 0°C, with very little temperature dependence (61–62 G at 35°C), and is attributed to protein aggregation.     

Activation of cGMP phosphodiesterase by purified green rod pigment from frog retina

Activation of cGMP phosphodiesterase(PDE) of frog rod outer segments (ROS) by purified green rod pigment (GRP) was analyzed. GRP activated PDE in a similar manner to purified rhodopsin. This activation required illumination of the pigment and presence of GTP.     

Effect of light and protein phosphorylation on photoreceptor rod outer segment acyltransferase activity

Rod outer segments (ROS) exhibit high acyltransferase (AT) activity, the preferred substrate of which being lysophosphatidylcholine. To study factors possibly regulating ROS AT activity purified ROS membranes were assayed under conditions under which protein kinase C (PKC), cAMP-dependent protein kinase (PKA), and phosphatases were stimulated or inhibited. PKC activation produced a significant increase in the acylation of phosphatidylethanolamine (PE) and phosphatidylinositol (PI) with oleate, it inhibited phosphatidylcholine (PC) acylation, and phosphatidylserine (PS) and phosphatidic acid (PA) acylation remained unchanged. ROS PKA activation resulted in increased oleate incorporation into PS and PI while the acylation of PC, PE, and PA remained unchanged. Inhibition of ROS PKC or PKA produced, as a general trait, inverse effects with respect to those observed under kinase-stimulatory conditions. ROS phosphatase 2A was inhibited by using okadaic acid, and the changes observed in AT activity are described. These findings suggest that changes in ROS protein phosphorylation produce specific changes in AT activity depending on the phospholipid substrate. The effect of light on AT activity in ROS membranes was also studied and it is reported that acylation in these membranes remains unchanged independent of the illumination condition used.     

Flash photolysis of rhodopsin in rabbit

Flash photolysis of rhodopsin in rabbit's retina has been analysed theoretically, and the results are found to be in good agreement with the experimental results of Hagins (1957). We have also obtained the variation of relative concentrations of rhodopsin, lumirhodopsin, isorhodopsin and metarhodopsin I during the period of the flash corresponding to two different intensities of the flash. It has been found that the quantum efficiencies of conversion of lumirhodopsin into rhodopsin and isorhodopsin will lie in the range 0.24–0.45 and 0.20–0.44 respectively; quantum efficiencies of conversion of metarhodopsin I into rhodopsin and isorhodopsin are found to have values greater than 0.52 and 0.45 respectively and the quantum efficiency of conversion of isorhodopsin into lumirhodopsin has been found to be approximately 0.865. Also the maximum value of the rate constant of the reaction metarhodopsin Imetarhodopsin II at 37 C has been determined in decerebrated eye and it has been found that it is of the same order as found by Pugh (1975) in the case of human eye.Work partially supported by Department of Science and Technology     

Active transducin alpha subunit carries PDE6 to detergent-resistant membranes in rod photoreceptor outer segments

cGMP-Phosphodiesterase 6 (PDE6) is the central effector enzyme in the phototransduction system of vertebrate photoreceptors. We have recently found that PDE6 accumulates in a detergent-resistant membrane (DRM) fraction in response to excitation of bovine rod phototransduction system. Here, we studied the molecular mechanism of the PDE6 translocation to DRM. Pertussis toxin inhibited the translocation of PDE6. Upon addition of AlF(4)(-) to dark-adapted ROS, PDE6 translocated to DRM along with a minor fraction of the alpha subunit of transducin (T alpha). The addition of an excess of the inhibitory subunit of PDE6 blocked its accumulation in the DRM, but did not block the translocation of the minor fraction of T alpha. These data suggested that the formation of a complex between activated T alpha and PDE6 imparted upon T alpha a high affinity for the DRM. The translocation of PDE6 to the DRM may be involved in the spatiotemporal regulation of its activity on disk membranes.     

Calcium-dependent activation and deactivation of rod outer segment phosphodiesterase is calmodulin-independent

ATP-dependent activation and deactivation of retinal rod outer segment phosphodiesterase is affected by calcium [Kawamura, S. and Bownds, M. D., J. Gen. Physiol. 77:571-591(1981)]. Our data demonstrate that although calmodulin has been found in rod outer segments [Liu, Y. P. and Schwartz, H., Biochim. Biophys. Acta 526:186-193(1978); Kohnken, R. E. et al, J. Biol. Chem. 256:12517-12522(1981)], this protein is not involved in calcium-dependent phosphodiesterase activation at light levels at which calcium clearly affects this enzyme's activity. Furthermore, calmodulin does not mediate the calcium-dependent deactivation of phosphodiesterase.     

On the fine structure of the frog's rod outer segments,observed by the freeze-etching technique

Summary The fine structure of the frog's (Rana esculenta) rod outer segments was investigated by two different methods: most of the experiments were made by means of the freeze-etching technique. The replicas were then examined by electron microscopy (40,000 X).By means of a second method, rod outer segments were negatively stained prior to electron microscopy.Inspection of the electron micrographs revealed that the frog's rod outer segments seem to be built up of three groups of elongated structures interpreted as fibrils (Fäden) arranged regularly at approximately equal distances. The diameters of the fibrils are below 100 Å; they depend on the state of light adaptation and on the chemical preparation before freeze-etching. The fibrils partly cross each other. In addition, there were found four groups of approximately equal distances between the fibrils. The order of magnitude of these spacings is from about 50 Å to a few hundred Å.Negatively stained outer segments also reveal fibrils. The results are expressed in a working hypothesis consisting of two parts. It is supposed first that the core of the rod outer segment represents a three dimensional paracrystalline lattice (Raumgitter) of three different types of fibrils (d ₁, d₂, d₄). The distances between the fibrils are interpreted as the lattice constants (a ₁, a₂, a₃, a₄). A unit cell of the lattice would consist of a web (Geflecht) of two different types of fibrils (d ₁, d₂) and four layers of parallel fibrils of the third type (d ₄).It is supposed, secondly, on the basis of a volume-evaluation, that the d₁-fibrils contain rhodopsin, those of type d ₂ another protein (not rhodopsin), and fibrils of type d ₄ lipids.The working hypothesis is supported by experimental findings of other authors (obtained by negative staining and diffraction of light and X-rays).Attempts have been made to relate some electron micrographs of ultrathin sections to those of replicas. (Rosenkranz et al., 1969; Rosenkranz, 1969a.)I wish to thank Prof. Dr. H. Stieve for the interest he took in this work through critical discussions and financial support. I also wish to thank Prof. A. Ruthmann, Ph. D., for introducing me to electron microscopy and for his linguistic aid. That Prof. Dr. K. Mühlethaler, ETH Zürich, and Prof. Dr. F. Schwanitz, KFA Jülich, put their freeze-etching apparatus and electron microscope at my disposal is gratefully acknowledged. The technical assistance of Miss M. Deichmann is also acknowledged.