Detection of cyclic GMP binding protein and ion channel activity in frog rod outer segments

In order to identify the cGMP-sensitive ion channel protein in frog rod outer segments (ROS), we analyzed cGMP binding proteins in the ROS by means of photoaffinity labeling with [3H]cGMP. We found four cGMP binding proteins with molecular weights (Mws) of 250K, 100K, 92K, and 53K. The 250K protein was an integral-membrane protein, which we named cG-Protein, (cG stands for cGMP). The cGMP-binding to cG-Protein was slightly increased by CaCl2. cG-Protein has a carbohydrate moiety. The amount of cG-Protein per single rod outer segment was estimated to be 9.0 x 10(6) molecules. Light-dependent phosphorylation of cG-Protein with [gamma-32P]ATP was observed. The 100K and 92K proteins were peripheral-membrane proteins, corresponding to cGMP phosphodiesterase. The 53K protein was a soluble protein. Incorporation of a membrane protein fraction of frog ROS into a planar lipid bilayer resulted in the appearance of at least three kinds of ion channel activities; two of them were related to cGMP. The possibility that cG-Protein is the cGMP-sensitive ion channel in vivo is discussed.     

Detection of Ca2+-dependent cyclic GMP binding protein in frog rod outer segments

For the identification of the cGMP-sensitive ion channel protein of frog rod outer segments (ROS), we analyzed cGMP binding proteins in the ROS by photoaffinity labeling with [3H]cGMP. We found three cGMP binding polypeptides (66 kDa, 92 kDa and 100 kDa) in the membrane protein fraction of ROS. cGMP binding to the 66 kDa polypeptide required the addition of 2 mM CaCl2. We propose that this polypeptide corresponds to the cGMP-activated channel protein reported by Cook et al. [(1987) Proc. Natl. Acad. Sci. USA 84, 585-589]. The 100 kDa and 92 kDa polypeptides are subunits of the cGMP phosphodiesterase.     

Regulation of cGMP levels by guanylate cyclase in truncated frog rod outer segments

Cyclic GMP is the second messenger in phototransduction and regulates the photoreceptor current. In the present work, we tried to understand the regulation mechanism of cytoplasmic cGMP levels in frog photoreceptors by measuring the photoreceptor current using a truncated rod outer segment (tROS) preparation. Since exogenously applied substance diffuses into tROS from the truncated end, we could examine the biochemical reactions relating to the cGMP metabolism by manipulating the cytoplasmic chemical condition. In tROS, exogenously applied GTP produced a dark current whose amplitude was half-maximal at approximately 0.4 mM GTP. The conductance for this current was suppressed by light in a fashion similar to when it is activated by cGMP. In addition, no current was produced in the absence of Mg2+, which is known to be necessary for the guanylate cyclase activity. These results indicate that guanylate cyclase was present in tROS and synthesized cGMP from exogenously applied GTP. The enzyme activity was distributed throughout the rod outer segment. The amount of synthesized cGMP increased as the cytoplasmic Ca2+ concentration of tROS decreased, which indicated the activation of guanylate cyclase at low Ca2+ concentrations. Half-maximal effect of Ca2+ was observed at approximately 100 nM. tROS contained the proteins involved in the phototransduction mechanism and therefore, we could examine the regulation of the light response waveform by Ca2+. At low Ca2+ concentrations, the time course of the light response was speeded up probably because cGMP recovery was facilitated by activation of the cyclase. Then, if the cytoplasmic Ca2+ concentration of a photoreceptor decreases during light stimulation, the Ca2+ decrease may explain the acceleration of the light response during light adaptation. In tROS, however, we did observe an acceleration during repetitive light flashes when the cytoplasmic Ca2+ concentration increased during the stimulation. This result suggests the presence of an additional light-dependent mechanism that is responsible for the acceleration of the light response during light adaptation.     

Cyclic nucleotide-dependent phosphorylation of proteins in rod outer segments in frog retina. Characteristics of the phosphorylated proteins and their dephosphorylation

To clarify the function of cyclic nucleotides in rod outer segments (ROS) of frog retinas, we studied cyclic nucleotide-dependent phosphorylation and dephosphorylation of protein. cGMP or cAMP with [gamma-32P]ATP in the dark enhanced the phosphorylation of two ROS proteins with Mr = 10,500 (Band 1) and 8,500 (Band 2) according to sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis. The phosphorylation was maximally enhanced at 2.0 mM cGMP and cAMP in the presence of Mg2+. The cGMP-activated protein kinase showed near-optimal activity between pH 6.5 and 8.0. GMP, GDP, GTP, AMP, and ADP did not enhance the phosphorylation. The stoichiometry of the phosphate incorporated into Bands 1 and 2 could not be calculated because the amount of Bands 1 and 2 was too small to measure. Both 32P-phosphorylated Bands 1 and 2 (32P-Bands 1 and 2) were solubilized during preparation and the molecular weight of each, in the native preparation, was 19,000. Their isoelectric point was 5.2. The sites of phosphorylation were the serine residue(s). DEAE-Sephadex A-50 column chromatography gave a good separation of Bands 1 and 2 from other 32P-phosphoproteins at 60 mM NaCl. Dephosphorylation of 32P-Bands 1 and 2 in dark-adapted ROS suspension required Mn2+ or Mg2+; the former was more effective than the latter at concentrations below 0.5 mM. Both phosphorylation and dephosphorylation were inhibited by Zn2+.     

The carbohydrates in frog retinal rod outer segments

Frog retinal rod outer segments appear to contain uncharacterized chemical components whose mass is roughly equivalent to 12--51% of the rhodopsin mass. Available data suggest that such components include soluble proteins and complex polysaccharides, and that hyaluronic acid accounts for a substantial fraction of this mass. Electron microscopic histochemical staining studies suggest that these polysaccharide components are located within the ROS disks. The oligosaccharide moieties of rhodopsin also appear localized within the disks. The interdisk cytoplasm may contain carbohydrates, but their quantity and identity are uncertain. Rhodopsin oligosaccharides as well as some fraction of the intradisk polysaccharide appear to have extended saccharide chains preferentially oriented perpendicular to the surface of the disk membrane. Possible roles for these polysaccharides in disk development and photoexcitation are discussed. The immediate need for complete rod outer segment chemical composition data is emphasized.     

Calcium content of frog rod outer segments and discs

To test the “Ca²⁺ hypothesis of visual excitation”, we measured the total Ca²⁺ content of freshly isolated bullforg rod outer segments, and have compared the total Ca²⁺ contents of fully dark-adapted discs with discs exposed to small amounts of light. Discs were prepared by hypotonically lysing outer segments under conditions expected to remove Ca²⁺ from the cytoplasm but not from the discs. Ca²⁺ was assayed by atomic absorption spectrophotometry. We find that both discs and outer segments contain a total of about 0.1–0.2 Ca²⁺ per rhodopsin molecule. Thus, each frog disc retains about $\text{2 · 10}{}^5\text{Ca}{}^{\mathrm{2+}}$. If most of this Ca²⁺ were free in the aqueous space inside the intact discs, the Ca²⁺ activity would be a few mM. Since the light-regulated Na⁺ channels have been reported to be highly sensitive to cytoplasmic Ca²⁺, this store of Ca²⁺ in the discs is far more than required by the Ca²⁺ hypothesis. However, despite several variations in experimental conditions, we did not observe any light-activated release of Ca²⁺ from discs in response to stimuli that photoactivated a small fraction of the rhodopsin, as required by the Ca²⁺ hypothesis. In the 26 experiments reported here we could have detected a release as small as 20–30% of the Ca²⁺ content of the disc.     

Rapid declines in cyclic GMP of rod outer segments of intact frog photoreceptors after illumination

Considerable disagreement has resulted from experiments designed to test whether light-induced falls in cGMP in outer segment (OS) of photoreceptors precede their light-induced electrical responses. Different studies have reported initial declines at 50 ms, at s, or not at all for physiological stimuli. Such studies have employed whole retinas, isolated rod OS, or isolated rod OS with attached inner segments and involved a variety of techniques. We developed an apparatus that illuminates intact pieces of dark-adapted frog retinas at 22 degrees C for known brief durations and then rapidly (47 ms) presses their OS surface against a copper mirror cooled by liquid helium. Freezing occurs in less than 2 ms. Cyclic GMP was then assayed in cryostat sections of the OS layer. Six illumination intensities that bleached from 90 to 9 X 10(8) rhodopsin molecules per s were delivered for durations of 0.1-2 s. Compared to dark-adapted values, progressive losses of cGMP were seen with all illumination intensities. Because a significant loss in cGMP was seen after a 100 ms exposure to our dimmest stimulus, it appears that a loss of cGMP could play a role in rod visual transduction.     

Phosphorylation of tyrosine aminotransferase in vitro by cyclic nucleotide-dependent protein kinases

An intraperitoneal injection of either leucine (1.57 mg/g body wt) or valine (2 mg/g body wt) into newborn mice led to a rapid accumulation of inactive monoribosomes in their brains. $\text{In}\text{vitro}$ measurements of protein synthesis by the remaining active ribosomes in leucine-treated mice revealed that polypeptide chain elongation was also inhibited. When a mixture of the seven amino acids from the leucine transport system was injected (0.15 mg each amino acid/g body wt) following the valine or leucine treatment, brain monoribosomes did not accumulate and elongation rates in the leucine-treated mice were only slightly altered.     

Inhibition of cyclic nucleotide phosphodiesterase from the rod outer segments of the frog retina by 3-hydroxypyridine

The influence of 8 analogues of 3-hydroxypyridine upon the phosphodiesterase of rod outer segments of frog retinae has been investigated. It has been shown that the analogues of 3-hydroxypyridine inhibit the enzeme reversely and noncompetitively in case of hydrolysis towards the cAMP and cGMP. The natural analogues of 3-hydroxypyridine (pyridoxol, pyridoxale, pyridoxale-phosphate) do not exert the inhibiting effect. It is suggested that the inhibition of phosphodiesterase from rod outer segments of retinae is caused by the interaction of 3-hydroxypyridines with the hydrophobic microenvironment of the active site of the enzyme.     

Protein complement of rod outer segments of frog retina

Rod outer segments (ROS) from frog retina have been purified by Percoll density gradient centrifugation, a procedure that preserves their form and intactness. One- and two-dimensional electrophoretic analysis reveals a smaller number of proteins than is observed in many cell organelles and permits quantitation of the 20 most abundant polypeptides. Rhodopsin accounts for 70% of the total protein (3 X 10(9) copies/outer segment), and approximately 70 other polypeptides are present at more than 6 X 10(4) copies/outer segment. Another 17% of the total protein is accounted for by the G-protein (3 X 10(8) copies/outer segment) that links rhodopsin bleaching and the activation of cyclic GMP phosphodiesterase (PDE). The phosphodiesterase accounts for 1.5% of the protein (1.5 X 10(7) copies/outer segment), and a 48,000-dalton component that binds to the membrane in the light accounts for a further 2.6%. The function of approximately 90% of the total protein in the outer segment is known, and two-thirds of the non-rhodopsin protein is accounted for by enzyme activities associated with cyclic GMP metabolism. The relative molar abundance of rhodopsin, G-protein, and PDE is 100:10:1. Apart from these major membrane-associated proteins, most of the other proteins are cytosolic. Thirteen other polypeptides are found at an abundance of one or more copies per 1000 rhodopsins, nine soluble and four membrane-bound, and their abundance relative to rhodopsin has been quantitated. ROS have been separated into subcellular fractions which resolve three classes of soluble, extrinsic membrane, and integral membrane proteins. A listing of the proteins that are phosphorylated and their subcellular localization is given. Approximately 25 phosphopeptides are detected, and most are in the soluble fraction. Fewer phosphorylated proteins are associated with the purified outer segments than with crude ROS. Distinct patterns of phosphorylation are associated with intact rods incubated with [32P]Pi and broken rods incubated with [gamma-32P]ATP.     

Phosphorylation of high mobility group 14 protein by cyclic nucleotide-dependent protein kinases

Chromosomal high mobility group (HMG) proteins have been examined as substrates for cGMP-dependent and cAMP-dependent protein kinases. Of the four HMG proteins only HMG 14 contained a major high affinity site which could be phosphorylated by both enzymes, preferentially by cGMP-dependent protein kinase. One mol of 32P was incorporated/mol of HMG 14. Kinetic analysis revealed apparent Km and Vmax of 40.5 microM and 14.7 mumol/min/mg, respectively, for cGMP-dependent protein kinase, and 123 microM and 11.1 mumol/min/mg, respectively, for cAMP-dependent protein kinase. Tryptic maps of 32P-labeled phosphopeptides of HMG 14 demonstrated phosphorylation of the same site by both enzymes. The tryptic fragment containing the major phosphorylation site was identified by amino acid composition and sequence as HMG 14 (residues 4-13): H-Lys-Val-Ser(P)-Ser-Ala-Glu-Gly-Ala-Ala-Lys-OH. HMG 14 and HMG 17 also contained minor sites which could be phosphorylated by cGMP-dependent protein kinase. Tryptic phosphopeptides mapping suggested that the same minor site was phosphorylated on both HMG 14 and 17. On the basis of amino acid composition, the tryptic peptides carrying the minor phosphorylation sites were identified as H-Leu-Ser(P)-Ala-Lys representing residues 23-26 and 27-30 of HMG 14 and HMG 17, respectively.     

A monoclonal antibody to guanine nucleotide binding protein inhibits the light-activated cyclic GMP pathway in frog rod outer segments

A monoclonal antibody that blocks the light-activated cyclic GMP (cGMP) pathway in frog photoreceptor outer segments (ROS) has been obtained. The antibody (4A) inhibits guanine nucleotide binding to G-protein, the intermediate that links rhodopsin excitation to cGMP phosphodiesterase (PDE), inhibiting light-induced PDE activity as a consequence. Antibody inhibition of the light-activated cGMP pathway is complete at a stoichiometry of approximately one antibody per G-protein in the mixture, which indicates high specificity of the inhibition. Inhibition is more pronounced than that caused by PDE inhibitors such as isobutylmethylxanthine (IBMX) or Ro 20-1724. Antibody 4A has the further effect of inhibiting the phosphorylation of two low molecular weight proteins, components I and II, whose phosphorylation normally can be stimulated by raising cGMP levels. The inhibition is not overridden by adding cGMP, which suggests that the G-protein influences these phosphorylations by a pathway distinct from its action on cGMP concentration. Antibody 4A may prove useful as a probe of the relevance of the cGMP pathway to visual transduction in living photoreceptors. Six other monoclonal antibodies to G-protein, as well as six monoclonal antibodies to rhodopsin and one to PDE, do not block light-activated guanine nucleotide binding, PDE activity, or ROS protein phosphorylations.     

Superoxide dismutase of bovine and frog rod outer segments.

Bovine rod outer segments (ROS) contain soluble superoxide dismutase (SOD) which from cyanide sensitivity and electrophoretic mobility appears identical to CuZn SOD of erythrocytes. Enzyme activity of ROS extracts is 200–400 times as much as remainder of retina. Frog ROS also contains a cyanide-sensitive SOD which is not due to erythrocyte contamination since the retina is avascular. SOD in ROS may inhibit free radical oxidation of polyunsaturated fatty acids. In light, high oxygen concentrations in developing retina may activate lipid peroxidation leading to retrolental fibroplasia. High concentrations of ascorbic acid in the retina may act as a protective mechanism against superoxide.     

Influence of light and calcium on guanosine 5'-triphosphate in isolated frog rod outer segments.

Frog rod outer segments contain approximately 0.25 mol of GTP and 0.25 mol of ATP per mol of rhodopsin 3 min after their isolation from the retina. UTP and CTP are present at 10-fold and 100-fold lower levels, respectively. Concentrations of GTP and ATP decline in parallel over the next 4 min to reach relatively stable levels of 0.1 mol per mol of rhodopsin. Illumination reduces the concentration of endogenous GTP but not ATP. This light-induced decrease in GTP can be as large as 70% and has a half-time of 7 s. GTP is reduced to steady intermediate levels during extended illumination of intermediate intensity, but partially returns to its dark-adapted level after brief illumination. The magnitude of the decrease increases as a linear function of the logarithm of continuous light intensity at levels which bleach between 5 X 10(2) and 5 X 10(6) rhodopsin molecules/outer segment per second. This exceeds the range of intensities over which illumination causes decreases in the cyclic GMP content and permeability of isolated outer segments (Woodruff and Bownds. 1979. J. Gen. Physiol. 73:629-653). Thus, over 4 log units of light intensity, a sensitivity control mechanism functions to make extended illumination less effective in stimulating a GTP decrease. GTP levels in dark-adapted outer segments are sensitive to changes in calcium concentration in the suspending medium. If the external calcium concentration is reduced to 10(-8) M, GTP concentration is lowered to the same level caused by saturating illumination, and the GTP remaining is no longer light-sensitive. Lowering calcium concentration to intermediate levels between 10(-6) and 10(-8) M reduces GTP to stable intermediate levels, and the GTP remaining can be reduced by light. Restoration of millimolar calcium drives synthesis of GTP, but not of ATP, and GTP lability towards illumination is again observed. These calcium-induced changes in GTP are diminished by the addition of the divalent cation ionophore A23187. Lowering or raising magnesium levels does not influence the GTP concentration. These data raise the possibility that light activates either a calcium transport mechanism driven by the hydrolysis of GTP, or some other calcium-sensitive GTPase activity of unknown function. Known light-dependent reactions involving cyclic nucleotide transformations and rhodopsin phosphorylation appear to account for only a small fraction of the light-induced GTP decrease.     

Light-induced dephosphorylation of two proteins in frog rod outer segments: influence of cyclic nucleotides and calcium

Two minor proteins of frog rod outer segments become phosphorylated when retinas are incubated in the dark with 32Pi. The proteins, designated component I (13,000 daltons) and component II (12,000 daltons), are dephosphorylated when retinas are illuminated. The dephosphorylation is reversible; the two proteins are rephosphorylated when illumination ceases. Each outer segment contains approximately 10(6( molecules of components I and II. These remain associated with both fragmented and intact outer segments but dissociate from the outer segment membranes under hypoosmotic conditions. The extent of the light-induced dephosphorylation increases with higher intensities of illumination and is maximal with continuous illumination which bleaches 5.0 x 10(5) rhodopsin molecules/outer segment per second. Light which bleaches 5.0 x 10(3) rhodopsin molecules/outer segment per second causes approximately half-maximal dephosphorylation. This same intermediate level of illumination causes half-suppression of the light-sensitive permeability mechanism in isolated outer segments (Brodie and Bownds. 1976. J. Gen Physiol. 68:1-11) and also induces a half-maximal decrease in their cyclic GMP content (Woodruff et al. 1977. J. Gen. Physiol. 69:667-679). The phosphorylation of components I and II is enhanced by the addition of cyclic GMP or cyclic AMP to either retinas or isolated rod outer segments maintained in the dark. Several pharmacological agents which influence cyclic GMP levels in outer segments, including calcium, cause similar effects on the phosphorylation of components I and II and outer segment permeability. Although the cyclic nucleotide-stimulated phosphorylation can be observed either in retinas or isolated rod outer segments, the light-induced dephosphorylation is observed only in intact retinas.     

Protein kinases of retinal rod outer segments: identification and partial characterization of cyclic nucleotide dependent protein kinase and rhodopsin kinase

Protein kinase activity of dark-adapted bovine rod outer segments is partitioned by centrifugation into soluble and membrane-bound fractions. The soluble kinases are separated by DEAE-cellulose chromatography into three peaks of activity, which can be classified by substrate specificity and cyclic nucleotide dependence into two categories. One peak of protein kinase activity has the characteristics reported for rhodopsin kinase (category one); it phosphorylates only bleached rhodopsin, and its activity is not affected by light, exogenous adenosine cyclic 3',5'--monophosphate (cAMP), guanosine cyclic 3',5'-monophosphate (cGMP), or a protein kinase inhibitor from skeletal muscle. Rhodopsin kinase has an apparent molecular weight of 68 000. The second category of kinase includes two peaks of activity which are stimulated severalfold by cAMP or cGMP but not by light. These protein kinases phosphorylate soluble proteins including histones and a protein kinase substrate prepared from rat intestine but not rhodopsin. The two peaks elute from DEAE-cellulose with 0.09 and 0.20 M KCl, suggesting that they are similar respectively to type I and type II cyclic nucleotide dependent protein kinases that have been characterized in other tissues. The activity of type I kinase is variable and much less than that of the type II enzyme; its molecular weight was not determined. The type II protein kinase has an apparent molecular weight of 165 000. This study confirms that different protein kinase enzymes catalyze selectively the phosphorylation of bleached rhodopsin and soluble proteins, and it repudiates the speculation in a previous publication [Farber, D. B., Brown, B. M., & Lolley, R. N. (1979) Biochemistry 18, 370-378] that a single protein kinase might catalyze both phosphorylation reactions.     

Effect of light and calcium on cyclic GMP synthesis in rod outer segments of toad retina

The rod outer segments of toad retina contain a guanylate cyclase activity of about 3 +/- 1 nmol of cGMP formed/min per mg protein. In darkness this value is largely independent of the Ca2+ concentration, although it is enhanced by light upon lowering the Ca2+ concentration from 10(-5) to 10(-8) M. The activating effect of light on cyclase at low Ca2+ concentrations is enlarged upon increasing the light intensity. With a flash of light bleaching 7 X 10(-2) percent of rhodopsin, cyclase activity increased by a factor of 30 when Ca2+ levels dropped from 10(-5) to 10(-8) M. In view of recent observations that shortly after a flash of light the calcium activity inside the photoreceptor cell decreases, it seems likely that Ca2+ plays a regulatory role on cGMP metabolism in visual excitation.     

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.     

Guanosine triphosphate complex in rod outer segments of the frog retina

It is shown that nearly 70% water--soluble protein of the frog retina outer segments (ROS) consist of three polypeptides with molecular weights 39 000, 36 000 and less than 15 000 daltons. These proteins are present in equal proportions and are, apparently, the subunits of a tightly bound protein complex. The subunit of 39 000 daltons is responsible for guanyl nucleotides binding. Parameters of the investigated GTP-binding complex are similar to transducyn which transmits excitation from bleached rhodopsin to PDE molecules in the bovine retina ROS. The thermodynamic state of GTP-binding protein in frog retina ROS depends on the functional state of the photoreceptor membrane, as shown by microcalorimetric method.