Rhodopsin kinase prepared from bovine rod disk membranes quenches light activation of cGMP phosphodiesterase in a reconstituted system

Rhodopsin kinase was extracted into a buffer containing 200 mM KCl and no MgCl2. The activity of the enzyme was stabilized with the use of a mixture of protease inhibitors, aprotinin, benzamidine, leupeptin, and pepstatin. The extract consisted of three major proteins of molecular weight (Mr) 65,000, 56,000, and 37,000, of which the Mr 65,000 protein was identified with the kinase activity since preparations containing the other proteins had no kinase activity and the Mr 65,000 protein was phosphorylated when the extract was incubated with ATP. A reconstituted cGMP phosphodiesterase (PDE) system consisting of peripheral protein-depleted rod disk membranes (RDM), GTP binding protein (G-protein), and PDE was used to test the effectiveness of the rhodopsin kinase preparation in mediating the ATP-dependent quench of light activation of PDE. In the absence of kinase, light-activated PDE activity lasted several minutes. In its presence, ATP and to a lesser extent GTP quenched the activation about as rapidly as in rod disk membranes. The influence of kinase was unaffected by increasing G-protein or PDE content of the reconstituted system but was slowed down by brighter flashes, showing that quench was caused by the inactivation of bleached rhodopsin and not of PDE or G-protein.     

Purification and characteristics of photoreceptor light-activated guanosinetriphosphatase

We describe a reconstitution of light-activated vertebrate photoreceptor GTPase and a purification of the GTP-binding protein (G protein), which is a component of the GTPase and modulates the light-activated phosphodiesterase (PDE) enzyme system. Rod outer segments (ROS) of bull frogs were treated with ethylenediaminetetraacetic acid (EDTA), and the GTPase and PDE fractions were solubilized (EDTA supernatant). When the EDTA supernatant and EDTA-treated membrane fraction (EDTA-washed membranes) were recombined, light-dependent GTPase activity appeared. In the reconstituted system, the Km for GTP as substrate was 0.5 microM; the optimum pH was 7.5-8.0. The isoelectric point of GTPase in EDTA supernatant was 4.8. G protein was purified 400-fold from ROS, and the molecular weight of G protein was determined to be 40 000 by polyacrylamide gel electrophoresis. The amount of G protein in ROS was calculated as at least 1 molecule per 400 rhodopsin molecules. By recombining (in the presence or absence of GTP) purified G protein, PDE, H fraction (an additional component of GTPase), and illuminated or unilluminated EDTA-washed membranes (as a source of rhodopsin), we showed that illuminated rhodopsin, G protein, PDE, and GTP are the minimum requirements for light-dependent PDE activity. We discuss the significance of these findings in the regulation of the light-activated GTPase and PDE activities, especially with regard to the mechanism of activation.     

Kinetic studies suggest that light-activated cyclic GMP phosphodiesterase is a complex with G-protein subunits

Cyclic GMP phosphodiesterase (PDE) in rod disk membranes has three subunits of molecular weight 88 000 (alpha), 84 000 (beta), and 13 000 (gamma). Physiological activation of the enzyme by light is mediated by a GTP binding protein (G protein). The enzyme can also be activated by controlled digestion with trypsin, which destroys the gamma subunit, leaving the activated enzyme as PDE alpha beta [Hurley, J. B., & Stryer, L. (1982) J. Biol. Chem. 257, 11094-11099]. Addition of purified gamma subunit to PDE alpha beta inhibited the enzyme fully. This suggested the possibility that G protein could also activate PDE by removing the gamma subunit and leaving the active enzyme in the form of PDE alpha beta. Should this be true, the properties of light- and trypsin-activated enzymes should be comparable. We found this not to be the case. The Km of light-activated enzyme for cyclic GMP was about 0.9-1.4 mM while that of trypsin-activated enzyme was about 140 microM. The cyclic AMP Km was also different for the two enzymes: 6.7 mM for light-activated enzyme and 2.0 mM for trypsin-activated enzyme. The inhibition of both enzymes by the addition of purified gamma subunit also differed significantly. Trypsin-activated enzyme was fully inhibited by the addition of about 200 nM gamma, but light-activated enzyme could not be fully inhibited even with 2600 nM inhibitor subunit. The Ki of the trypsin-activated enzyme for gamma was 15 nM and of the light-activated enzyme 440 nM.(ABSTRACT TRUNCATED AT 250 WORDS)     

Contribution of the guanosinetriphosphatase activity of G-protein to termination of light-activated guanosine cyclic 3',5'-phosphate hydrolysis in retinal rod outer segments

Light activation of GTP binding to G-protein and its eventual hydrolysis are hypothesized to lead to activation and inactivation of cGMP phosphodiesterase (PDE) in vertebrate rod disk membranes (RDM). However, the reported GTPase rate of 3 per minute is too slow to account for the observed rapid inactivation of PDE. Our investigations on GTPase activity showed that RDM isolated in the dark have considerable dark GTPase activity, which is enhanced by light. In dark and light, the enzyme exhibits biphasic substrate dependence with two Km's for GTP of 2-3 and 40-80 microM at 22 degrees C and less than 1 and 10-25 microM at 37 degrees C. The Km's were not influenced by light. On the basis of G-protein content of the RDM, the Vmax's for the two activities at 37 degrees C in light are 4-5 and 20-30 GTPs hydrolyzed per minute per G-protein. RDM washed free of soluble and peripheral proteins do not have measurable GTPase activity in the dark or light. Purified G-protein alone also did not turn over GTP, apparently because bleached rhodopsin is required for it to bind GTP. Reconstitution of washed membranes with purified G-protein restores both the low- and high-Km GTPase activities. Inactivation of G-protein as measured by PDE turnoff and dissociation signal recovery is found to be faster at higher than lower [GTP], consistent with the observation that the higher GTPase activity associated with the higher Km alos resides in the G-protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Stimulation of rhodopsin phosphorylation by guanine nucleotides in rod outer segments

Porcine rod outer segment (ROS) proteins were phosphorylated in the presence of [gamma-32P]ATP and Mg2+, separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and detected by autoradiography. The phosphorylation of rhodopsin, the major protein-staining band (Mr approximately 34 000-38 000), was markedly and specifically increased by exposure of rod outer segments to light; various guanine nucleotides (10 microM) including GMP, GDP, and GTP also specifically increased rhodopsin phosphorylation (up to 5-fold). Adenine nucleotides (cyclic AMP, AMP, and ADP at 10 microM) and 8-bromo-GMP (10 microM) or cyclic 8-bromo-GMP (10 microM) had no detectable stimulatory effect on rhodopsin phosphorylation. GTP increased the phosphorylation of rhodopsin at concentrations as low as 100 nM, and guanosine 5'-(beta, gamma-imidotriphosphate), a relatively stable analogue of GTP, was nearly as effective as GTP. Maximal stimulation of rhodopsin phosphorylation by GTP was observed at 2 microM. GMP and GDP were less potent than GTP. Both cyclic GMP and GMP were converted to GTP during the time period of the protein phosphorylation reaction, suggestive of a GTP-specific effect. Transphosphorylation of guanine nucleotides by [32P]ATP and subsequent utilization of [32P]GTP as a more effective substrate were ruled out as an explanation for the guanine nucleotide stimulation. With increasing concentrations of ROS proteins, the phosphorylation of rhodopsin was nonlinear, whereas in the presence of GTP (2 microM) linear increases in rhodopsin phosphorylation as a function of added ROS protein were observed. These results suggest that GTP stimulates the phosphorylation of rhodopsin by ATP and that a GTP-sensitive inhibitor (or regulator) of rhodopsin phosphorylation may be present in ROS.     

Light-regulated biochemical events in invertebrate photoreceptors. 1. Light-activated guanosinetriphosphatase, guanine nucleotide binding, and cholera toxin catalyzed labeling of squid photoreceptor membranes

The occurrence of a guanine nucleotide binding protein activated by squid rhodopsin was established by examination of GTPase activity, guanine nucleotide binding, and cholera toxin catalyzed labeling of squid photoreceptor membranes. Purified squid (Loligo opalescens) photoreceptors exhibited GTPase activity that increased 3-4-fold by illumination. Half-maximal GTPase activity was observed when 2% of the rhodopsin was photoconverted to metarhodopsin. The Km of the light-regulated activity was 1 microM GTP. Binding of the hydrolysis-resistant GTP analogue guanosine 5'-(beta, gamma-imidotriphosphate) [Gpp(NH)p] was enhanced greater than 10 times by illumination. A protein, Mr 44 000, was identified as a component of the light-activated guanine nucleotide binding protein/GTPase through its specific labeling with [32P]NAD catalyzed by cholera toxin: light increased the extent of 32P incorporation 7-fold. The addition of ATP to the membrane suspension enhanced labeling, while guanine nucleotides inhibited labeling with the relative potency GTP gamma S much greater than GDP greater than GTP greater than Gpp(NH)p. The 44 000-dalton protein was membrane bound irrespective of variations in ionic strength and divalent ion concentration over a wide range. These results suggest that a G protein, which incorporates both GTP binding and hydrolysis functions, is intimately involved in the visual process of invertebrate photoreceptors.     

Control of the cyclic GMP phosphodiesterase of frog photoreceptor membranes

The light-activated cyclic GMP phosphodiesterase (PDE) of frog photoreceptor membranes has been assayed in isolated outer segments suspended in a low-calcium Ringer's solution. Activation occurs over a range of light intensity that also causes a decrease in the permeability, cyclic GMP levels, and GTP levels of isolated outer segments. At intermediate intensities, PDE activity assumes constant intermediate values determined by the rate of rhodopsin bleaching. Washing causes an increase in maximal enzyme activity. Increasing light intensity from darkness to a level bleaching 5 x 10(3) rhodopsin molecules per outer segment per second shifts the apparent Michaelis constant (Km) from 100 to 900 microM. Maximum enzyme velocity increases at least 10-fold. The component that normally regulates this light- induced increase in the Km of PDE is removed by the customary sucrose flotation procedures. The presence of 10(-3) M Ca++ increases the light sensitivity of PDE, and maximal activation is caused by illumination bleaching only 5 x 10(2) rhodopsin molecules per outer segment per second. Calcium acts by increasing enzyme velocity while having little influence on Km. The effect of calcium appears to require a labile component, sensitive to aging of the outer segment preparation. The decrease in the light sensitivity of PDE that can be observed upon lowering the calcium concentration may be related to the desensitization of the permeability change mechanism that occurs during light adaptation of rod photoreceptors.     

Membrane stimulation of cGMP phosphodiesterase activation by transducin: comparison of phospholipid bilayers to rod outer segment membranes.

To clarify the role of phospholipids in G protein-effector interactions of vertebrate phototransduction, transducin activation of cGMP phosphodiesterase (PDE) has been reconstituted on the surface of well-defined phosphatidylcholine (PC) vesicles, using purified proteins from bovine rod outer segments (ROS). PC vesicles enhanced PDE stimulation by the GTP-gamma S-bound transducin alpha subunit (T alpha-GTP gamma S) as much as 17-fold over activation in the absence of membranes. In the presence of 3.5 microM accessible PC in the form of large (100 nm) unilamellar vesicles, 500 nM T alpha-GTP gamma S stimulated PDE activity to more than 70% of the maximum activity induced by trypsin. Activation required PC, PDE, and T alpha-GTP gamma S, but did not require prior incubation of any of the components, and occurred within 4 s of mixing. The PC vesicles were somewhat more efficient than urea-washed ROS membranes in enhancing PDE activation. Half-maximal activation occurred at accessible phospholipid concentrations of 3.8 microM for PC vesicles, and 13 microM for ROS membranes. Titrations of PDE with T alpha-GTP gamma S in the presence of membranes indicated a high-affinity (Kact less than 250 pM) activation of PDE by a small fraction (0.5-5%) of active T alpha-GTP gamma S, as did titrations of ROS with GTP gamma S. When activation by PC vesicles was compared to PDE binding to membranes, the results were consistent with activation enhancement resulting from formation of a T alpha-GTP gamma S-dependent PDE-membrane complex with half-maximal binding at phospholipid concentrations in the micromolar range. The value of the apparent dissociation constant, KPL, associated with the activation enhancement was estimated to be in the range of 2.5 nM (assuming an upper limit value of 1600 phospholipids/site) to 80 nM (for a lower limit value of 50 phospholipids/site). Another component of membrane binding was more than 100-fold weaker and was not correlated with activation by T alpha-GTP gamma S. Low ionic strength disrupted the ability of ROS membranes, but not PC vesicles, to bind and activate PDE. Removal of PDE's membrane-binding domain by limited trypsin digestion eliminated both the binding of PDE to vesicles and the ability of PDE to be activated by T alpha-GTP gamma S and membranes. These results suggest that ROS membrane stimulation of PDE activation by T alpha-GTP gamma S is due almost exclusively to the phospholipids in the disk membrane.     

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.     

Sites of arrestin action during the quench phenomenon in retinal rods

The target proteins for arrestin (48 kDa protein) action during the quench of cGMP phosphodiesterase (PDE) activation in retinal rod disk membranes were identified by the use of a cross-linking reagent. A heterobifunctional, cleavable, photo-activatable cross-linker (sulfo-SADP) was coupled to purified arrestin. Under precise weak visible light bleach and nucleotide conditions of quench, the cross-linker was UV flash-activated at a time when quench was well established. The target proteins covalently linked to arrestin by cross-linker activation were identified by immunoblotting. In the presence of ATP arrestin cross-linked to both PDE and rhodopsin during the quench phenomenon. Removal of ATP from the reaction mixture essentially abolished the cross-link with PDE, just as ATP omission abolishes quench, but significantly increased the cross-link to rhodopsin. The absence of a cross-link to the plentiful beta-subunit of transductin, as well as the results of competition studies employing arrestin without attached cross-linker, suggest that the observed cross-links are specific and reflect true binding interactions of arrestin during quench. The data are consistent with a model of quench in which photolyzed rhodopsin (R*) catalyzes the formation of an activated form of arrestin, which dissociates from R* in the presence of ATP, and binds to PDEs, thereby deactivating them.     

Amplification of phosphodiesterase activation is greatly reduced by rhodopsin phosphorylation

In the vertebrate rod outer segment (ROS), the light-dependent activation of a GTP-binding protein (G-protein) and phosphodiesterase (PDE) is quenched by a process that requires ATP [Liebman, P.A., & Pugh, E.N. (1979) Vision Res. 19, 375-380]. The ATP-dependent quenching mechanism apparently requires the phosphorylation of photoactivated rhodopsin (Rho*); however, a 48-kilodalton protein (48K protein) has also been proposed to participate in the inactivation process. Purified species of phosphorylated rhodopsin containing 0, 2, or greater than or equal to 4 (high) phosphates per rhodopsin (PO4/Rho) were reconstituted into phosphatidylcholine (PC) vesicles and reassociated with a hypotonic extract from isotonically washed disk membranes that were depleted of 48K protein; PDE activation, in response to bleaching from 0.01% to 15% of the rhodopsin present, was measured. PDE activity was reduced by at least 30% at high fractional rhodopsin bleaches and by greater than 80% at low fractional rhodopsin bleaches in high PO4/Rho samples when compared to the activity measured in O PO4/Rho controls. A phosphorylation level of 2 PO4/Rho produced PDE activities that were intermediate between O PO4/Rho and high PO4/Rho samples at low bleaches, but were identical with the O PO4/Rho samples at high rhodopsin bleaches. Rhodopsin phosphorylation is thus capable of producing a graded inhibition of light-stimulated PDE activation over a limited range of (near physiological) bleach levels. This effect become less pronounced as the bleach levels approach those that saturate PDE activation. These results are consistent with increasing levels of phosphorylation, producing a reduction of the binding affinity of G-protein for Rho*.     

Transducin activation in electropermeabilized frog rod outer segments is highly amplified, and a portion equivalent to phosphodiesterase remains membrane-bound

An electropermeabilized preparation of frog retinal rod outer segments (ROS) has been developed to examine the light sensitivity and amplification of visual transduction reactions in a minimally disturbed environment. Electropermeabilized ROS are indistinguishable from whole and osmotically intact ROS in the light microscope and retain 3-fold more protein than mechanically disrupted ROS. They differ from mechanically fragmented ROS in several respects. Illumination results in more amplified activation of the GTP-binding protein transducin (Gt) than previously observed: bleaching as little as approximately 1 rhodopsin molecule (Rho*) in every 10 disks within a single ROS activates 37,000 molecules of Gt per Rho*, equivalent to 70% of the light-activatable Gt present on a single disk face. This amplification is maintained over approximately 1 decade of light intensity but drops sharply as disk faces begin to absorb a second photon. Lower amplification is observed in fragmented ROS and derives from the fact that physical disruption of ROS causes Gt to bind GTP and elute from the membrane, thus decreasing the amount remaining and available for light activation. Illumination of electropermeabilized ROS in the presence of GTP or of the nonhydrolyzable substrate guanosine 5'-(gamma-thio)triphosphate (GTP gamma S) causes redistribution of Gt: an amount (approximately 20 mmol/mol Rho) equivalent to the amount of inhibitory gamma subunit of phosphodiesterase (PDE) remains internal and bound to nucleotide, and the remaining activated Gt diffuses out in a manner graded with light intensity. This suggests that PDE activation by Gt alpha may not require dissociation of Gt alpha bound to the gamma subunit of PDE in a form than can elute from ROS. Two further differences between electropermeabilized and mechanically disrupted ROS are noted: the addition of ATP to electropermeabilized ROS does not affect the light sensitivity or kinetics of the GTP binding reaction, and a specificity for light-induced GTP versus GDP binding is observed.     

Guanine nucleotide binding characteristics of transducin: essential role of rhodopsin for rapid exchange of guanine nucleotides

Transducin (Gt) is a member of a family of receptor-coupled signal-transducing guanine nucleotide (GN) binding proteins (G-proteins). Light-activated rhodopsin is known to catalyze GN exchange on Gt, resulting in the formation of the active state of the Gt alpha-GTP complex. However, purified preparations of Gt have been shown to exchange GN in the absence of activated receptors [Wessling-Resnick, M., & Johnson, G. L. (1987) Biochemistry 26, 4316-4323]. To evaluate the role of rhodopsin in the activation of Gt, we studied GN-binding characteristics of different preparations of Gt. Gt preparations obtained rom the supernate of GTP-treated bovine rod outer segment (ROS) disks, followed by removal of free GTP on a Sephadex G-25 column, bound GTP gamma S at 30 degrees C in the absence of added exogenous rhodopsin with an activity of 1 mol of GTP gamma S bound/mol of Gt (Gt-I preparations). Binding of GTP gamma S to Gt-I preparations closely correlated with the activation of ROS disk cGMP phosphodiesterase. GN-binding activity of Gt-I preparations was dependent on reaction temperature, and no binding was observed at 4 degrees C. In the presence of 10 microM bleached rhodopsin, Gt-I preparations bound GTP gamma S at 4 degrees C. However, hexylagarose chromatography of Gt-I preparations led to a preparation of Gt that showed less than 0.1 mol/mol binding activity following 60-min incubation at 30 degrees C in the absence of rhodopsin (Gt-II preparations).(ABSTRACT TRUNCATED AT 250 WORDS)     

Light- and nucleotide-dependent binding of phosphodiesterase to rod disk membranes: correlation with light-scattering changes and vesicle aggregation

Under conditions in which large guanosine cyclic 3',5'-phosphate (cGMP)- and phosphodiesterase (PDE)-dependent changes in near-infrared transmission and vesicle aggregation and disaggregation occur, we have observed a striking change in the binding of PDE to rod disk membranes. The change in PDE binding is nucleotide and light dependent as are the light-scattering changes. The cGMP- and PDE-dependent light-scattering signal can be produced by a 500-nm light flash which bleaches 1/(1 X 10(7] rhodopsin molecules. Mg ions are an essential cofactor for the nucleotide-dependent PDE binding and light-scattering changes. 3-Isobutyl-1-methylxanthine and other competitive inhibitors of PDE hydrolytic activity support increased PDE binding to the disk membrane, vesicle aggregation, and the light-scattering signal. However, treatments which block GTP-dependent activation of PDE hydrolytic activity (colchicine, GDP, or ethylenediaminetetraacetic acid) also block these phenomena. Thus, GTP-dependent activation of PDE rather than its hydrolytic activity appears to be correlated with the light-scattering signal.     

cGMP suppresses GTPase activity of a portion of transducin equimolar to phosphodiesterase in frog rod outer segments. Light-induced cGMP decreases as a putative feedback mechanism of the photoresponse.

In rod photoreceptor cells, the light response is triggered by an enzymatic cascade that causes cGMP levels to fall: excited rhodopsin (Rho*)----rod G-protein (transducin, Gt)----cGMP-phosphodiesterase (PDE). This results in the closure of plasma membrane channels that are gated by cGMP. PDE activation by Gt occurs when GDP bound to the alpha-subunit of Gt (Gt alpha) is exchanged with free GTP. The interaction of Gt alpha-GTP with the gamma-subunits of PDE releases their inhibitory action and causes cGMP hydrolysis. Inactivation is thought to be caused by subsequent hydrolysis of Gt alpha-GTP by an intrinsic Gt-GTPase activity. Here we report that there are two portions of Gt in frog rod outer segments (ROS) expressing different rates of GTP hydrolysis: 19.5 +/- 3 mmol of Gt/mol of Rho, equivalent to that amount which participates in PDE activation, hydrolyzing GTP at a rate of approximately 0.6 turnover/s ("fast") and the remaining Gt (80.5 +/- 3 mmol/mol Rho) hydrolyzing GTP at a rate of 0.058 +/- 0.009 turnover/s. Fast GTPase activity is abolished in the presence of cGMP. This effect occurs over the physiological range of cGMP concentration changes in ROS, half-saturating at approximately 2 microM and saturating at 5 microM cGMP. cGMP-dependent suppression of GTPase is specific for cGMP; cAMP in millimolar concentration does not affect GTPase, while the poorly hydrolyzable cGMP analogue, 8-bromo-cGMP, mimics the effect. GTPase regulation by cGMP is not affected by Ca2+ over the concentration range 5-500 nM, which spans the physiological changes in cytoplasmic Ca2+ in rod cells. We suggest that the fast cGMP-sensitive GTPase activity is a property of the Gt that activates PDE. In this model, cGMP serves not only as a messenger of excitation but also modulates GTPase activity, thereby mediating negative feedback regulation of the pathway via PDE turnoff: a light-dependent decrease in cGMP accelerates the hydrolysis of GTP bound to Gt, resulting in the rapid inactivation of PDE.     

Effect of GDP on transducin interaction with cyclic nucleotide phosphodiesterase and rhodopsin from bovine retinal rods

In the presence of guanyl nucleotides and rhodopsin-containing retinal rod outer segment membranes, transducin stimulates the light-sensitive cyclic nucleotide phosphodiesterase 5.5-7 times. The activation constant (Ka) for GTP and Gpp(NH)p is 0.25 microM, that for GDP and GDP beta S is 14 and 110 microM, respectively. GDP purified from other nucleotide contaminations at concentrations up to 1 mM does not stimulate phosphodiesterase but binds to transducin and inhibits the Gpp(NH)p-dependent activation of phosphodiesterase. The mode of transducin interaction with bleached rhodopsin also depends on the nature of the bound guanyl nucleotide: in the presence of GDP rhodopsin-containing membranes bind 70-100% of transducin, whereas in the presence of Gpp(NH)p the membranes bind only 13% of the protein. The experimental results suggest that GDP and GTP convert transducin into two different functional states, i.e., the transducin X GTP complex binds to phosphodiesterase causing its stimulation, while the transducin X GDP complex is predominantly bound to rhodopsin.     

Interactions of nucleotide analogues with rod outer segment guanylate cyclase.

Light activation of cyclic GMP hydrolysis in rod outer segments is mediated by a G-protein which is active in the GTP-bound form. Substitution of GTP with a nonhydrolyzable GTP analogue is thought to leave the G-protein in a persistently activated state, thereby prolonging the hydrolysis of cyclic GMP. Restoration of cyclic GMP concentration in the cell also depends upon GTP since it is the substrate for guanylate cyclase, but little is known about the effects of GTP analogues on this enzyme. We report here the effects of the analogues of GTP and ATP as inhibitors and substrates of rod disk membrane guanylate cyclase. The rate of cyclic GMP synthesis from GTP in rod disk membranes was about 50 pmol min-1 (nmol of rhodopsin)-1. Analogues of GTP and adenine nucleotides competitively inhibited the cyclase activity. The order of inhibition, with magnesium as metal cofactor, was ATP greater than GMP-PNP greater than AMP-PNP approximately GTP-gamma-S; with manganese, AMP-PNP was more inhibitory than GTP-gamma-S. The inhibition constants, with magnesium as cofactor, were 0.65-2.0 mM for GTP-gamma-S, 0.4-0.8 mM for GMP-PNP, 1.5-2.3 mM for AMP-PNP, and 0.07-0.2 mM for ATP. The fraction of cyclase activity inhibited by analogues was similar at 1 and 0.03 microM calcium. Besides inhibition of cyclase, the analogues also served as its substrates. GTP-gamma-S substituted GTP with about 85% efficiency while GMP-PNP and ATP were about 5 and 7% as efficient, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Inhibitors of phosphodiesterase III block stimulation of Xenopus laevis oocyte ribosomal S6 kinase activity by insulin-like growth factor-I.

Insulin-like growth factor-I (IGF-I) stimulated Xenopus laevis oocyte ribosomal S6 kinase activity 5- to 10-fold, with an apparent EC50 of 0.8 +/- 0.1 nM after 90 min of hormone treatment. IGF-I-stimulated enzyme activity was inhibited by treatment of oocytes with nonselective phosphodiesterase (PDE) inhibitors, with apparent IC50 values of 2 +/- 1 microM papaverine, 20 +/- 2 microM isobutylmethylxanthine, and 128 +/- 16 microM theophylline. Type III PDE inhibitors also inhibited IGF-I-stimulated S6 kinase activity with IC50 values of 9.7 +/- 0.3 microM Cl-930 and 84 +/- 23 microM imazodan (Cl-914). These drugs apparently affected an intracellular molecular event leading to activation of S6 kinase, since Cl-930 prevented IGF-I-stimulation of S6 kinase, but had no direct inhibitory effect when added to the S6 kinase enzyme assay mixture. While hormone-stimulated S6 kinase activity was inhibited by isobutylmethylxanthine (nonselective PDE inhibitor) and Cl-930 (PDE III inhibitor), Ro 20, 1724 and rolipram (PDE IV inhibitors) and dipyridamole (PDE V inhibitor) had no significant effect on activated enzyme levels. The time course for IGF-I stimulation of oocyte S6 kinase displayed a small early peak of activity approximately 0.15-0.4 time required for 50% of cell population to display white spots (GVBD50) and a second major increase in activity at 0.6-0.7 GVBD50 that was sustained until meiotic maturation was complete. The second wave of enzyme activation was inhibited by Cl-930, but the early increase was not.(ABSTRACT TRUNCATED AT 250 WORDS)     

Molecular weight and structural studies on cephalopod rhodopsin.

The protein moiety of squid (Watasenia scintillans) rhodopsin has been shown to have a molecular weight of 46 800 by means of amino acid analysis. This value was comparable to the value (51 000) obtained from SDS-polyacrylamide gel electrophoresis. After the squid eyes were incubated at 10 degrees C for 8 days, the rhodopsin showed a molecular weight of 39 000 on electrophoresis. The smaller molecular weight was ascertained by amino acid analysis of the rhodopsin; and may result from autolysis by the lysosomal enzyme. The rhodopsin in rhabdomeric membranes and in detergent solution was treated with chymotrypsin, papain or subtilisin. These enzymes first produced the 39 000 dalton rhodopsin and then cleaved this into the 25 000 and 14 000 dalton peptides without bleaching. The rhodopsin was attacked by proteases and readily lost an approx. 12 000 dalton peptide portion. This portion included the COOH-terminal and was rich in glutamic acid, proline, glycine, alanine and tyrosine residues.     

Nucleotide regulatory protein-mediated activation of phospholipase C in human polymorphonuclear leukocytes is disrupted by phorbol esters

Polymorphonuclear leukocytes (PMNs) activate phospholipase C via a guanine nucleotide regulatory (G) protein. Pretreatment of the PMNs with pertussis toxin (PT) or 4-beta-phorbol 12-myristate 13-acetate (PMA) inhibited chemoattractant-induced inositol trisphosphate generation. To determine the loci of inhibition by PT and PMA, G protein-mediated reactions in PMN plasma membranes were examined. Plasma membranes prepared from untreated and PMA-treated PMNs demonstrated equivalent ability of a GTP analogue to suppress high affinity binding of the chemoattractant-N-formyl-methionyl-leucyl-phenylalanine (fMet-Leu-Phe) to its receptor. The rate, but not the extent, of high affinity binding of GTP gamma[35S] to untreated PMN membranes was stimulated up to 2-fold by preincubation with 1 microM fMet-Leu-Phe. The ability of fMet-Leu-Phe to stimulate the rate of GTP gamma S binding was absent in membranes prepared from PT-treated PMNs, but remained intact in membranes from PMA-treated cells. Hydrolysis of phosphatidylinositol 4,5-bisphosphate (PIP2) via phospholipase C could be activated in untreated PMN membranes by either fMet-Leu-Phe plus GTP or GTP gamma S alone at low concentrations of Ca2+ (0.1-1 microM). Membranes prepared from PT-treated PMNs degraded PIP2 upon exposure to GTP gamma S, but not fMet-Leu-Phe plus GTP. In contrast, membranes prepared from phorbol ester-treated PMNs did not hydrolyze PIP2 when incubated with GTP gamma S. Treatment with PT or PMA did not affect the ability of 1 mM Ca2+ to activate PIP2 hydrolysis in PMN membranes, indicating that neither treatment directly inactivated phospholipase C. Therefore, PT appears to block coupling of the chemoattractant receptors to G protein activation, while phorbol esters disrupt coupling of the activated G protein to phospholipase C. The phorbol ester-mediated effect may mimic a negative feedback signal induced by protein kinase C activation by diacylglycerol generated upon activation of phospholipase C.