EC:3.1.4.1 - FACTA Search

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Query: EC:3.1.4.1 (phosphodiesterase)
18,767 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Light-induced GTP-dependent scattering changes are studied in suspensions of retinal disc membranes to which one or both of the purified proteins involved in the phototransduction mechanism (G-protein and cGMP phosphodiesterase) are reassociated; a scattering change which depends on the presence of both G-protein (G) and inhibited cGMP phosphodiesterase (PDE) and on an ATPase-dependent process, previously described in Bennett [(1986) Eur. J. Biochem. 157, 487-495] is compared to the signal observed in the absence of PDE or of ATP and to PDE activity. The same signal can also be induced either in the dark or in the light by addition of preactivated G in the presence of inhibited PDE. This PDE-dependent scattering change is composed of two components (fast and slow); the variation of the amplitude and kinetics of both components with PDE or G concentration is similar to the variation of the active PDE state with two activator GGTP molecules (G with GTP bound), calculated with dissociation constants previously reported for the interaction between GGTP and PDE [Bennett, N., & Clerc, A. (1989) Biochemistry 28, 7418-7424]. The two components are therefore proposed to be associated with processes which depend on the formation of the active PDE state with two activators.
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PMID:cGMP phosphodiesterase dependent light-induced scattering changes in suspensions of retinal disc membranes. 131 Jun 20

Retinal rod-outer-segment phosphodiesterase (PDE) is a heterotetramer consisting of two similar, but not identical, catalytic subunits (alpha and beta) and two identical inhibitory subunits (gamma 2). Previously, we have reported that the site of PDE alpha/beta interaction with PDE gamma is located within residues 54-87 [Cunnick, Hurt, Oppert, Sakamoto & Takemoto (1990) Biochem. J. 271, 721-727]. The site for PDE gamma interaction with transducin alpha (T alpha) was found to encompass residues 24-45 of PDE gamma [Morrison, Cunnick, Oppert & Takemoto (1989) J. Biol. Chem. 264, 11671-11681]. In order to identify binding sites and other functional domains of PDE gamma, the three peptides which are encoded by the three exons of the PDE gamma gene were synthesized chemically. These exons encode for residues 1-49, 50-62 and 63-87 of bovine PDE gamma [Piriev, Purishko, Khramtsov & Lipkin (1990) Dokl. Akad. Nauk. SSSR 315, 229-230]. The peptide encompassing residues 63-87 was inhibitory in a PDE assay, whereas peptides 1-49 and 50-62 had no effect. However, both peptides 1-49 and 63-87 bound to PDE alpha/beta in a solid-phase binding assay. Only peptide 1-49 bound to T alpha.GTP[S] (GTP[S] is guanosine 5'-[gamma-thio]triphosphate). These data confirm that the inhibitory region of PDE gamma is encoded by exon 3 (residues 63-87), whereas a separate binding site for PDE alpha/beta and for T alpha.GTP[S] is encoded by exon 1 (residues 1-49). To study further the structure-function relationship of PDE gamma, this entire protein and two mutants were chemically synthesized. One mutant (-CT) lacked residues 78-87, whereas another replaced tyrosine-84 with glycine (TYR-84). Whereas the synthetic PDE gamma inhibited PDE alpha/beta catalytic activity, the -CT and TVR-84 mutants did not. All three synthetic proteins bound to both PDE alpha/beta and and T alpha.GTP[S]. These data confirm the presence of an alternative binding site on PDE gamma and demonstrate the importance of tyrosine-84 in PDE gamma inhibitory activity.
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PMID:Domain mapping of the retinal cyclic GMP phosphodiesterase gamma-subunit. Function of the domains encoded by the three exons of the gamma-subunit gene. 131 Nov 70

Purified G-protein (transducin) activated with the nonhydrolyzable analog guanosine 5'-O-(thiotriphosphate) (GTP gamma S) and cGMP phosphodiesterase (PDE) from retinal rods are added to protein-stripped disc membranes. Specific binding of the mainly soluble alpha subunit of G-protein with GTP gamma S bound (G alpha GTP gamma S, activator of the PDE) to the disc membrane in the presence of PDE is measured from gel scans or experiments with labeled G-protein alpha subunit (G alpha). Its variation as a function of G concentration matches the theoretical variation of G alpha involved in the activation of PDE calculated with previously estimated dissociation constants (Bennett, N., and Clerc, A. (1989) Biochemistry 28, 7418-7424), and the G alpha bound/PDE ratio at saturation is close to 2. No increase of G alpha binding to the membrane is observed when purified inhibitory subunit of PDE (PDE gamma) is added together with or instead of total PDE, and excess PDE gamma remains soluble. These results suggest that activated PDE is a complex with the activator G alpha GTP rather than PDE from which the inhibitory subunits have been removed. A method for purifying PDE gamma with a high yield of recovery and activity is described.
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PMID:Activated cGMP phosphodiesterase of retinal rods. A complex with transducin alpha subunit. 131 17

Atopic dermatitis (AD) is characterized by a variety of abnormal physiologic and pharmacologic responses in the skin. Leukocyte abnormalities of the cyclic nucleotide system include increased cAMP phosphodiesterase (PDE) and adenylyl cyclase activities. We have evaluated the possibility that a defect of the inhibitory GTP-binding protein (Gi) might cause inadequate modulation of adenylyl cyclase activity in AD leukocytes. We carried out a series of studies assessing adenylyl cyclase and Gi subunits in monocyte membranes. Using both pertussis toxin ribosylation and direct monoclonal antibody labeling of Gi proteins, we have shown evidence for a decrease or possible absence of one of the Gi proteins in atopic monocyte membranes. A genetic defect or toxin-mediated abnormality in leukocyte membrane Gi could account for these findings. Increased cAMP degradation by PDE may be a compensatory mechanism for increased cAMP synthesis that is regulated by GTP-binding proteins. But this increased PDE activity also rendered AD leukocytes hypo-responsive to immunofunction regulatory signals mediated by cAMP.
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PMID:Relationship between increased cyclic AMP-phosphodiesterase activity and abnormal adenylyl cyclase regulation in leukocytes from patients with atopic dermatitis. 131 24

The photoreceptor G protein, transducin, is one of the class of heterotrimeric G proteins that mediates between membrane receptors and intracellular enzymes or ion channels. Light-activated rhodopsin catalyses the exchange of GDP for GTP on multiple transducin molecules. Activated transducin then stimulates cyclic GMP phosphodiesterase by releasing an inhibitory action of the phosphodiesterase gamma-subunits. This leads to a decrease in cGMP levels in the rod, and closure of plasma membrane cationic channels gated by cGMP. In this and other systems, turn-off of the response requires the GTP bound to G protein to be hydrolysed by an intrinsic GTPase activity. Here we report that the interaction of transducin with cGMP phosphodiesterase, specifically with its gamma-subunits, accelerates GTPase activity by several fold. Thus the gamma-subunits of the phosphodiesterase serve a function analogous to the GTPase-activating proteins that regulate the class of small GTP-binding proteins. The acceleration can be partially suppressed by cGMP, most probably through the non-catalytic cGMP-binding sites of phosphodiesterase alpha and beta-subunits. This cGMP regulation may function in light-adaptation of the photo-response as a negative feedback that decreases the lifetime of activated cGMP phosphodiesterase as light causes decreases in cytoplasmic cGMP.
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PMID:Regulation of deactivation of photoreceptor G protein by its target enzyme and cGMP. 131 9

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.
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PMID:Membrane stimulation of cGMP phosphodiesterase activation by transducin: comparison of phospholipid bilayers to rod outer segment membranes. 132 16

Cross-linking of the different subunits of the retinal cGMP-phosphodiesterase (PDE) with its activator G alpha GTP gamma S (alpha subunit of the retinal G-protein transducin with GTP gamma S (guanosine 5'-O-(3-thiotriphosphate) bound) has been investigated using purified proteins, with a N-hydroxysuccinimide homobifunctional cross-linker, bis(sulfosuccinimidyl)suberate (BS3) and its cleavable analog 3,3'-dithiobis(sulfosuccinimidylpropionate) (DTSSP). Interaction of purified G-protein and PDE is achieved in the presence of lecithin vesicles, at protein concentrations sufficient for full PDE activation. Protein subunits linked with DTSSP are separated by cleavage of the disulfide bridge and identified by electrophoresis. Complexes of PDE alpha (PDE beta) with 1 and 2 molecules of activator G alpha GTP gamma S are observed, providing direct evidence for an interaction or at least a close proximity between 2 molecules of activator G alpha and each of the catalytic PDE subunits in the activated state of PDE. The results also reveal symmetrical roles of PDE alpha and PDE beta, with the existence of one site for PDE gamma and one site for G alpha on each catalytic subunit.
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PMID:Interaction between cGMP-phosphodiesterase and transducin alpha-subunit in retinal rods. A cross-linking study. 132 88

The generation of the physiological response of a retinal rod cell to an incident photon involves activation of a cGMP phosphodiesterase (PDE) by a GTP-binding protein, transducin (T). This activation has been shown to occur by formation of a membrane-bound T alpha GTP-PDE complex (Clerc, A., and Bennett, N. (1992) J. Biol. Chem. 267, 6620-6627; Catty, P., Pfister, C., Bruckert, F., and Deterre, P. (1992) J. Biol. Chem 267, 19489-19493). The recovery of the response involves turning-off of T by its intrinsic GTPase activity. We show here that the formation of the membrane-bound T alpha GTP-PDE complex correlates with an enhanced rate of GTP hydrolysis. In vivo, this would provide an appropriate mechanism for fast turn-off of cGMP hydrolysis.
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PMID:Enhanced GTPase activity of transducin when bound to cGMP phosphodiesterase in bovine retinal rods. 133 Oct 45

Phototransduction mechanisms have been so far investigated mostly in rods, whereas those in cones are much less known. In the present experiment, we investigated phototransduction mechanisms in inside-out patches excised from cone outer segments of the carp. Cyclic GMP-activated channels on the patch became light-sensitive when both GTP and Mg2+ were supplied by perfusion. When the channels were activated by a hydrolysis-resistant analogue of cGMP, activities were not suppressed by light even though both GTP and Mg2+ were present. Thus activation of transducin and phosphodiesterase (PDE) were involved in the transduction processes, indicating that phototransduction mechanisms in cones are qualitatively similar to those in rods. In cone patches, however, light responses fully terminated even though ATP was absent, opposing to the report that ATP was indispensable for light response termination in rods. The response termination in the cone patch might result from activation of guanylate cyclase and/or inactivation of PDE. Under the perfusion of GTP together with Mg2+ and 3-isobutyl-1-methyl xanthine, no channel activities were observed, indicating that no guanylate cyclase activity was present in cone patch preparations. Therefore, termination of the light response in the patch might be caused by inactivation of PDE which resulted from inactivation of photopigment and transducin. Based on these observations, differences in light response kinetics between the rod and cone are discussed.
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PMID:Phototransduction in cones as examined in excised membrane patch. 133 81

Transducin (T alpha beta gamma), the heterotrimeric GTP-binding protein that interacts with photoexcited rhodopsin (Rh*) and the cGMP-phosphodiesterase (PDE) in retinal rod cells, is sensitive to cholera (CTx) and pertussis toxins (PTx), which catalyze the binding of an ADP-ribose to the alpha subunit at Arg174 and Cys347, respectively. These two types of ADP-ribosylations are investigated with transducin in vitro or with reconstituted retinal rod outer-segment membranes. Several functional perturbations inflicted on T alpha by the resulting covalent modifications are studied such as: the binding of T alpha to T beta gamma to the membrane and to Rh*; the spontaneous or Rh*-catalysed exchange of GDP for GTP or guanosine 5-[gamma-thio]triphosphate (GTP[gamma S]), the conformational switch and activation undergone by transducin upon this exchange, the activation of T alpha GDP by fluoride complexes and the activation of the PDE by T alpha GTP. ADP-ribosylation of transducin by CTx requires the GTP-dependent activation of ADP-ribosylation factors (ARF), takes place only on the high-affinity, nucleotide-free complex, Rh*-T alpha empty-T beta gamma and does not activate T alpha. Subsequent to CTx-catalyzed ADP-ribosylation the following occurs: (a) addition of GDP induces the release from Rh* of inactive CTxT alpha GDP (CTxT alpha, ADP-ribosylated alpha subunit of transducin) which remains associated to T beta gamma; (b) CTxT alpha GDP-T beta gamma exhibits the usual slow kinetics of spontaneous exchange of GDP for GTP[gamma S] in the absence of Rh*, but the association and dissociation of fluoride complexes, which act as gamma-phosphate analogs, are kinetically modified, suggesting that the ADP-ribose on Arg174 specifically perturbs binding of the gamma-phosphate in the nucleotide site; (c) CTxT alpha GDP-T beta gamma can still couple to Rh* and undergo fast nucleotide exchange; (d) CTxT alpha GTP[gamma S] and CTxT alpha GDP-AlFx (AlFx, Aluminofluoride complex) activate retinal cGMP-phosphodiesterase (PDE) with the same efficiency as their unmodified counterparts, but the kinetics and affinities of fluoride activation are changed; (e) CTxT alpha GTP hydrolyses GTP more slowly than unmodified T alpha GTP, which entirely accounts for the prolonged action of CTxT alpha GTP on the PDE; (f) after GTP hydrolysis, CTxT alpha GDP reassociates to T beta gamma and becomes inactive. Thus, CTx catalyzed ADP-ribosylation only perturbs in T alpha the GTP-binding domain, but not the conformational switch nor the domains of contact with the T beta gamma subunit, with Rh* and with the PDE.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Functional modifications of transducin induced by cholera or pertussis-toxin-catalyzed ADP-ribosylation. 133 64

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