Mechanism for the regulation of mammalian cGMP phosphodiesterase6. 1: identification of its inhibitory subunit complexes and their roles.

Cyclic GMP phosphodiesterase (PDE) in bovine rod photoreceptor outer segments (OS) comprises a catalytic subunit complex (Palphabeta) and two inhibitory subunits (Pgamma) and is regulated by the alpha subunit of transducin (Talpha). Here, we show an overall mechanism for PDE regulation by identifying Pgamma complexes in OS homogenates prepared with an isotonic buffer. Before Talpha activation, three Pgamma complexes exist in the soluble fraction. Complex a, a minor complex, contains Palphabeta, Talpha, and a protein named Pdelta. Complex b, Palphabetagammagamma( b ), has a PDE activity similar to that of membranous Palphabetagammagamma, Palphabetagammagamma( M ), and its level, although its large portion is Pdelta-free, is estimated to be 20-30% of the total Palphabetagammagamma. Complex c, (Pgamma.GDP-Talpha) (2) ( c ) , appears to be a dimer of Pgamma.GDP-Talpha. Upon Talpha activation, (1) complex a stays unchanged, (2) Palphabetagammagamma( b ) binds to membranes, (3) the level of (Pgamma.GDP-Talpha) (2) ( c ) is reduced as its GTP-form is produced, (4) complex d, Pgamma.GTP-Talpha( d ), is formed on membranes and its substantial amount is released to the soluble fraction, and (5) membranous Palphabetagammagamma, Palphabetagammagamma( M ) and/or Palphabetagammagamma( b ), becomes Pgamma-depleted. These observations indicate that Pgamma as a complex with GTP-Talpha dissociates from Palphabetagammagamma on membranes and is released to the soluble fraction and that Pgamma-depleted PDE is the GTP-Talpha-activated PDE. After GTP hydrolysis, both (Pgamma.GDP-Talpha) (2) ( c ) and Pgamma.GDP-Talpha( d ), without liberating Pgamma, deactivate Pgamma-depleted PDE. The preferential order to be used for the deactivation is membranous Pgamma.GDP-Talpha( d ), solubilized Pgamma.GDP-Talpha( d ) and (Pgamma.GDP-Talpha) (2) ( c ) . Release of Pgamma.GTP-Talpha complexes to the soluble fraction is relevant to light adaptation.

Mechanism for the regulation of mammalian cGMP phosphodiesterase6. 2: isolation and characterization of the transducin-activated form.

Rod photoreceptor cGMP phosphodiesterase (PDE6) consists of a catalytic subunit complex (Palphabeta) and two inhibitory subunits (Pgamma). In the accompanying article, using bovine photoreceptor outer segment homogenates, we show that Pgamma as a complex with the GTP-bound transducin alpha subunit (GTP-Talpha) dissociates from Palphabetagammagamma on membranes, and the Palphabetagammagamma becomes Pgamma-depleted. Here, we identify and characterize the Pgamma-depleted PDE. After incubation with or without guanosine 5'-O-(3-thiotriphosphate) (GTPgammaS), Palphabeta complexes are extracted. When a hypotonic buffer is used, Palphabetagammagamma, Palphabetagamma, and a negligible amount of a Palphabeta complex containing Pgamma are isolated with GTPgammaS, and only Palphabetagammagamma is obtained without GTPgammaS. When an isotonic buffer containing Pdelta, a prenyl-binding protein, is used, Palphabetagammagammadelta, Palphabetagammadeltadelta, and a negligible amount of a Palphabeta complex containing Pgamma and Pdelta are isolated with GTPgammaS, and Palphabetagammagammadelta is obtained without GTPgammaS. Neither Palphabeta nor Palphabetagammagamma complexed with GTPgammaS-Talpha is found under any condition we examined. Palphabetagamma has approximately 12 times higher PDE activity and approximately 30 times higher Pgamma sensitivity than those of Palphabetagammagamma. These results indicate that the Pgamma-depleted PDE is Palphabetagamma. Isolation of Palphabetagammagammadelta and Palphabetagammadeltadelta suggests that one C-terminus of Palphabeta is involved in the Palphabetagammagamma interaction with membranes, and that Pgamma dissociation opens another C-terminus for Pdelta binding, which may lead to the expression of high PDE activity. Cone PDE behaves similarly to rod PDE in the anion exchange column chromatography. We conclude that the mechanisms for PDE activation are similar in mammalian and amphibian photoreceptors as well as in rods and cones.

Phosphorylation by cyclin-dependent protein kinase 5 of the regulatory subunit (Pgamma) of retinal cgmp phosphodiesterase (PDE6): its implications in phototransduction.

Cyclic GMP phosphodiesterase (PDE6) is a key enzyme in vertebrate retinal phototransduction. After GTP/GDP exchange on the a subunit of transducin (Talpha) by illuminated rhodopsin, the GTP-bound form Talpha (GTP/Talpha) interacts with the regulatory subunit (Pgamma) of PDE6 to activate cGMP hydrolytic activity. The regulatory mechanism of PDE6 has been believed to be a typical G protein-mediated signal transduction process. We found that cyclin-dependent protein kinase 5 (Cdk5) phosphorylates Pgamma complexed with GTP/Talpha in vitro and in vivo. Phosphorylated Py dissociates from GTP/Talpha without GTP hydrolysis and interacts effectively with catalytic subunits of PDE6 to inhibit the enzyme activity. These observations provide new twists to the current model of retinal phototransduction. In this article, in addition to the details of Py phosphorylation by Cdk5, we review previous studies implying the Pgamma phosphorylation and the turnoff of PDE6 without GTP hydrolysis and indicate the direction for future studies of Py phosphorylation, including the possible involvement of Ca2+/Ca2+-binding proteins.

Illuminated rhodopsin is required for strong activation of retinal guanylate cyclase by guanylate cyclase-activating proteins.

We have recently shown that activation of retinal guanylate cyclase (retGC) by GC-activating proteins (GCAPs) is much stronger than that previously reported and that preincubation of photoreceptor outer segment homogenates with ATP or its analogue, adenylyl imidodiphosphate (AMP-PNP), is required for the strong activation [Yamazaki, A., Yu, H., Yamazaki, M., Honkawa, H., Matsuura, I., Usukura, J., and Yamazaki, R. K. (2003) J. Biol. Chem. 278, 33150-33160]. Here we show that illuminated rhodopsin is essential for development of the AMP-PNP incubation effect. This was demonstrated by illumination of dark homogenates and treatments of illuminated homogenates with 11-cis-retinal and hydroxylamine prior to the AMP-PNP incubation and by measurement of the GCAP2 concentration required for 50% activation. We also found that the AMP-PNP incubation effect was not altered by addition of guanosine 5'-O-(3-thiotriphosphate), indicating that transducin activation is not required. It is concluded that illuminated rhodopsin is involved in retGC activation in two ways: to initiate the ATP incubation effect for preparation of retGC activation as shown here and to reduce the Ca2+ concentrations through cGMP phosphodiesterase activation as already known. These two signal pathways may be activated in a parallel and perhaps proportional manner and finally converge for strong activation of retGC by Ca2+-free GCAPs.

ATP binding is required for physiological activation of retinal guanylate cyclase.

ATP bound to retinal guanylate cyclase (retGC)/membranes prior to the assay (pre-binding effect) and during the assay (direct effect) further enhances retGC activity stimulated by GC-activating proteins (GCAPs). Here we investigate differences between these two effects. We found that the pre-binding effect, but not the direct effect, was absent in membranes pre-washed with Mg(2+)-free hypotonic buffers, that the pre-binding effect, but not the direct effect, was strictly limited to GCAP-stimulated retGC activity, and that these two effects were independent and additive rather than being synergistic. Pre-incubation with amiloride enhanced GCAP2-activated retGC activity in a manner similar to that by ATP pre-binding; however, amiloride did not directly stimulate the retGC activity. These results indicate that these two effects are mechanistically different. Levels of retGC activation by these effects and conditions required for these effects indicate that only the mechanism involving ATP pre-binding is physiologically relevant to retGC activation.

A novel role of RGS9: inhibition of retinal guanylyl cyclase.

Cyclic GMP plays a key role in retinal phototransduction and its photoreceptor concentration is precisely controlled by the cooperative action of cGMP phosphodiesterase (PDE) and retinal guanylyl cyclase (retGC). However, studies of the relationship between these two systems have focused only on a Ca2+-mediated, indirect connection. This article summarizes our studies strongly suggesting that RGS9-1 is directly involved in the cooperative action of PDE and retGC, and that this ingenious mechanism plays an important role in tuning of cGMP concentration in photoreceptors.

Binding of cGMP to GAF domains in amphibian rod photoreceptor cGMP phosphodiesterase (PDE). Identification of GAF domains in PDE alphabeta subunits and distinct domains in the PDE gamma subunit involved in stimulation of cGMP binding to GAF domains.

Retinal cGMP phosphodiesterase (PDE6) is a key enzyme in vertebrate phototransduction. Rod PDE contains two homologous catalytic subunits (Palphabeta) and two identical regulatory subunits (Pgamma). Biochemical studies have shown that amphibian Palphabeta has high affinity, cGMP-specific, non-catalytic binding sites and that Pgamma stimulates cGMP binding to these sites. Here we show by molecular cloning that each catalytic subunit in amphibian PDE, as in its mammalian counterpart, contains two homologous tandem GAF domains in its N-terminal region. In Pgamma-depleted membrane-bound PDE (20-40% Pgamma still present), a single type of cGMP-binding site with a relatively low affinity (K(d) approximately 100 nm) was observed, and addition of Pgamma increased both the affinity for cGMP and the level of cGMP binding. We also show that mutations of amino acid residues in four different sites in Pgamma reduced its ability to stimulate cGMP binding. Among these, the site involved in Pgamma phosphorylation by Cdk5 (positions 20-23) had the largest effect on cGMP binding. However, except for the C terminus, these sites were not involved in Pgamma inhibition of the cGMP hydrolytic activity of Palphabeta. In addition, the Pgamma concentration required for 50% stimulation of cGMP binding was much greater than that required for 50% inhibition of cGMP hydrolysis. These results suggest that the Palphabeta heterodimer contains two spatially and functionally distinct types of Pgamma-binding sites: one for inhibition of cGMP hydrolytic activity and the second for activation of cGMP binding to GAF domains. We propose a model for the Palphabeta-Pgamma interaction in which Pgamma, by binding to one of the two sites in Palphabeta, may preferentially act either as an inhibitor of catalytic activity or as an activator of cGMP binding to GAF domains in frog PDE.

A critical role for ATP in the stimulation of retinal guanylyl cyclase by guanylyl cyclase-activating proteins.

It has been believed that retinal guanylyl cyclase (retGC), a key enzyme in the cGMP recovery to the dark state, is solely activated by guanylyl cyclase-activating proteins (GCAPs) in a Ca2+-sensitive manner. However, a question has arisen as to whether the observed GCAP stimulation of retGC is sufficient to account for the cGMP recovery because the stimulated activity measured in vitro is less than the light/GTP-activated cGMP phosphodiesterase activity. Here we report that the retGC activation by GCAPs is larger than previously reported and that a preincubation with adenine nucleotide is essential for the large activation. Under certain conditions, ATP is two times more effective than adenylyl imidodiphosphate (AMP-PNP), a hydrolysis-resistant ATP analog; however, this study mainly used AMP-PNP to focus on the role of adenine nucleotide binding to retGC. When photoreceptor outer segment homogenates are preincubated with AMP-PNP (EC50 = 0.65 +/- 0.20 mM), GCAP2 enhanced the retGC activity 10-13 times over the control rate. Without AMP-PNP, GCAP2 stimulated the control activity only 3-4-fold as in previous reports. The large activation is due to a GCAP2-dependent increase in Vmax without an alteration of retGC affinity for GCAP2 (EC50 = 47.9 +/- 2.7 nM). GCAP1 stimulated retGC activity in a similar fashion but with lower affinity (EC50 = 308 nM). In the AMP-PNP preincubation, low Ca2+ concentrations are not required, and retGC exists as a monomeric form. This large activation is accomplished through enhanced action of GCAPs as shown by Ca2+ inhibition of the activity (IC50 = 178 nM). We propose that retGC is activated by a two-step mechanism: a conformational change by ATP binding to its kinase homology domain under high Ca2+ concentrations that allows large enhancement of GCAP activation under low Ca2+ concentrations.