Intrinsically disordered γ-subunit of cGMP phosphodiesterase encodes functionally relevant transient secondary and tertiary structure

Song, Jikui; Guo, Lian‐Wang; Muradov, Hakim; Artemyev, Nikolai O.; Ruoho, Arnold E.; Markley, John L.

doi:10.1073/pnas.0709558105

Cited by 85 publications

(129 citation statements)

References 49 publications

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“…4) clearly demonstrated that the additional 10 amino acids in the longer truncation mutant induced a partial inhibition of catalytic activity in the absence of the blocking C-terminal segment. This region encompasses the ␣1 helical region previously defined in structural studies (19,20). Furthermore, the ability of the region comprising amino acids 71-76 to further increase the inhibition of cGMP hydrolysis (Fig.…”

Section: Discussionmentioning

confidence: 99%

“…The proline-rich and polycationic region (amino acids 18 -45, open box) serves as the primary interaction site with the GAF domains of the PDE6 catalytic dimer. The C-terminal domain of P␥ (amino acids ϳ62-87) is shown as consisting of three ␣-helical sequences (␣1, light gray; ␣2, dark gray; ␣3, black) based on structural studies of its complex with transducin ␣-subunit (20) or free in solution (19); the functional interaction of these putative structural elements with PDE6 catalytic dimer is a focus of the experiments in this paper. B, some of the P␥ truncation mutants and synthetic peptides used in this study are depicted.…”

Section: The C-terminal Region Of P␥ Is a Classical Noncompetitive Inmentioning

confidence: 99%

“…Structural studies of P␥ in solution indicate that this protein is overall an intrinsically disordered protein (18) but contains ␣-helical secondary structure (␣1, ␣2, and ␣3; Fig. 1A) in its C-terminal region (19); the ␣-helical content within the C-terminal region of P␥ is also observed when this region of P␥ forms a complex with either transducin (20) or a chimeric PDE5/6 catalytic domain (21).…”

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Structural Requirements of the Photoreceptor Phosphodiesterase γ-Subunit for Inhibition of Rod PDE6 Holoenzyme and for Its Activation by Transducin

Zhang

Skiba²,

Cote³

2010

Journal of Biological Chemistry

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The central enzyme of the visual transduction cascade, cGMP phosphodiesterase (PDE6), is regulated by its ␥-subunit (P␥), whose inhibitory constraint is released upon binding of activated transducin. It is generally believed that the last four or five C-terminal amino acid residues of P␥ are responsible for blocking catalysis. In this paper, we showed that the last 10 C-terminal residues (P␥78 -87) are the minimum required to completely block catalysis. The kinetic mechanism of inhibition by the P␥ C terminus depends on which substrate is undergoing catalysis. We also discovered a second mechanism of P␥ inhibition that does not require this C-terminal region and that is capable of inhibiting up to 80% of the maximal cGMP hydrolytic rate. Furthermore, amino acids 63-70 and/or the intact ␣2 helix of P␥ stabilize binding of C-terminal P␥ peptides by 100-fold. When PDE6 catalytic subunits were reconstituted with portions of the P␥ molecule and tested for activation by transducin, we found that the C-terminal region (P␥63-87) by itself could not be displaced but that transducin could relieve inhibition of certain P␥ truncation mutants. Our results are consistent with two distinct mechanisms of P␥ inhibition of PDE6. One involves direct interaction of the C-terminal residues with the catalytic site. A second regulatory mechanism may involve binding of other regions of P␥ to the catalytic domain, thereby allosterically reducing the catalytic rate. Transducin activation of PDE6 appears to require interaction with both the C terminus and other regions of P␥ to effectively relieve its inhibitory constraint. The photoreceptor cyclic nucleotide phosphodiesterase (PDE6)2 is the central enzyme in the vertebrate visual signaling pathway in rods and cones. Phototransduction is initiated when light induces the isomerization of the 11-cis-retinal chromophore of rhodopsin, which leads to activation of the photoreceptor-specific G-protein, transducin. Transducin binds GTP and releases its activated ␣-subunit (T␣*-GTP) to activate membrane-associated rod PDE6 by relieving the inhibition of the ␥-subunit at the active sites. The activation of PDE6 results in rapid lowering of cGMP levels, closure of cGMP gated ion channels, and hyperpolarization of the cell membrane (1-5).The PDE6 holoenzyme consists of a catalytic dimer of ␣-and ␤-subunits (P␣␤) and two inhibitory ␥-subunits (P␥) that are tightly bound to P␣␤. Considering its small size, the P␥ subunit of rod and cone PDE6 serves a remarkable number of functions (reviewed in Refs. (6 and 7): 1) a primary function of the P␥ subunit is to inhibit catalysis of cGMP by binding to the catalytic domain of PDE6; 2) the P␥ subunit also enhances the binding affinity of cGMP to the regulatory GAF (cGMP-regulated PDEs, certain adenylate cyclases, and the transcription factor Fh1A of bacteria) domain; 3) activated transducin binds to the P␥ subunit, leading to deinhibition of PDE6 at its active site; and 4) during deactivation, the ␥-subunit participates in a protein complex with the RGS9 and o...

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Section: Discussionmentioning

confidence: 99%

Section: The C-terminal Region Of P␥ Is a Classical Noncompetitive Inmentioning

confidence: 99%

mentioning

confidence: 99%

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Structural Requirements of the Photoreceptor Phosphodiesterase γ-Subunit for Inhibition of Rod PDE6 Holoenzyme and for Its Activation by Transducin

Zhang

Skiba²,

Cote³

2010

Journal of Biological Chemistry

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“…For PDE5, cGMP-induced activation is mediated by binding to the most N-terminal, GAF-A, domain, whereas for PDE2 cGMP interacts with GAF-B, which is more proximal to the catalytic domain. PDE6 is also regulated by cGMP binding to GAF-A, in the unique context of interaction with the P␥ subunit (19,20). The physiological role of GAF domain regulation for PDE10 and 11 is still to be determined (21).…”

mentioning

confidence: 99%

Mechanism for the allosteric regulation of phosphodiesterase 2A deduced from the X-ray structure of a near full-length construct

Pandit

Forman

Fennell

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

151

159

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We report the X-ray crystal structure of a phosphodiesterase (PDE) that includes both catalytic and regulatory domains. PDE2A (215-900) crystallized as a dimer in which each subunit had an extended organization of regulatory GAF-A and GAF-B and catalytic domains connected by long ␣-helices. The subunits cross at the GAF-B/ catalytic domain linker, and each side of the dimer contains in series the GAF-A and GAF-B of one subunit and the catalytic domain of the other subunit. A dimer interface extends over the entire length of the molecule. The substrate binding pocket of each catalytic domain is occluded by the H-loop. We deduced from comparisons with structures of isolated, ligand-bound catalytic subunits that the H-loop swings out to allow substrate access. However, in dimeric PDE2A (215-900), the H-loops of the two catalytic subunits pack against each other at the dimer interface, necessitating movement of the catalytic subunits to allow for H-loop movement. Comparison of the unliganded GAF-B of PDE2A (215-900) with previous structures of isolated, cGMP-bound GAF domains indicates that cGMP binding induces a significant shift in the GAF-B/catalytic domain linker. We propose that cGMP binding to GAF-B causes movement, through this linker region, of the catalytic domains, such that the H-loops no longer pack at the dimer interface and are, instead, free to swing out to allow substrate access. This increase in substrate access is proposed as the basis for PDE2A activation by cGMP and may be a general mechanism for regulation of all PDEs.cGMP activation ͉ GAF domains ͉ PDE-2A T he cyclic nucleotides cAMP and cGMP are ubiquitous intracellular signaling molecules that mediate a vast array of biological processes throughout the body. The means by which these two molecules participate in diverse functions, in different cell types and within single cells, involves tight regulation of the spatial and temporal residence of their concentrations. The phosphodiesterases (PDEs) are a superfamily of enzymes that metabolically inactivate cAMP and cGMP (1) to play key roles in both these aspects of regulation. The PDEs are modular enzymes characterized by a relatively conserved C-terminal catalytic domain and a more variable N-terminal domain involved in regulation of activity, subcellular localization, and interactions with other proteins. There are 11 PDE gene families, with different families encoded by one to four genes, and further diversity derived from alternative splicing. The PDE families differ broadly in specificity and affinity for cAMP and cGMP. Much has been learned about the molecular bases for these differences from studies of X-ray crystal structures of the catalytic domains of

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“…However, the intrinsically disordered PDE␥, especially its N-terminal half (18), has been problematic in solving a crystal structure of ␣t and RGS9⅐␤5 bound with the full-length PDE␥. As indicated in our previous reports (13,19,20), the label transfer approach has allowed for systematic mapping of interactions between fulllength molecules, thus circumventing the problems of intrinsic disorder that can impede efforts in solving atomic structures.…”

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confidence: 99%

N-terminal Half of the cGMP Phosphodiesterase γ-Subunit Contributes to Stabilization of the GTPase-accelerating Protein Complex

Ruoho

2011

Journal of Biological Chemistry

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In the visual signal terminating transition state, the cyclic GMP phosphodiesterase (PDE6) inhibitory ␥-subunit (PDE␥) stimulates GTPase activity of the ␣-subunit of transducin (␣t) by enhancing the interaction between ␣t and its regulator of G protein signaling (RGS9), which is constitutively bound to the type 5 G protein ␤-subunit (␤5). Although it is known from a crystal structure of partial molecules that the PDE␥ C terminus contacts with both ␣t and RGS9, contributions from the intrinsically disordered PDE␥ N-terminal half remain unclear. In this study, we were able to investigate this issue using a photolabel transfer strategy that allows for mapping the interface of fulllength proteins. We observed label transfer from PDE␥ N-terminal positions 50, 30, and 16 to RGS9⅐␤5 in the GTPase-accelerating protein (GAP) complex composed of PDE␥⅐␣t⅐RGS9⅐␤5. In support of a direct PDE␥ N-terminal interaction with RGS9⅐␤5, the PDE␥ N-terminal peptide PDE␥(1-61) abolished label transfer to RGS9⅐␤5, and another N-terminal peptide, PDE␥(10 -30), disassembled the GAP complex in label transfer and pulldown experiments. Furthermore, we determined that the PDE␥ C-terminal interaction with ␣t was enhanced whereas the N-terminal interaction was weakened upon changing the ␣t conformation from the signaling state to the transition state. This "rearrangement" of PDE␥ domain interactions with ␣t appears to facilitate the interaction of the PDE␥ N-terminal half with RGS9⅐␤5 and hence its contribution to optimal stabilization of the GAP complex.In vertebrate photoreceptor cells, interactions of the cyclic GMP (cGMP) phosphodiesterase (PDE6) 2 inhibitory ␥-subunit (PDE␥) with its targets switch on and off visual signal transduction (for review, see Refs. 1-4). The signaling is turned on when the GTP-bound ␣-subunit of transducin (␣t), which is converted from the GDP-bound conformation by light-excited rhodopsin, activates PDE6 by interacting with PDE␥ and displacing its C terminus from the PDE6 catalytic pocket (signaling state). Lowered cGMP levels then cause hyperpolarization of the plasma membrane by closing cGMP-gated channels, thus leading to signal transmission to the brain. Concomitantly, the GTPase activity of ␣t is accelerated to hydrolyze the bound GTP into GDP, via simultaneous ␣t interactions with PDE␥ and the regulator of G protein signaling (RGS9) constitutively bound with the type 5 G protein ␤-subunit (␤5) (transition state). Once the conformation of ␣t reverts back to the GDPbound inactive form, PDE␥ dissociates from ␣t and reinhibits PDE6. Visual transduction is thus turned off, and the signaling proteins are primed for the next round of the photoresponse.Throughout this report, the two conformers of ␣t in the signaling state and transition state are represented respectively by ␣t-GTP␥S (5) and ␣t-GDP-AlF 4 Ϫ (6). The four-component (␣t⅐PDE␥⅐RGS9⅐␤5) transition state complex is also referred to as the GAP (GTPase-accelerating protein) complex (2).Our knowledge regarding the protein functions and interactions within t...

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Intrinsically disordered γ-subunit of cGMP phosphodiesterase encodes functionally relevant transient secondary and tertiary structure

Cited by 85 publications

References 49 publications

Structural Requirements of the Photoreceptor Phosphodiesterase γ-Subunit for Inhibition of Rod PDE6 Holoenzyme and for Its Activation by Transducin

Structural Requirements of the Photoreceptor Phosphodiesterase γ-Subunit for Inhibition of Rod PDE6 Holoenzyme and for Its Activation by Transducin

Mechanism for the allosteric regulation of phosphodiesterase 2A deduced from the X-ray structure of a near full-length construct

N-terminal Half of the cGMP Phosphodiesterase γ-Subunit Contributes to Stabilization of the GTPase-accelerating Protein Complex

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