The Molecular Basis for Different Recognition of Substrates by Phosphodiesterase Families 4 and 10

Wang, Huanchen; Robinson, Howard; Ke, Hengming

doi:10.1016/j.jmb.2007.05.060

Cited by 48 publications

(30 citation statements)

References 29 publications

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“…Catalytic rates in those mutants are like those of WT enzymes. In the x-ray co-crystal of PDE4D2 in complex with cAMP, there is only one hydrogen bond between the glutamine side chain and cAMP compared with the prediction of two bonds (401).…”

Section: A) the Fixed Side Chain Of The Invariant Glutamine Doesmentioning

confidence: 98%

“…This seems counterintuitive since 5=-nucleotides interact weakly with PDEs (K i ϳ1-10 mM) compared with the affinities for substrates (K m ϳ0.02-40 M) (399). Wang and co-workers (399,401) have determined the x-ray crystal structures of PDE4D2 (a cAMP-specific PDE) and PDE10 (dual-specificity PDE) utilizing C domains with WT sequence and those in which mutations of critical residues have rendered them largely inactive. The mutations introduced into PDE4D2 or PDE10A2 did not significantly alter the active site conformation compared with WT proteins, thereby validating insights regarding interaction of substrates with WT PDEs.…”

Section: Interaction Of Cn Substrates and Products Of Hydrolysis Withmentioning

confidence: 99%

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Mammalian Cyclic Nucleotide Phosphodiesterases: Molecular Mechanisms and Physiological Functions

Francis

Blount

Corbin

2011

Physiological Reviews

560

546

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The superfamily of cyclic nucleotide (cN) phosphodiesterases (PDEs) is comprised of 11 families of enzymes. PDEs break down cAMP and/or cGMP and are major determinants of cellular cN levels and, consequently, the actions of cN-signaling pathways. PDEs exhibit a range of catalytic efficiencies for breakdown of cAMP and/or cGMP and are regulated by myriad processes including phosphorylation, cN binding to allosteric GAF domains, changes in expression levels, interaction with regulatory or anchoring proteins, and reversible translocation among subcellular compartments. Selective PDE inhibitors are currently in clinical use for treatment of erectile dysfunction, pulmonary hypertension, intermittent claudication, and chronic pulmonary obstructive disease; many new inhibitors are being developed for treatment of these and other maladies. Recently reported x-ray crystallographic structures have defined features that provide for specificity for cAMP or cGMP in PDE catalytic sites or their GAF domains, as well as mechanisms involved in catalysis, oligomerization, autoinhibition, and interactions with inhibitors. In addition, major advances have been made in understanding the physiological impact and the biochemical basis for selective localization and/or recruitment of specific PDE isoenzymes to particular subcellular compartments. The many recent advances in understanding PDE structures, functions, and physiological actions are discussed in this review.

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Section: A) the Fixed Side Chain Of The Invariant Glutamine Doesmentioning

confidence: 98%

Section: Interaction Of Cn Substrates and Products Of Hydrolysis Withmentioning

confidence: 99%

Mammalian Cyclic Nucleotide Phosphodiesterases: Molecular Mechanisms and Physiological Functions

Francis

Blount

Corbin

2011

Physiological Reviews

560

546

View full text Add to dashboard Cite

show abstract

“…The three inhibitors have a central planar ring that stacks between Phe372 and Ile336, and each forms a hydrogen bond with Gln535. These features are common to all known PDE4 inhibitors (Wang et al 2007b). Active site-directed, competitive PDE4 inhibitors often coordinate to the catalytic metals in the active site.…”

Section: Structure Of Pde4 Regulatory Domainsmentioning

confidence: 99%

“…The understanding of the active site pocket has allowed the design of inhibitors competitive with cyclic nucleotide binding, and there are sufficient differences between different superfamily members to create family specific inhibitors (e.g., PDE4 vs. PDE5). However, the active site residues of PDE4A, 4B, 4C, and 4D are completely superimposable, and there are no sequence or structural differences that can allow the design of subtype-selective PDE4 competitive inhibitors, for example, PDE4B vs. PDE4D (Wang et al 2007b).…”

Section: Structure Of Pde4 Regulatory Domainsmentioning

confidence: 99%

“…These are compounds with complex kinetics of inhibition with rolipram being the archetype (Huston et al 1996). The bulk of industry effort has been devoted to the design of active sitedirected PDE4 inhibitors with simple Michaelis-Menten kinetics that bind to the catalytic site and thus are competitive with the cAMP substrate (Wang et al 2007b). Atypical PDE4 inhibitors such as rolipram were recognized to bind both high-and low-affinity sites on PDE4, although the structural basis of those sites was not known (Souness and Rao 1997).…”

Section: Structure Of Pde4 Regulatory Domainsmentioning

confidence: 99%

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Small Molecule Allosteric Modulators of Phosphodiesterase 4

Gurney

Burgin²,

Magnússon

et al. 2011

Phosphodiesterases as Drug Targets

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Phosphodiesterase 4 (PDE4) inhibitors have shown benefit in human clinical trials but dosing is limited by tolerability, particularly because of emesis. Novel cocrystal structures of PDE4 catalytic units with their regulatory domains together with bound inhibitors have revealed three different PDE4 conformers that can be exploited in the design of novel therapeutic agents. The first is an open conformer, which has been employed in the traditional approach to the design of competitive PDE4 inhibitors. The second is an asymmetric dimer in which a UCR2 regulatory helix from one monomer is placed in a closed conformation over the opposite active site in the PDE4 dimer (trans-capping). Only one active site can be closed by an inhibitor at a time with the consequence that compounds exploiting this conformer only partially inhibit PDE4 enzymatic activity while retaining potency in cellular and in vivo models. By placing an intrinsic ceiling on the magnitude of PDE4 inhibition, such compounds may better maintain spatial and temporal patterning of signaling in cAMP microdomains with consequent improved tolerability. The third is a symmetric PDE4 conformer in which helices from the C-terminal portion of the catalytic unit cap both active sites (cis-capping). We propose that dual-gating of PDE4 activity may be further fine tuned by accessory proteins that recognize open or closed conformers of PDE4 regulatory helices.

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Phosphodiesterase Inhibitors as a Novel Therapeutic Approach for Schizophrenia

Siuciak¹,

Pitts²

2012

Targets and Emerging Therapies for Schizophrenia

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The Molecular Basis for Different Recognition of Substrates by Phosphodiesterase Families 4 and 10

Cited by 48 publications

References 29 publications

Mammalian Cyclic Nucleotide Phosphodiesterases: Molecular Mechanisms and Physiological Functions

Mammalian Cyclic Nucleotide Phosphodiesterases: Molecular Mechanisms and Physiological Functions

Small Molecule Allosteric Modulators of Phosphodiesterase 4

Phosphodiesterase Inhibitors as a Novel Therapeutic Approach for Schizophrenia

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