Application of Structure-Based Drug Design and Parallel Chemistry to Identify Selective, Brain Penetrant, In Vivo Active Phosphodiesterase 9A Inhibitors

Claffey, Michelle M.; Helal, Christopher J.; Verhoest, Patrick R.; Kang, Zhijun; Fors, Kristina S.; Jung, Stanley; Zhong, Jiaying; Bundesmann, Mark W.; Hou, Xinjun; Lui, Shenping; Kleiman, Robin J.; Vanase-Frawley, Michelle; Schmidt, Anne W.; Menniti, Frank S.; Schmidt, Christopher J.; Hoffman, William E.; Hajós, Mihály; McDowell, Laura; O’Connor, Rebecca E.; MacDougall-Murphy, Mary; Fonseca, Kari R.; Becker, Stacey L.; Nelson, Frederick; Liras, Spiros

doi:10.1021/jm3009635

Cited by 49 publications

(61 citation statements)

References 32 publications

(47 reference statements)

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“…The remaining PDE families are capable of degrading both substrates. PDE9 inhibitors have been studied for their potential applications to treat diabetes (Deninno et al, 2009;Shao et al, 2014) and central nervous system diseases such as Alzheimer's disease (Wunder et al, 2005;van der Staay et al, 2008;Verhoest et al, 2009Verhoest et al, , 2012Hutson et al, 2011;Vardigan et al, 2011;Claffey et al, 2012;Kleiman et al, 2012;Kroker et al, 2012Kroker et al, , 2014Liddie et al, 2012;Schwam et al, 2014;Singh and Patra, 2014;Heckman et al, 2015;Nagy et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Structural Asymmetry of Phosphodiesterase-9A and a Unique Pocket for Selective Binding of a Potent Enantiomeric Inhibitor

et al. 2015

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Phosphodiesterase-9 (PDE9) inhibitors have been studied as potential therapeutics for treatment of central nervous system diseases and diabetes. Here, we report the discovery of a new category of PDE9 inhibitors by rational design on the basis of the crystal structures. The best compound, (S), has an IC 50 value of 11 nM against PDE9 and the racemic C33 has bioavailability of 56.5% in the rat pharmacokinetic model. The crystal structures of PDE9 in the complex with racemic C33, (R)-C33, and (S)-C33 reveal subtle conformational asymmetry of two M-loops in the PDE9 dimer and different conformations of two C33 enantiomers. The structures also identified a small hydrophobic pocket that interacts with the tyrosyl tail of (S)-C33 but not with (R)-C33, and is thus possibly useful for improvement of selectivity of PDE9 inhibitors. The asymmetry of the M-loop and the different interactions of the C33 enantiomers imply the necessity to consider the whole PDE9 dimer in the design of inhibitors.

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Section: Introductionmentioning

confidence: 99%

Structural Asymmetry of Phosphodiesterase-9A and a Unique Pocket for Selective Binding of a Potent Enantiomeric Inhibitor

et al. 2015

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“…40) and 73 (PDB ID: 4G2L) bound to PDE9A reveal the expected binding modes [166,167], with the pyrazolopyrimidinone core sandwiched between the P clamp residues and forming two HBs with Gln-453. The N1 4-tetrahydropyran (4-THP) substituent interacts with residues in the M pocket and the C6 substituent accesses the Q 2 and S pockets with the pyrrolidine methyl and the pyrimidine, respectively.…”

Section: Pf-04447943 and Related Toolsmentioning

confidence: 99%

“…Pfizer has published several papers describing the discovery of the PDE9A clinical candidate, PF-04447943, 70 (IC 50 ¼ 8.3 nM) [167], related PDE9A inhibitors, PF-04181366 71 (IC 50 ¼ 1.8 nM) [169] and PF-04449613 72 (IC 50 ¼ 14 nM) [166,200], and preclinical PDE9A candidate 73 (IC 50 ¼ 32.4 nM) [166] (Fig. 39).…”

Section: Pf-04447943 and Related Toolsmentioning

confidence: 99%

“…Physiological effects were seen at~5x the PDE9A IC50. Compound 73 has a brain/ plasma ratio of 1.4 and free brain/free plasma and free CSF/free plasma ratios of 1.4, indicating no brain impairment [166]. It has an oral bioavailability of 63% in rat and 71% in dog and was predicted to be 80% bioavailable in human.…”

Section: Pf-04447943 and Related Toolsmentioning

confidence: 99%

“…The basic nitrogen of the azetidines and pyrrolidines are oriented to interact with Tyr-424. An aryl substituent either directly attached or ether-linked to the azetidine or pyrrolidine is found in most of the exemplified compounds, which is oriented to interact with Phe-441 and/or Phe-456 to obtain selectivity over other PDEs, evident in the X-ray crystal structures of 73 and 83 (PDB IDs: 4G2L and 4G2J) [166].…”

Section: Pfizermentioning

confidence: 99%

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The Use of PDE10A and PDE9 Inhibitors for Treating Schizophrenia

Tuttle

Kormos

2014

Small Molecule Therapeutics for Schizophrenia

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Schizophrenia (Scz) is a chronic and debilitating neurological disorder that afflicts approximately 1% of the general population with an increased incidence within families. Signs of this disorder typically appear between the ages of 16-30 although rare cases of childhood (<13) onset exist. Diagnosis of scz requires symptoms that persist for a duration of 1 month over a 6-month time period. The broad spectrum of symptoms are typically split into three categories: positive, negative, and cognitive. Implicit within these categories is the difficulty for stand-alone treatment methods, suggesting a combination of pharmacological and psychological treatment strategies is needed to manage this disease. Furthermore, while current pharmaceuticals are moderately effective at managing positive symptoms, the severe side effects lower patient compliance. Additionally, drugs used to treat negative and cognitive symptoms only have modest benefits, at best. Due to these limitations, there is a clear need for novel pharmaceuticals that modulate dysfunctional neurological pathways in scz patients. As such, both academic and pharmaceutical researchers are focused on identifying enzymes that can attenuate neurological signaling in disease-relevant brain regions. Specifically, this chapter will provide an in-depth review of current drug discovery efforts focused on inhibiting phosphodiesterase 10 and 9 (PDE10A, PDE9A, respectively).

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Morphy¹

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Attrition in the Pharmaceutical Industry

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Application of Structure-Based Drug Design and Parallel Chemistry to Identify Selective, Brain Penetrant, In Vivo Active Phosphodiesterase 9A Inhibitors

Cited by 49 publications

References 32 publications

Structural Asymmetry of Phosphodiesterase-9A and a Unique Pocket for Selective Binding of a Potent Enantiomeric Inhibitor

Structural Asymmetry of Phosphodiesterase-9A and a Unique Pocket for Selective Binding of a Potent Enantiomeric Inhibitor

The Use of PDE10A and PDE9 Inhibitors for Treating Schizophrenia

Medicinal Chemistry Strategies to Prevent Compound Attrition

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