The enzyme has an S1 specificity pocket similar to that of trypsin, a restricted, less accessible, hydrophobic S2 pocket and a solvent-accessible S3 pocket which is capable of accommodating a wide range of residues. The EGRcmk inhibitor binds covalently at the active site to form a tetrahedral hemiketal structure. Although the overall structure is similar to that of homologous serine proteases, at six positions insertions of extra residues in loop regions create unique surface areas. One of these loop regions is highly mobile despite being anchored by the disulphide bridge which is characteristic of a small subset of serine proteases namely tissuetype plasminogen activator, Factor XII and Complement Factor I.
In a previous communication, our efforts leading from 1 to the identification of spiro [cyclohexanedihydropyrano[3,4-b]indole]-amine 2a as analgesic NOP and opioid receptor agonist were disclosed and their favorable in vitro and in vivo pharmacological properties revealed. We herein report our efforts to further optimize lead 2a, toward trans-6′-, which is currently in clinical development for the treatment of severe chronic nociceptive and neuropathic pain. KEYWORDS: NOP receptor agonists, MOP receptor agonists, cebranopadol, analgesics R ecent publications indicate that small molecules activating both nociceptin/orphanin FQ peptide (NOP) and mu opioid peptide (MOP) receptors may potentiate opiate analgesia and at the same time display an improved side effects profile. 1,2 We have recently reported the discovery of a series of small molecules, characterized by their high NOP and opioid receptor agonistic activity. 3 This series included uncyclized (e.g., 1) as well as spirocyclic examples (e.g., 2a). The discovery of spirocyclic 2a originated from the respective uncyclized analogues, which were potent NOP and MOP receptor binders but sometimes hampered by only partial agonistic NOP and MOP receptor activity. In particular, the spiroindole derivates sparked our interest due to their structural novelty and favorable in vitro and in vivo properties. The leading spiroether 2a exhibited strong efficacy in preclinical models of acute (ED 50 rat tail-flick: 3.63 nmol/kg i.v.) and neuropathic pain (ED 50 rat spinal nerve ligation: 1.05 nmol/kg i.v.) but was hampered by poor pharmacokinetic (PK) properties in rats with high clearance, large volume of distribution, moderate half-life (Cl = 4.0 L/h·kg; V ss = 7.52 L/kg; t 1/2 = 1.6 h), and a critically very low oral bioavailability (F = 4%).We herein report our efforts to further optimize the spiroindole lead 2a, which eventually led to the discovery of trans-6′-fluoro-4′,9′-dihydro-N,N-dimethyl-4-phenyl-spiro-[cyclohexane-1,1′(3′H)-pyrano [3,4-b]indol]-4-amine (3a, cebranopadol), a novel potent analgesic NOP and opioid receptor agonist, currently in clinical development for the treatment of severe chronic nociceptive and neuropathic pain.The structure−activity relationship (SAR) established around the uncyclized scaffolds (e.g., 1) suggested that a broad variety of linkers such as alcohols, ethers, and amines are tolerated, showing high NOP and MOP receptor binding affinities. 3 As a result, we applied this knowledge through analogous structural variations to lead structure 2a (region A, Figure 1). These changes were also combined with a targeted approach to improve the poor PK profile, in particular by addressing metabolically liable regions B and C.With this in mind, the transformation of the oxacyclic spiro moiety into a carba-, aza-, or thio-cyclic moiety was investigated. Advancing from the oxacyclic spiro 2a to the azacyclic moiety 5a led to equally potent NOP and MOP receptor binders, as well as the introduction of the N-methyl subunit 6a. Similarly, pot...
The synthesis, biological activity, and molecular modeling of a novel series of substituted 1-(3-pyridylcarbamoyl)indolines are reported. These compounds are isosteres of the previously published indole urea 1 (SB-206553) and illustrate the use of aromatic disubstitution as a replacement for fused five-membered rings in the context of 5-HT2C/2B receptor antagonists. By targeting a region of space previously identified as sterically allowed at the 5-HT2C receptor but disallowed at the 5-HT2A receptor, we have identified a number of compounds which are the most potent and selective 5-HT2C/2B receptor antagonists yet reported. 46 (SB-221284) was selected on the basis of its overall biological profile for further evaluation as a novel, potential nonsedating anxiolytic agent. A CoMFA analysis of these compounds produced a model with good predictive value and in addition good qualitative agreement with both our 5-HT2C receptor model and our proposed binding mode for this class of ligands within that model.
The expression of specific membrane receptors for C3a was determined on guinea pig C3a-sensitive (gp R+) platelets and human polymorphonuclear leukocytes (hu PMNL). Binding studies with 125I-labeled C3a from gp or hu sources and Scatchard analysis applied to the binding data revealed the existence of two receptor classes on gp R+ platelets; a high-affinity class with about 200 binding sites/cell and Kd = 1.7 x 10(-9) M, and a relatively low-affinity class with Kd = 10(-8) M and about 500 sites/cell. Hu PMNL express a homogeneous receptor class with Kd = 3 x 10(-8) M and 40,000 sites/cell. Molecular characterization of the C3a receptor on gp R+ platelets was achieved by (a) cross-linking photoaffinity-labeled receptors to bound 125I-labeled C3a; (b) photoaffinity labeling receptors with a 13-amino acid residue C3a analogue 125I-Nap-Ahx-13; and (c) use of chemical cross-linkers like disuccinimidylsuberate to cross-link receptors with 125I-C3a. All three techniques gave rise to very similar labeling patterns. With the photoaffinity labeling methods, a diffuse band pattern was observed with an apparent molecular mass of 95-123 kDa with 125I-C3a as label, and 85-105 kDa with 125I-Nap-Ahx-13 as label. Chemical cross-linking of 125I-C3a revealed three distinct bands with molecular masses of approximately 123, 108 and 95 kDa. Subtracting the contribution of the cross-linked ligands, the C3a receptor on gp R+ platelets appears to be a protein complex, consisting of one to three components with estimated molecular masses between 83-114 kDa.
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