18 research outputs found

    Peptidoleukotriene Antagonists State of the Art

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    Peptidoleukotrienes (LTC4, LTD4, and LTE4) have been proposed as important mediators of asthma. Twenty years of research in the field of peptidoleukotriene (pLT) antagonists have generated a number of biologically active compounds from different structural classes. Several drugs have been or are currently in clinical trials. The first generation peptidoleukotriene antagonists (e.g. FPL 55712) showed disappointing results in asthmatic patients, due to insufficient potency. However, new classes of highly potent antagonists (e.g. ICI 204219) are proving successfull in clinical trials in asthma patients. Thus, peptidoleukotriene antagonists may represent a new principle in asthma therapy. In this paper, the in vitro potency and clinical data of different classes of peptidoleukotriene antagonists are reviewed

    The 7 TM G-protein-coupled receptor target family.

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    Chemical biology approaches have a long history in the exploration of the G-protein-coupled receptor (GPCR) family, which represents the largest and most important group of targets for therapeutics. The analysis of the human genome revealed a significant number of new members with unknown physiological function which are today the focus of many reverse pharmacology drug-discovery programs. As the seven hydrophobic transmembrane segments are a defining common structural feature of these receptors, and as signaling through heterotrimeric G proteins is not demonstrated in all cases, these proteins are also referred to as seven transmembrane (7 TM) or serpentine receptors. This review summarizes important historic milestones of GPCR research, from the beginning, when pharmacology was mainly descriptive, to the age of modern molecular biology, with the cloning of the first receptor and now the availability of the entire human GPCR repertoire at the sequence and protein level. It shows how GPCR-directed drug discovery was initially based on the careful testing of a few specifically made chemical compounds and is today pursued with modern drug-discovery approaches, including combinatorial library design, structural biology, molecular informatics, and advanced screening technologies for the identification of new compounds that activate or inhibit GPCRs specifically. Such compounds, in conjunction with other new technologies, allow us to study the role of receptors in physiology and medicine, and will hopefully result in novel therapies. We also outline how basic research on the signaling and regulatory mechanisms of GPCRs is advancing, leading to the discovery of new GPCR-interacting proteins and thus opening new perspectives for drug development. Practical examples from GPCR expression studies, HTS (high-throughput screening), and the design of monoamine-related GPCR-focused combinatorial libraries illustrate ongoing GPCR chemical biology research. Finally, we outline future progress that may relate today's discoveries to the development of new medicines

    Design of Two New Chemotypes for Inhibiting the Janus Kinase 2 by Scaffold Morphing

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    JAK2 is a target of high interest in chronic myeloproliferative disorders drug research. Starting from a screening hit, two new JAK2 inhibitor chemotypes were designed by scaffold morphing. The prototype compounds of these new series showed nanomolar inhibition of the kinase

    The 7TM G-Protein-Coupled Receptor Target Family

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    Chemical biology approaches have a long history in the exploration of the G-protein-coupled receptor (GPCR) family, which represents the largest and most important group of targets for therapeutics. The analysis of the human genome revealed a significant number of new members with unknown physiological function which are today the focus of many reverse pharmacology drug-discovery programs. As the seven hydrophobic transmembrane segments are a defining common structural feature of these receptors, and as signaling through heterotrimeric G proteins is not demonstrated in all cases, these proteins are also referred to as seven transmembrane (7 TM) or serpentine receptors. This review summarizes important historic milestones of GPCR research, from the beginning, when pharmacology was mainly descriptive, to the age of modern molecular biology, with the cloning of the first receptor and now the availability of the entire human GPCR repertoire at the sequence and protein level. It shows how GPCR-directed drug discovery was initially based on the careful testing of a few specifically made chemical compounds and is today pursued with modern drug-discovery approaches, including combinatorial library design, structural biology, molecular informatics, and advanced screening technologies for the identification of new compounds that activate or inhibit GPCRs specifically. Such compounds, in conjunction with other new technologies, allow us to study the role of receptors in physiology and medicine, and will hopefully result in novel therapies. We also outline how basic research on the signaling and regulatory mechanisms of GPCRs is advancing, leading to the discovery of new GPCR-interacting proteins and thus opening new perspectives for drug development. Practical examples from GPCR expression studies, HTS (high-throughput screening), and the design of monoamine-related GPCR-focused combinatorial libraries illustrate ongoing GPCR chemical biology research. Finally, we outline future progress that may relate today's discoveries to the development of new medicines

    Discovery of a Novel Tricyclic 4H-Thiazolo[5',4':4,5]pyrano[2,3-c]pyridine-2-amino Scaffold and its Application in a PI3K Inhibitor with High PI3K Isoform Selectivity and Potent Cellular Activity

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    A novel, previously undescribed 4H-thiazolo[5',4':4,5]pyrano[2,3-c]pyridine tricyclic scaffold has been discovered. The application of this novel chemotype leading to a potent and selective prototype PI3K inhibitor is described

    Discovery and SAR of potent, orally available and brain-penetrable 5,6-dihydro-4H-3-thia-1-aza-benzo[e]azulen- and 4,5-dihydro-6-oxa-3-thia-1-aza-benzo[e]azulen derivatives as neuropeptide Y Y5 receptor antagonists.

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    Combination of structural elements from a potent Y5 antagonist (2) with thiazole fragments that exhibit weak Y5 affinities followed by lead optimisation led to the discovery of (5,6-dihydro-4H-3-thia-1-aza-benzo[e]azulen-2-yl)-piperidin-4-ylmethyl-amino and (4,5-dihydro-6-oxa-3-thia-1-aza-benzo[e]azulen-2-yl)-piperidin-4-ylmethyl-amino derivatives. Both classes of compounds are capable of delivering potent and selective orally and centrally bioavailable NPY Y5 receptor antagonists

    Identification and optimisation of a 4',5-bisthiazole series of selective phosphatidylinositol-3 kinase alpha inhibitors

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    Abstract: Exploring the affinity-pocket binding moiety of a 2-aminothiazole (S)-proline-amide-urea series of selective PI3Kα inhibitors using a parallel-synthesis approach led to the identification of a novel 4',5-bisthiazole sub-series. The synthesis and optimisation of both the affinity pocket and (S)-proline amide moieties within this 4',5-bisthiazole sub-series are described. From this work a number of analogues, including 14 (A66) and 24, were identified as potent and selective PI3Kα inhibitor in vitro tool compounds

    Penta-Substituted Benzimidazoles as Potent Antagonists of the Calcium Sensing Receptor (CaSR-Antagonists)

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    A series of novel benzimidazole derivatives has been designed via a scaffold morphing approach based on known calcilytics chemotypes. Subsequent lead optimisation led to the discovery of penta-substituted benzimidazoles that exhibit attractive in vitro and in vivo calcium sensing receptor (CaSR) inhibitory profiles. In addition, synthesis and structure activity relationship data are provided

    2-Amino-aryl-7-aryl-benzoxazoles as Potent, Selective and Orally Available JAK2 Inhibitors

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    A series of novel benzoxazole derivatives has been designed and shown to exhibit attractive JAK2 inhibitory profiles in biochemical and cellular assays, capable of delivering compounds with favorable PK properties in rats. Synthesis and structure activity relationship data are also provided
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