Pateamine A (PatA), a marine metabolite from Mycale sp., is a potent inhibitor of the intracellular signal transduction pathway emanating from the T-cell receptor leading to the transcription of cytokines such as interleukin-2 (IL-2). On the basis of the structure of PatA and initial biological results, a hypothesis was developed regarding the presence of distinct binding and scaffolding domains in the PatA structure with respect to interactions with its putative cellular receptor(s). Employing a highly convergent approach involving a Hantzsch coupling strategy, we probed this hypothesis by preparing a simplified PatA derivative (desmethyl, desamino PatA, DMDAPatA, 3). This derivative was prepared in 10 fewer synthetic steps relative to PatA and was indeed found to exhibit equal to greater potency (IC50 0.81 +/- 0.27 nM) in inhibition of IL-2 production relative to PatA (IC50 4.01 +/- 0.94 nM) thus providing support for the binding/scaffolding domain hypothesis. In addition, as a means to find more stable derivatives and gain further insights into structure-activity relationships, several PatA derivatives were synthesized and assayed in the IL-2 reporter gene assay. Several of these derivatives displayed lower potency but marked stability relative to the natural product and provide further insights into the nature of the binding domain required for activity.
Potent covalent inhibitors of Bruton's tyrosine kinase (BTK) based on an aminopyrazole carboxamide scaffold have been identified. Compared to acrylamide-based covalent reactive groups leading to irreversible protein adducts, cyanamide-based reversible-covalent inhibitors provided the highest combined BTK potency and EGFR selectivity. The cyanamide covalent mechanism with BTK was confirmed through enzyme kinetic, NMR, MS, and X-ray crystallographic studies. The lead cyanamide-based inhibitors demonstrated excellent kinome selectivity and rat pharmacokinetic properties.
A series of 8-hydroxy quinolines were identified as potent inhibitors of catechol O-methyltransferase (COMT) with selectivity for the membrane-bound form of the enzyme. Small substituents at the 7-position of the quinoline were found to increase metabolic stability without sacrificing potency. Compounds with good pharmacokinetics and brain penetration were identified and demonstrated in vivo modulation of dopamine metabolites in the brain. An X-ray co-crystal structure of compound 21 in the S-COMT active site shows chelation of the active site magnesium similar to catechol-based inhibitors. These compounds should prove useful for treatment of many neurological and psychiatric conditions associated with compromised cortical dopamine signaling.
Cognitive impairment is a primary feature of many neuropsychiatric disorders and there is a need for new therapeutic options. Catechol-O-methyltransferase (COMT) inhibitors modulate cortical dopaminergic function and have been proposed as potential cognitive enhancers. Unfortunately, currently available COMT inhibitors are not good candidates due to either poor blood-brain barrier penetration or severe toxicity. To address the need for safe, brain-penetrant COMT inhibitors, we tested multiple novel COMT inhibitors in a set of preclinical in vivo efficacy assays to determine their viability as potential clinical candidates. We found that multiple COMT inhibitors, exemplified by LIBD-1 and LIBD-3, significantly modulated dopaminergic function measured as decreases in homovanillic acid (HVA) and increases in 3,4-Dihydroxyphenylacetic acid (DOPAC), two dopamine metabolites, in cerebrospinal fluid (CSF) and the frontal cortex. Additionally, we found the LIBD-1 significantly improved cognitive flexibility in a rat attentional set-shifting assay (ASST), an effect previously seen with the COMT inhibitor tolcapone. These results demonstrate that LIBD-1 is a novel COMT inhibitor with promising in vivo activity and the potential to serve as a new therapy for cognitive impairment.
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