RESUMEN
The NLRP3 inflammasome plays an important role in the defense mechanism of the innate immune system and has recently attracted much attention as a drug target for various inflammatory disorders. Among the strategies for generating the novel chemotype in current drug discovery, scaffold hopping and bioisosteric replacement are known to be attractive approaches. As the results of our medicinal chemistry campaign, which involved exploration of core motifs using a ring closing approach, a five-membered oxazole-based scaffold was identified, and subsequent implementation of bioisosteric replacement led to discovery of a novel chemical class of NLRP3 inflammasome inhibitor bearing the acylsulfamide group. Further optimization of aniline and sulfamide moieties to improve potency in human whole blood assay led to the identification of the orally bioactive compound 32 in the LPS challenge model. Furthermore, compound 32 attenuated kidney injury in adriamycin-induced glomerulonephritis in mice. These investigations indicated that the NLRP3 inhibitor could be a potential therapeutic agent for glomerulonephritis.
RESUMEN
Stereocontrolled access to the hexacyclic core of FD-594 has been achieved. The key steps include the intramolecular S(N)Ar reaction for construction of the densely functionalized xanthone skeleton, the stereoselective lactone cleavage using a chiral nucleophile to induce the axial stereochemistry, and the SmI(2)-mediated pinacol cyclization for the stereocontrolled conversion of axially chiral biaryl dialdehyde into the corresponding trans diol.
Asunto(s)
Antibióticos Antineoplásicos/síntesis química , Lactonas/síntesis química , Piranos/síntesis química , Xantenos/síntesis química , Antibióticos Antineoplásicos/química , Lactonas/química , Piranos/química , Estereoisomerismo , Streptomyces/química , Streptomyces/metabolismo , Xantenos/químicaRESUMEN
A solvent-controlled inversion of leaving group ability allows selective access to either of two internal substitution products in S(N)Ar reactions of substrates with competing leaving groups. Application of this principle in a selective synthesis of the highly functionalized xanthone core of the antibiotic FD-594 is presented.