M. Khayat, A. Omar, M. Elfaky, Yosra A. Muhammad, Elaf A. Felemban, K. El-Say, M. El‐Araby
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引用次数: 0
Abstract
Chronic Hepatitis C is a global health threat and a silent killer. Regardless of the profound progress in preventing and treating this disease, research continues to discover new direct antiviral agents (DAAs), especially against novel targets. Our research has been directed to leverage the NS4A binding site to develop peptidomimetic inhibitors of the hepatitis C virus (HCV) NS3 protease. In previous reports, we could provide evidence of tunability of this site by peptide and nonpeptide NS3/4A inhibitors. In this report, we used structure-based techniques to design 1,2,3,4-tetrahydro-1,7-naphthyridine derivative as NS4A core mimics that cover the region between residues Ile-25′ to Arg-28′. The synthetic plan featured the Povarov reaction as an efficient strategy to construct the 1,7-naphthyridine core. Although this reaction has been reported in many literatures, critical assessments for its scope and limitations are scarce. In our work, we found that Povarov was extremely sensitive to alkene and aldehyde reactants. Moreover, using pyridine amines was not as successful as anilines. The most striking results were the lack of stability of compounds during purification and storage. The four compounds that survived the stability problems (1a-1d) did not show significant binding potency with NS3, because their structures were too simple to resemble the originally planned compounds.
期刊介绍:
Heteroatom Chemistry brings together a broad, interdisciplinary group of chemists who work with compounds containing main-group elements of groups 13 through 17 of the Periodic Table, and certain other related elements. The fundamental reactivity under investigation should, in all cases, be concentrated about the heteroatoms. It does not matter whether the compounds being studied are acyclic or cyclic; saturated or unsaturated; monomeric, polymeric or solid state in nature; inorganic, organic, or naturally occurring, so long as the heteroatom is playing an essential role. Computational, experimental, and combined studies are equally welcome.
Subject areas include (but are by no means limited to):
-Reactivity about heteroatoms for accessing new products or synthetic pathways
-Unusual valency main-group element compounds and their properties
-Highly strained (e.g. bridged) main-group element compounds and their properties
-Photochemical or thermal cleavage of heteroatom bonds and the resulting reactivity
-Uncommon and structurally interesting heteroatom-containing species (including those containing multiple bonds and catenation)
-Stereochemistry of compounds due to the presence of heteroatoms
-Neighboring group effects of heteroatoms on the properties of compounds
-Main-group element compounds as analogues of transition metal compounds
-Variations and new results from established and named reactions (including Wittig, Kabachnik–Fields, Pudovik, Arbuzov, Hirao, and Mitsunobu)
-Catalysis and green syntheses enabled by heteroatoms and their chemistry
-Applications of compounds where the heteroatom plays a critical role.
In addition to original research articles on heteroatom chemistry, the journal welcomes focused review articles that examine the state of the art, identify emerging trends, and suggest future directions for developing fields.
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