Structure-activity relationships for a series of thiobenzamide influenza fusion inhibitors derived from 1,3,3-trimethyl-5-hydroxy-cyclohexylmethylamine.

The anti-influenza activity of a series of thiobenzamide fusion inhibitors derived from 1,3,3-trimethyl-5-hydroxy-cyclohexylmethylamine is profiled. Axial disposition of the thioamide moiety is essential for potent influenza inhibitory activity.

An approach to the identification of potent inhibitors of influenza virus fusion using parallel synthesis methodology.

Structure-activity studies associated with the salicylic acid-derived inhibitor of influenza fusion, BMY-27709, were examined using a parallel synthesis approach. This SAR survey led to the discovery of potent influenza inhibitory activity in a series of aromatic amides and thioamides derived from 1,3,3-trimethyl-5-hydroxycyclohexylmethylamine. Select compounds were characterized as inhibitors of the H1 subtype of influenza A viruses that act by preventing the pH-induced fusion process, thereby blocking viral entry into host cells.

Salicylamide inhibitors of influenza virus fusion.

Structural variation of the quinolizidine heterocycle of the influenza fusion inhibitor BMY-27709 was examined by several topological dissections in order to illuminate the critical features of the ring system. This exercise resulted in the identification of a series of synthetically more accessible decahydroquinolines that retained the structural elements of BMY-27709 important for antiviral activity. The 2-methyl-cis-decahydroquinoline 6f was the most potent influenza inhibitor identified that demonstrated an EC50 of 90 ng/mL in a plaque reduction assay.

Novel quinolizidine salicylamide influenza fusion inhibitors.

A novel series of quinolizidine salicylamides was synthesized as specific inhibitors of the H1 subtype of influenza A viruses. These inhibitors inhibit the pH-induced fusion process, thereby blocking viral entry into host cells. Compound 16 was the most active inhibitor in this series with an EC50 of 0.

Inhibition of influenza viral polymerases by minimal viral RNA decoys.

All gene segments of influenza virus share a common feature at their respective termini. Both the 5'- and 3'-terminal sequences are highly conserved and possess partial inverted complementarity. This allows for the formation of a double-stranded duplex, which plays a major role in transcription, replication and packaging of the viral genome.