A broad screening program previously identified phenprocoumon (1) as a small molecule template for inhibition of HIV protease. Subsequent modification of this lead through iterative cycles of structure-based design led to the activity enhancements of pyrone and dihydropyrone ring systems (II and V) and amide-based substitution (III). Incorporation of sulfonamide substitution within the dihydropyrone template provided a series of highly potent HIV protease inhibitors, with structure-activity relationships described in this paper. Crystallographic studies provided further information on important binding interactions responsible for high enzymatic binding. These studies culminated in compound VI, which inhibits HIV protease with a Ki value of 8 pM and shows an IC90 value of 100 nM in antiviral cell culture. Clinical trials of this compound (PNU-140690, Tipranavir) for treatment of HIV infection are currently underway.
Neuraminidase is one of the two glycoprotein spikes protruding from the influenza virus membrane. We have determined by X-ray crystallography the native structure of B/Lee/40 neuraminidase (NA) and the structures of its crystals soaked with a substrate, N-acetylneuraminyllactose (NANL), and an inhibitor, 2-deoxy-2,3-didehydro-N-acetylneuraminic acid (DANA) at 1.8-A resolution. NANL was hydrolyzed by the crystalline NA to generate the product N-acetylneuraminic acid (NANA, also known as sialic acid), which is still able to bind to NA. In the difference Fourier map of the presumed NA-NANA complex, the moiety bound in the active site had a distorted boat conformation of NANA, but there is no significant electron density for O2. The structure of the bound moiety is not identical to that of chemically synthesized DANA soaked into NA crystals. Prolonged incubation of NANA with NA in solution at room temperature produced only a trace amount of DANA as detected by NMR. On the basis of our studies, a mechanism is proposed for the enzymatic hydrolysis by influenza virus neuraminidase.
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