Synthesis, stability, antiviral activity, and protease-bound structures of substrate-mimicking constrained macrocyclic inhibitors of HIV-1 protease.Tyndall, J.D., Reid, R.C., Tyssen, D.P., Jardine, D.K., Todd, B., Passmore, M., March, D.R., Pattenden, L.K., Bergman, D.A., Alewood, D., Hu, S.H., Alewood, P.F., Birch, C.J., Martin, J.L., Fairlie, D.P.
(2000) J Med Chem 43: 3495-3504
- PubMed: 11000004
- DOI: 10.1021/jm000013n
- Primary Citation of Related Structures:
- PubMed Abstract:
- Molecular Recognition of Macrocyclic Peptidomimetic Inhibitors by HIV-1 Protease.
Martin, J.L., Begun, J., Schindeler, A., Wickramasinghe, W.A., Alewood, D., Alewood, P.F., Bergman, D.A., Brinkworth, R.I., Abbenante, G., March, D.R., Reid, R.C., Fairlie, D.P.
(1999) Biochemistry 38: 7978
- Substrate-Based Cyclic Peptidomimetics Of Phe Ile Val That Inhibit HIV-1 Protease Using a Novel Enzyme Binding Mode
March, D.R., Abbenante, G., Bergman, D., Brinkworth, R.I., Wickramasinghe, W., Begun, J., Martin, J.L., Fairlie, D.P.
(1996) J Am Chem Soc 118: 3375
- Regioselective Structural and Functional Mimicry Of Peptides: Design Of Hydrolytically Stable Cyclic Peptidomimetic Inhibitors Of HIV-1 Protease.
Abbenante, G., March, D., Bergman, D., Hunt, P.A., Garnham, B., Dancer, R.J., Martin, J.L., Fairlie, D.P.
(1995) J Am Chem Soc 117: 10220
Three new peptidomimetics (1-3) have been developed with highly stable and conformationally constrained macrocyclic components that replace tripeptide segments of protease substrates. Each compound inhibits both HIV-1 protease and viral replication (HIV-1, HIV-2) at nanomolar concentrations without cytotoxicity to uninfected cells below 10 microM ...
Three new peptidomimetics (1-3) have been developed with highly stable and conformationally constrained macrocyclic components that replace tripeptide segments of protease substrates. Each compound inhibits both HIV-1 protease and viral replication (HIV-1, HIV-2) at nanomolar concentrations without cytotoxicity to uninfected cells below 10 microM. Their activities against HIV-1 protease (K(i) 1.7 nM (1), 0.6 nM (2), 0.3 nM (3)) are 1-2 orders of magnitude greater than their antiviral potencies against HIV-1-infected primary peripheral blood mononuclear cells (IC(50) 45 nM (1), 56 nM (2), 95 nM (3)) or HIV-1-infected MT2 cells (IC(50) 90 nM (1), 60 nM (2)), suggesting suboptimal cellular uptake. However their antiviral potencies are similar to those of indinavir and amprenavir under identical conditions. There were significant differences in their capacities to inhibit the replication of HIV-1 and HIV-2 in infected MT2 cells, 1 being ineffective against HIV-2 while 2 was equally effective against both virus types. Evidence is presented that 1 and 2 inhibit cleavage of the HIV-1 structural protein precursor Pr55(gag) to p24 in virions derived from chronically infected cells, consistent with inhibition of the viral protease in cells. Crystal structures refined to 1.75 A (1) and 1.85 A (2) for two of the macrocyclic inhibitors bound to HIV-1 protease establish structural mimicry of the tripeptides that the cycles were designed to imitate. Structural comparisons between protease-bound macrocyclic inhibitors, VX478 (amprenavir), and L-735,524 (indinavir) show that their common acyclic components share the same space in the active site of the enzyme and make identical interactions with enzyme residues. This substrate-mimicking minimalist approach to drug design could have benefits in the context of viral resistance, since mutations which induce inhibitor resistance may also be those which prevent substrate processing.
Centre for Drug Design and Development, The University of Queensland, Brisbane, Queensland 4072, Australia.