An alternate binding site for the P1-P3 group of a class of potent HIV-1 protease inhibitors as a result of concerted structural change in the 80s loop of the protease.

Structures of the complexes of HIV protease inhibitor L--756,423 with the HIV-1 wild-type protease and of the inhibitors Indinavir, L-739,622 and Saquinavir with the mutant protease (9X) containing nine point mutations (Leu10Val, Lys20Met, Leu24Ile, Ser37Asp, Met46Ile, Ile54Val, Leu63Pro, Ala71Val, Val82Thr) have been determined. Comparative analysis of these structures reveals an alternate binding pocket for the P1-P3 group of Indinavir and L--756, 423. The alternate binding pocket is a result of concerted structural change in the 80s loop (residues 79-82) of the protease. The 80s loop is pulled away from the active site in order to accommodate the P1-P3 group, which is sandwiched between the flap and the 80s loop. This structural change is observed for the complexes of the wild type as well as the 9X mutant protease. The study reveals that the 80s loop is an intrinsically flexible loop in the wild-type HIV-1 protease and that mutations in this loop are not necessary to result in conformational changes. Conformation of this loop in the complex depends primarily upon the nature of the bound inhibitor and may be influenced by mutations in the protease. The results underscore the need to understand the intrinsic structural plasticity of the protease for the design of effective inhibitors against the wild-type and drug-resistant enzyme forms. In addition, the alternate binding pocket for the P1-P3 group of Indinavir and L--756,423 may be exploited for the design of potent inhibitors.

Plasmid DNA vaccines: assay for integration into host genomic DNA.

The primary safety concern for DNA vaccines is their potential to integrate into host cellular DNA. We describe a sensitive and quantitative assay for investigating the tissue distribution and integration of plasmid DNA vaccines. By including gonadal tissues in the analysis, the potential for germline transmission is also assessed. At various time points after injection, total DNA is isolated from a variety of tissues and assayed by PCR for the presence of plasmid. To test for integration, genomic DNA is first purified away from free plasmid using a series of different gel electrophoresis procedures. The gel-purified genomic DNA is then assayed for integrated plasmid using PCR. Stringent methods are used to prevent contamination. The assay, validated using a variety of positive and negative controls, is capable of detecting one copy of plasmid per ug DNA (approximately 150,000 diploid cells). Using this assay, we have carried out intramuscular studies in mice or guinea pigs for four different DNA vaccine plasmids. There was no evidence of integration to a sensitivity of about one copy/microg DNA, which is at least three orders of magnitude below the spontaneous mutation frequency.

Non-active site changes elicit broad-based cross-resistance of the HIV-1 protease to inhibitors.

Three high level, cross-resistant variants of the HIV-1 protease have been analyzed for their ability to bind four protease inhibitors approved by the Food and Drug Administration (saquinavir, ritonavir, indinavir, and nelfinavir) as AIDS therapeutics. The loss in binding energy (DeltaDeltaG(b)) going from the wild-type enzyme to mutant enzymes ranges from 2.5 to 4.4 kcal/mol, 40-65% of which is attributed to amino acid substitutions away from the active site of the protease and not in direct contact with the inhibitor. The data suggest that non-active site changes are collectively a major contributor toward engendering resistance against the protease inhibitor and cannot be ignored when considering cross-resistance issues of drugs against the HIV-1 protease.

Mutational anatomy of an HIV-1 protease variant conferring cross-resistance to protease inhibitors in clinical trials. Compensatory modulations of binding and activity.

Site-specific substitutions of as few as four amino acids (M46I/L63P/V82T/I84V) of the human immunodeficiency virus type 1 (HIV-1) protease engenders cross-resistance to a panel of protease inhibitors that are either in clinical trials or have recently been approved for HIV therapy (Condra, J. H., Schleif, W. A., Blahy, O. M. , Gadryelski, L. J., Graham, D. J., Quintero, J. C., Rhodes, A., Robbins, H. L., Roth, E., Shivaprakash, M., Titus, D., Yang, T., Teppler, H., Squires, K. E., Deutsch, P. J., and Emini, E. A. (1995) Nature 374, 569-571). These four substitutions are among the prominent mutations found in primary HIV isolates obtained from patients undergoing therapy with several protease inhibitors. Two of these mutations (V82T/I84V) are located in, while the other two (M46I/L63P) are away from, the binding cleft of the enzyme. The functional role of these mutations has now been delineated in terms of their influence on the binding affinity and catalytic efficiency of the protease. We have found that the double substitutions of M46I and L63P do not affect binding but instead endow the enzyme with a catalytic efficiency significantly exceeding (110-360%) that of the wild-type enzyme. In contrast, the double substitutions of V82T and I84V are detrimental to the ability of the protease to bind and, thereby, to catalyze. When combined, the four amino acid replacements institute in the protease resistance against inhibitors and a significantly higher catalytic activity than one containing only mutations in its active site. The results suggest that in raising drug resistance, these four site-specific mutations of the protease are compensatory in function; those in the active site diminish equilibrium binding (by increasing Ki), and those away from the active site enhance catalysis (by increasing kcat/KM). This conclusion is further supported by energy estimates in that the Gibbs free energies of binding and catalysis for the quadruple mutant are quantitatively dictated by those of the double mutants.

Three-dimensional structure of a mutant HIV-1 protease displaying cross-resistance to all protease inhibitors in clinical trials.

Analysis of mutational effects in the human immunodeficiency virus type-1 (HIV-1) provirus has revealed that as few as four amino acid side-chain substitutions in the HIV-1 protease (M46I/L63P/V82T/I84V) suffice to yield viral variants cross-resistant to a panel of protease inhibitors either in or being considered for clinical trials (Condra, J. H., Schleif, W. A., Blahy, O. M., Gadryelski, L. J., Graham, D. J., Quintero, J. C., Rhodes, A., Robbins, H. L., Roth, E., Shivaprakash, M., Titus, D., Yang, T., Teppler, H., Squires, K. E., Deutsch, P. J., and Emini, E. A. (1995) Nature 374, 569-571). As an initial effort toward elucidation of the molecular mechanism of drug resistance in AIDS therapies, the three-dimensional structure of the HIV-1 protease mutant containing the four substitutions has been determined to 2.4-A resolution with an R factor of 17.1%. The structure of its complex with MK639, a protease inhibitor of the hydroxyaminopentane amide class of peptidomimetics currently in Phase III clinical trials, has been resolved at 2.0 A with an R factor of 17.0%. These structures are compared with those of the wild-type enzyme and its complex with MK639 (Chen, Z., Li, Y., Chen, E., Hall, D. L., Darke, P. L., Culberson, C., Shafer, J., and Kuo, L. C. (1994) J. Biol. Chem. 269, 26344-26348). There is no gross structural alteration of the protease due to the site-specific mutations. The C alpha tracings of the two native structures are identical with a root-mean-square deviation of 0.5 A, and the four substituted side chains are clearly revealed in the electron density map. In the MK639-bound form, the V82T substitution introduces an unfavorable hydrophilic moiety for binding in the active site and the I84V substitution creates a cavity (unoccupied by water) that should lead to a decrease in van der Waals contacts with the inhibitor. These changes are consistent with the observed 70-fold increase in the Ki value (approximately 2.5 kcal/mol) for MK639 as a result of the mutations in the HIV-1 protease. The role of the M46I and L63P substitutions in drug resistance is not obvious from the crystallographic data, but they induce conformational perturbations (0.9-1.1 A) in the flap domain of the native enzyme and may affect the stability and/or activity of the enzyme unrelated directly to binding.