Probing the S1/S1' substrate binding pocket geometry of HIV-1 protease with modified aspartic acid analogues.

Aspartates 25 and 125, the active site residues of HIV-1 protease, participate functionally in proteolysis by what is believed to be a general acid-general base mechanism. However, the structural role that these residues may play in the formation and maintenance of the neighboring S1/S1' substrate binding pockets remains largely unstudied. Because the active site aspartic acids are essential for catalysis, alteration of these residues to any other naturally occurring amino acid by conventional site-directed mutagenesis renders the protease inactive, and hence impossible to characterize functionally. To investigate whether Asp-25 and Asp-125 may also play a structural role that influences substrate processing, a series of active site protease mutants has been produced in a cell-free protein synthesizing system via readthrough of mRNA nonsense (UAG) codons by chemically misacylated suppressor tRNAs. The suppressor tRNAs were activated with the unnatural aspartic acid analogues erythro-beta-methylaspartic acid, threo-beta-methylaspartic acid, or beta,beta-dimethylaspartic acid. On the basis of the specific activity measurements of the mutants that were produced, the introduction of the beta-methyl moiety was found to alter protease function to varying extents depending upon its orientation. While a beta-methyl group in the erythro orientation was the least deleterious to the specific activity of the protease, a beta-methyl group in the threo orientation, present in the modified proteins containing threo-beta-methylaspartate and beta,beta-dimethylaspartate, resulted in specific activities between 0 and 45% of that of the wild type depending upon the substrate and the substituted active site position. Titration studies of pH versus specific activity and inactivation studies, using an aspartyl protease specific suicide inhibitor, demonstrated that the mutant proteases maintained bell-shaped pH profiles, as well as suicide-inhibitor susceptibilities that are characteristic of aspartyl proteases. A molecular dynamics simulation of the beta-substituted aspartates in position 25 of HIV-1 protease indicated that the threo-beta-methyl moiety may partially obstruct the adjacent S1' binding pocket, and also cause reorganization within the pocket, especially with regard to residues Val-82 and Ile-84. This finding, in conjunction with the biochemical studies, suggests that the active site aspartate residues are in proximity to the S1/S1' binding pocket and may be spatially influenced by the residues presented in these pockets upon substrate binding. It thus seems possible that the catalytic residues cooperatively interact with the residues that constitute the S1/S1' binding pockets and can be repositioned during substrate binding to orient the active site carboxylates with respect to the scissile amide bond, a process that likely affects the facility of proteolysis.

Effects of release factor 1 on in vitro protein translation and the elaboration of proteins containing unnatural amino acids.

An in vitro protein synthesizing system was modified to facilitate the improved, site-specific incorporation of unnatural amino acids into proteins via readthrough of mRNA nonsense (UAG) codons by chemically misacylated suppressor tRNAs. The modified system included an S-30 extract derived from Escherichia coli that expresses a temperature-sensitive variant of E. coli release factor 1 (RF1). Mild heat treatment of the S-30 extract partially deactivated RF1 and improved UAG codon readthrough by as much as 11-fold, as demonstrated by the incorporation of unnatural amino acids into positions 25 and 125 of HIV-1 protease and positions 10 and 22 of E. coli dihydrofolate reductase. The increases in yields were the greatest for those amino acids normally incorporated poorly in the in vitro protein synthesizing system, thus significantly enhancing the repertoire of modified amino acids that can be incorporated into the proteins of interest. The substantial increase in mutant protein yields over those obtained with an S-30 extract derived from an RF1 proficient E. coli strain is proposed to result from a relaxed stringency of termination by RF1 at the stop codon (UAG). When RF1 levels were depleted further, the intrinsic rate of DHFR synthesis increased, consistent with the possibility that RF1 competes not only at stop codons but also at other mRNA codons during peptide elongation. It thus seems possible that in addition to its currently accepted role as a protein factor involved in peptide termination, RF1 is also involved in functions that control the rate at which protein synthesis proceeds.

Effects of camptothecin analogues on DNA transformations mediated by calf thymus and human DNA topoisomerases I.

Camptothecin (CPT) and 10 structural analogues were studied to characterize their effects on specific rearrangements of DNA structure mediated by human and calf thymus DNA topoisomerases I. A 30 base pair DNA duplex containing a single high-efficiency topoisomerase cleavage site was incubated with each of the enzymes in the presence of the inhibitors. Individual inhibitors stabilized the covalent enzyme-DNA binary complex to different extents, as anticipated. However, for several of the inhibitors, the extent of ternary complex formation differed substantially for the human and calf thymus enzymes. In common with calf thymus topoisomerase I, the human enzyme was shown to mediate the rearrangement of branched, nicked, and gapped DNA substrates that constitute models for illegitimate recombination. However, some of these rearrangements proceeded with different rates and efficiencies in the presence of human topoisomerase I. When inhibition of three of the rearrangements by CPT analogues was studied, most of the analogues exhibited differential effects on a given transformation, depending on the source of the enzyme employed.