Characterization of an active single polypeptide form of the human immunodeficiency virus type 1 protease

Screening of HIV-1 Protease Using a Combination of an Ultra-High-Throughput Fluorescent-Based Assay and RapidFire Mass Spectrometry

HIV-1 protease (PR) represents one of the primary targets for developing antiviral agents for the treatment of HIV-infected patients. To identify novel PR inhibitors, a label-free, high-throughput mass spectrometry (HTMS) assay was developed using the RapidFire platform and applied as an orthogonal assay to confirm hits identified in a fluorescence resonance energy transfer (FRET)-based primary screen of > 1 million compounds. For substrate selection, a panel of peptide substrates derived from natural processing sites for PR was evaluated on the RapidFire platform. As a result, KVSLNFPIL, a new substrate measured to have a ~ 20- and 60-fold improvement in k cat/K m over the frequently used sequences SQNYPIVQ and SQNYPIV, respectively, was identified for the HTMS screen. About 17% of hits from the FRET-based primary screen were confirmed in the HTMS confirmatory assay including all 304 known PR inhibitors in the set, demonstrating that the HTMS assay is effective at triaging false-positives while capturing true hits. Hence, with a sampling rate of ~7 s per well, the RapidFire HTMS assay enables the high-throughput evaluation of peptide substrates and functions as an efficient tool for hits triage in the discovery of novel PR inhibitors.

Evidence that the Bacillus subtilis SpoIIGA protein is a novel type of signal-transducing aspartic protease

The bacterium Bacillus subtilis undergoes endospore formation in response to starvation. sigma factors play a key role in spatiotemporal regulation of gene expression during development. Activation of sigma factors is coordinated by signal transduction between the forespore and the mother cell. sigma(E) is produced as pro-sigma(E), which is activated in the mother cell by cleavage in response to a signal from the forespore. We report that expression of SpoIIR, a putative signaling protein normally made in the forespore, and SpoIIGA, a putative protease, is necessary and sufficient for accurate, rapid, and abundant processing of pro-sigma(E) to sigma(E) in Escherichia coli. Modeling and mutational analyses provide evidence that SpoIIGA is a novel type of aspartic protease whose C-terminal half forms a dimer similar to the human immunodeficiency virus type 1 protease. Previous studies suggest that the N-terminal half of SpoIIGA is membrane-embedded. We found that SpoIIGA expressed in E. coli is membrane-associated and that after detergent treatment SpoIIGA was self-associated. Also, SpoIIGA interacts with SpoIIR. The results support a model in which SpoIIGA forms inactive dimers or oligomers, and interaction of SpoIIR with the N-terminal domain of SpoIIGA on one side of a membrane causes a conformational change that allows formation of active aspartic protease dimer in the C-terminal domain on the other side of the membrane, where it cleaves pro-sigma(E).

Expression of the murine leukemia virus protease in fusion with maltose-binding protein in Escherichia coli

The protease of murine leukemia virus (MLV) was cloned into pMal-c2 vector, expressed in fusion with maltose-binding protein (MBP), and purified to homogeneity after Factor Xa cleavage of the chimeric protein. Substantial degradation of the fusion protein was observed during expression, which severely diminished the yield. The degree of degradation of the fusion protein was even more pronounced when a single-chain form of the MLV protease was cloned after the gene coding for MBP. To increase the yield, a hexahistidine tag with an additional Factor Xa cleavage site was cloned after the protease and nickel chelate affinity chromatography was used as the first purification step. The modified procedure resulted in substantially higher yield as compared to the original procedure. The degradation of hexahistidine-tagged active site mutant MLV protease was very low and comparable to that obtained with hexahistidine-tagged MBP, but purified MLV protease alone was not able to degrade purified MBP, suggesting that during expression the active MLV protease may activate bacterial proteases which appear to be responsible for the degradation of the fusion proteins.

Mechanisms for the deterioration in glucose tolerance associated with HIV protease inhibitor regimens

The mechanisms responsible for the deterioration in glucose tolerance associated with protease inhibitor-containing regimens in HIV infection are unclear. Insulin resistance has been implicated as a major factor, but the affected tissues have not been identified. Furthermore, beta-cell function has not been evaluated in detail. The present study was therefore undertaken to assess the effects of protease inhibitor-containing regimens on hepatic, muscle, and adipose tissue insulin sensitivity as well as pancreatic beta-cell function. We evaluated beta-cell function in addition to glucose production, glucose disposal, and free fatty acid (FFA) turnover using the hyperglycemic clamp technique in combination with isotopic measurements in 13 HIV-infected patients before and after 12 weeks of treatment and in 14 normal healthy volunteers. beta-Cell function and insulin sensitivity were also assessed by homeostasis model assessment (HOMA). Treatment increased fasting plasma glucose concentrations in all subjects (P < 0.001). Insulin sensitivity as assessed by HOMA and clamp experiments decreased by approximately 50% (P < 0.003). Postabsorptive glucose production was appropriately suppressed for the prevailing hyperinsulinemia, whereas glucose clearance was reduced (P < 0.001). beta-Cell function decreased by approximately 50% (P = 0.002), as assessed by HOMA, and first-phase insulin release decreased by approximately 25%, as assessed by clamp data (P = 0.002). Plasma FFA turnover and clearance both increased significantly (P < 0.001). No differences at baseline or in responses after treatment were observed between drug naïve patients who were started on a nucleoside reverse transcriptase inhibitor (NRTI) plus a protease inhibitor and patients who had been on long-term NRTI treatment and had a protease inhibitor added. The present study indicates that protease inhibitor-containing regimens impair glucose tolerance in HIV-infected patients by two mechanisms: 1) inducement of peripheral insulin resistance in skeletal muscle and adipose tissue and 2) impairment of the ability of the beta-cell to compensate.

Mutagenesis of the dimer interface residues of tethered and untethered HIV-1 protease result in differential activity and suggest multiple mechanisms of compensation

As is the case for all retroviruses, the protease of HIV-1 is only functional as a homodimer; dimerization of two protease monomers results in the formation of the enzyme active site. This dimer structure is supported primarily by interactions between the first four amino-terminal and the last four carboxy-terminal amino acids. These eight amino acids form a beta-sheet in which hydrophobic residues are oriented towards the core of the molecule and polar residues are directed towards the solvent. Although the structure of the dimer interface has been determined, the forces that support dimerization have not been fully characterized. Here, we describe a tethered construct in which two protease monomers are joined by a 5 amino acid linker. We evaluate the relative role of each dimer interface residue in functional homo- and heterodimers. Our studies indicate that the hydrophobic residues of the dimer interface are particularly important in maintaining enzyme activity and that enzyme activity is more sensitive to substitutions of the C-terminal amino acids. Further, we demonstrate that the presence of the tether is able to compensate for mutations within the dimer interface that inactivate the enzyme.

Total chemical synthesis of enzymes

The total synthesis, at will, of a wide variety of protein and enzyme molecules is made feasible by modem chemical ligation methods. As Emil Fischer intuitively understood, synthetic access to the enzyme molecule enables the power of chemical science to be applied to elucidating the molecular basis of catalytic function in unprecedented detail.

Characterization of the protease of a fish retrovirus, walleye dermal sarcoma virus

Three fish retroviruses infecting walleyes constitute the recently recognized genus called epsilonretrovirus. The founding member of this group, walleye dermal sarcoma virus (WDSV), induces benign skin tumors in the infected fish and replicates near 4 degrees C. While the viral genomic sequence is known, biochemical characterization of the virus has been limited to the identification of the mature structural and envelope proteins present in virions. We undertook this study to determine the cleavage sites in the WDSV Pro and Pol proteins and to characterize the viral protease (PR) in vitro. A recombinant PR was expressed in and purified from Escherichia coli as a larger fusion with additional nucleocapsid and reverse transcriptase residues flanking the PR domain. Autocleavage produced a functional, mature PR. Autocleavage as well as cleavage of peptides and of Gag protein by the mature PR occurred at a pH optimum of 7.0, higher than that of other retroviral proteases. Analysis of the cleavage sites identified a glutamine residue in the P2 position of all WDSV sites, both in Gag and in Pol. Amino acid sequence alignments of Gag-Pro-Pol from WDSV, walleye epidermal hyperplasia virus type 1, and walleye epidermal hyperplasia virus type 2 showed the P2 glutamine to be conserved in all cleavage sites in these three viruses. Such conservation is unprecedented in other retroviruses.

NMR identification of local structural preferences in HIV-1 protease tethered heterodimer in 6 M guanidine hydrochloride

Understanding protein folding requires complete characterization of all the states of the protein present along the folding pathways. For this purpose nuclear magnetic resonance (NMR) has proved to be a very powerful technique because of the great detail it can unravel regarding the structure and dynamics of protein molecules. We report here NMR identification of local structural preferences in human immunodeficiency virus-1 protease in the 'unfolded state'. Analyses of the chemical shifts revealed the presence of local structural preferences many of which are native-like, and there are also some non-native structural elements. Three-bond H(N)-H(alpha) coupling constants that could be measured for some of the N-terminal and C-terminal residues are consistent with the native-like beta-structure. Unusually shifted 15N and amide proton chemical shifts of residues adjacent to some prolines and tryptophans also indicate the presence of some structural elements. These conclusions are supported by amide proton temperature coefficients and nuclear Overhauser enhancement data. The locations of the residues exhibiting preferred structural propensities on the crystal structure of the protein, give useful insights into the folding mechanism of this protein.

Real time NMR monitoring of local unfolding of HIV-1 protease tethered dimer driven by autolysis

Structural studies in proteases have been hampered because of their inherent autolytic function. However, since autolysis is known to be mediated via protein unfolding, careful monitoring of the autolytic reaction has the potential to throw light on the folding-unfolding equilibria. In this paper we describe real time nuclear magnetic resonance investigations on the tethered dimer construct of the human immunodeficiency virus-1 protease, which have yielded insights into the relative stabilities of several residues in the protein. The residues lying along the active site (bottom, side and top of the active site) and those in helix have lower unfolding free energy values than the other parts of the protein. The residue level stability differences suggest that the protein is well suited to adjust itself in almost all the regions of its structure, as and when perturbations occur, either due to ligand binding or due to mutations.

Importance of the N terminus of rous sarcoma virus protease for structure and enzymatic function

All retrovirus proteases (PRs) are homodimers, and dimerization is essential for enzymatic function. The dimer is held together largely by a short four-stranded antiparallel beta sheet composed of the four or five N-terminal amino acid residues and a similar stretch of residues from the C terminus. We have found that the enzymatic and structural properties of Rous sarcoma virus (RSV) PR are exquisitely sensitive to mutations at the N terminus. Deletion of one or three residues, addition of one residue, or substitution of alanine for the N-terminal leucine reduced enzymatic activity on peptide and protein substrates 100- to 1,000-fold. The purified mutant proteins remained monomeric up to a concentration of about 2 mg/ml, as determined by dynamic light scattering. At higher concentrations, dimerization was observed, but the dimer lacked or was deficient in enzymatic activity and thus was inferred to be structurally distinct from a wild-type dimer. The mutant protein lacking three N-terminal residues (DeltaLAM), a form of PR occurring naturally in virions, was examined by nuclear magnetic resonance spectroscopy and found to be folded at concentrations where it was monomeric. This result stands in contrast to the report that a similarly engineered monomeric PR of human immunodeficiency virus type 1 is unstructured. Heteronuclear single quantum coherence spectra of the mutant at concentrations where either monomers or dimers prevail were nearly identical. However, these spectra differed from that of the dimeric wild-type RSV PR. These results imply that the chemical environment of many of the amide protons differed and thus that the three-dimensional structure of the DeltaLAM PR mutant is different from that of the wild-type PR. The structure of this mutant protein may serve as a model for the structure of the PR domain of the Gag polyprotein and may thus give clues to the initiation of proteolytic maturation in retroviruses.

1.9 A x-ray study shows closed flap conformation in crystals of tethered HIV-1 PR

Three-dimensional structure of an asymmetrically mutated (C95M) tethered human immunodeficiency virus type 1 protease enzyme (HIV-1 PR) has been determined in an unliganded form using X-ray diffraction data to 1.9 A resolution. The structure, refined using X-PLOR to an R factor of 19.5%, is unexpectedly similar to the ligand-bound native enzyme, rather than to the ligand-free native enzyme. In particular, the two flaps in the tethered dimer are in a closed configuration. The environments around M95 and C1095 are identical, showing no structural effect of this asymmetric mutation at position 95. Oxidation of Cys1095 has been observed for the first time. There is one well-defined water molecule that hydrogen bonds to both carboxyl groups of the essential aspartic acids in the active site. Proteins 2001;43:57-64.

Free energy calculations on dimer stability of the HIV protease using molecular dynamics and a continuum solvent model

Dimerization of HIV-I protease (HIV PR) monomers is an essential prerequisite for viral proteolytic activity and the subsequent generation of infectious virus particles. Disrupting dimerization of the enzyme can inhibit its activity. We have calculated the relative binding free energies between different dimers of the HIV protease using molecular dynamics and a continuum model, which we call MM/PBSA. We examined the dominant negative inhibition of the HIV PR by a mutated form of the protease and found relative dimerization free energies of homo- and hetero-dimerization consistent with experimental data. We also developed a rapid screening method, which was called the virtual mutagenesis method to consider other mutations which might stabilize non-wild-type heterodimers. Using this approach, we considered the mutations near the dimer interface which might cause dominant negative inhibition of the HIV PR. The rapid method we developed can be used in studying any ligand-protein and protein-protein interaction, in order to identify mutations that can enhance the binding affinities of the complex.

Systematic mutational analysis of the active-site threonine of HIV-1 proteinase: rethinking the "fireman's grip" hypothesis

Aspartic proteinases share a conserved network of hydrogen bonds (termed "fireman's grip"), which involves the hydroxyl groups of two threonine residues in the active site Asp-Thr-Gly triplets (Thr26 in the case of human immunodeficiency virus type 1 (HIV-1) PR). In the case of retroviral proteinases (PRs), which are active as symmetrical homodimers, these interactions occur at the dimer interface. For a systematic analysis of the "fireman's grip," Thr26 of HIV-1 PR was changed to either Ser, Cys, or Ala. The variant enzymes were tested for cleavage of HIV-1 derived peptide and polyprotein substrates. PR(T26S) and PR(T26C) showed similar or slightly reduced activity compared to wild-type HIV-1 PR, indicating that the sulfhydryl group of cysteine can substitute for the hydroxyl of the conserved threonine in this position. PR(T26A), which lacks the "fireman's grip" interaction, was virtually inactive and was monomeric in solution at conditions where wild-type PR exhibited a monomer-dimer equilibrium. All three mutations had little effect when introduced into only one chain of a linked dimer of HIV-1 PR. In this case, even changing both Thr residues to Ala yielded residual activity suggesting that the "fireman's grip" is not essential for activity but contributes significantly to dimer formation. Taken together, these results indicate that the "fireman's grip" is crucial for stabilization of the retroviral PR dimer and for overall stability of the enzyme.

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.

Small dipeptide-based HIV protease inhibitors containing the hydroxymethylcarbonyl isostere as an ideal transition-state mimic

The human immunodeficiency virus (HIV) codes for an aspartic protease known to be essential for retroviral maturation and replication. HIV protease is formed from two identical 99 amino acid peptides. We synthesized [(NHCH2CH2-S-CH2CO)51-52, Ala67,95]HIV-1 protease using the thioether chemical ligation method, and then prepared the [(NHCH2CH2-S-CH2CO)51-52, Ala67,95, Cys98]HIV-1 protease dimer analogue covalently linked by a disulfide bridge. These HIV-1 protease analogues effectively cleaved the Tyr-Phe-type substrate, but had weak affinity to the Tyr-Pro-type substrate. Consequently, the molecular recognition of the protease analogues differs from that of the wild-type enzyme. Based on the substrate transition state, we designed and synthesized a novel class of HIV protease inhibitors containing an unnatural amino acid, (2S, 3S)-3-amino-2-hydroxy-4-phenylbutyric acid, named allophenylnorstatine, with a hydroxymethylcarbonyl (HMC) isostere. The stereochemistry of the hydroxyl group was significant for the enzyme inhibition and the HMC group interacted excellently with the aspartic acid carboxyl groups of HIV protease active site in the essentially same hydrogen-bonding mode as the transition state. Small dipeptide-based HIV protease inhibitors containing the HMC isostere were studied as advantageous compounds. Among them, a dipeptide-based HIV protease inhibitor, KNI-577, exhibited potent antiviral activities, low cytotoxicity, and good pharmacokinetic properties.

Unfolding kinetics of tryptophan side chains in the dimerization and hinge regions of HIV-I protease tethered dimer by real time NMR spectroscopy

HIV I protease has been the target of extensive and variety of investigations in recent years because of its importance in the AIDS viral life cycle. We describe here real time NMR studies on the unfolding kinetics of two tryptophans, W6 and W42, which are located in the dimerization and hinge domains of the protein, respectively. Unfolding seems to get initiated in the dimerization domain. The kinetic data at two temperatures, 32 and 42 degrees C, can both be described by two-state models for both the tryptophans, and the final state reached at 42 degrees C does not depend on the path of unfolding. Unfolding free energy changes derived from the kinetic fitting parameters are less than 3 kJ/mol, indicating that the energy landscape is very shallow. The free energy values and the rates for the two tryptophans are different at 32 degrees C, but are nearly the same at 42 degrees C. These are interpreted in the light of the "new view" of protein folding and the relative behaviors of the two tryptophans suggest the existence of cooperative pathways in the unfolding reaction of the protein. These observations would provide valuable insights into protein function, stability, and effects of nonactive site mutations conferring drug resistance.

Targeting the HIV-protease in AIDS therapy: a current clinical perspective

This review deals with clinical applications of compounds that inhibit the action of the protease encoded within the genome of human immunodeficiency virus (HIV). The HIV-protease is essential for viral maturation and represents an important therapeutic target in the fight against AIDS. Following a brief overview of the enzyme structure and function, the article focuses on a number of peptide and non-peptide based HIV-protease inhibitors that are in current clinical use. These drugs are discussed both with respect to their efficacy in treatment of AIDS, and to problems related to insurgence of viral resistance and side effects seen to date in patient populations.

Structural and biochemical studies of retroviral proteases

Retroviral proteases form a unique subclass of the family of aspartic proteases. These homodimeric enzymes from a number of viral sources have by now been extensively characterized, both structurally and biochemically. The importance of such knowledge to the development of new drugs against AIDS has been, to a large extent, the driving force behind this progress. High-resolution structures are now available for enzymes from human immunodeficiency virus types 1 and 2, simian immunodeficiency virus, feline immunodeficiency virus, Rous sarcoma virus, and equine infectious anemia virus. In this review, structural and biochemical data for retroviral proteases are compared in order to analyze the similarities and differences between the enzymes from different sources and to enhance our understanding of their properties.

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.

Redesigning the quaternary structure of R67 dihydrofolate reductase. Creation of an active monomer from a tetrameric protein by quadruplication of the gene

R67 dihydrofolate reductase (DHFR) provides resistance to the antibacterial drug trimethoprim. This R-plasmid-encoded enzyme does not share any homology with chromosomal DHFR. A recent crystal structure of active, homotetrameric R67 DHFR (Narayana, N., Matthews, D. A., Howell, E. E., and Xuong, N.-H. (1995) Nat. Struct. Biol. 2, 1018-1025) indicates that a single active site pore traverses the length of the molecule. Since the center of the pore possesses exact 222 symmetry, site-directed mutagenesis of residues in the pore will produce four mutations/active site. To break this inevitable symmetry, four copies of the gene have been linked in frame to create an active monomer possessing the essential tertiary structure of native tetrameric R67 DHFR. The protein product, quadruple R67 DHFR, is 4 times the molecular mass of native R67 DHFR in SDS-polyacrylamide gel electrophoresis and is monomeric under nondenaturing conditions as measured by sedimentation equilibrium experiments. The catalytic activity of quadruple R67 DHFR is decreased only slightly when compared with native R67 DHFR. Folding of quadruple R67 DHFR is completely reversible at pH 5. However, at pH 8, folding is not fully reversible; this is likely due to a competition between productive intramolecular versus nonproductive intermolecular domain association. The production of a fully active, monomeric R67 DHFR variant will enable the design of more meaningful site-directed mutants where single substitutions per active site pore can be generated.

Destroying retroviruses from within

One strategy for neutralizing retroviral infectivity is to induce the incorporation of lethal fusion proteins, such as capsid protein-nuclease fusions, into the virion during the normal viral assembly process. Genes encoding such antiviral fusion proteins must be nontoxic to the host, lethal to the virus, and must be efficiently delivered to, and expressed in, appropriate target cells.

Therapeutic effect of Gag-nuclease fusion protein on retrovirus-infected cell cultures

Capsid-targeted viral inactivation is a novel protein-based strategy for the treatment of viral infections. Virus particles are inactivated by targeting toxic fusion proteins to virions, where they destroy viral components from within. We have fused Staphylococcus nuclease (SN) to the C-terminal end of Moloney murine leukemia virus Gag and demonstrated that expression of this fusion protein in chronically infected chicken embryo fibroblasts resulted in its incorporation into virions and subsequent inactivation of the virus particles by degradation of viral RNA. Release of particles incorporating Gag-SN fusion proteins into the extracellular milieu activates the nuclease and results in destruction of the virion from within. By comparing the effects of incorporated SN and SN*, an enzymatically inactive missense mutant form of SN, on the infectivity of virus particles, we have clearly demonstrated that nucleolytic activity is the antiviral mechanism. Expression of Gag-SN fusion proteins as a therapeutic agent causes a stable reduction of infectious titers by 20- to 60-fold. The antiviral effect of capsid-targeted viral inactivation in our model system, using both prophylactic and therapeutic approaches, suggests that a similar anti-human immunodeficiency virus strategy might be successful.

Assay of HIV-1 protease activity by use of crude preparations of enzyme and biotinylated substrate

An enzyme immunoassay was developed for monitoring protease reactions of human immunodeficiency virus (HIV). The protease and its substrate, the gag precursor, were generated separately in Escherichia coli. The HIV-1 protease was generated with a glutathione-S-transferase expression system and the gag substrate, named Pin17/24, was prepared with a PinPoint expression system. Pin17/24 consists of an N-terminal peptide, which is biotinylated in E. coli, fused with a C-terminal peptide that contains a protease cleavage site flanked by p17 and p24 segments. Through its biotin in the N-terminal region, Pin17/24 bound to ELISA plates coated with avidin, whereas through its C-terminal region, the same molecule of Pin17/24 could be recognized by an anti-p24 monoclonal antibody. When the protease was added to Pin17/24, the p24 fragment was released from the biotinylated fusion protein and could no longer be retained on the avidin plates, and as a result, binding of the anti-p24 monoclonal antibody decreased. The binding was specific and the reaction was inhibited by a known HIV protease inhibitor. Due to the specific interactions between avidin and biotin, monoclonal antibody and antigen, and the HIV protease and the gag substrate, crude preparations of these reagents can be used readily in the assay. The simplicity and feasibility of this method should be useful for simultaneous monitoring of many enzyme reactions, particularly for screening possible HIV protease inhibitors.

Crystal structure of a tethered dimer of HIV-1 proteinase complexed with an inhibitor

HIV-1 proteinase (HIV PR) is a dimeric enzyme composed of two identical polypeptide chains that associate with twofold symmetry. We have determined to 1.8 A the crystal structure of a covalently tethered dimer of HIV PR. The tethered dimer:inhibitor complex is identical in nearly every respect to the complex of the same inhibitor with the wild type dimeric molecule, except for the linker region. Our results suggest that the tethered dimer may be a useful surrogate enzyme for studying the effects of single site mutations on substrate and inhibitor binding as well as on enzyme asymmetry, and for simulating independent mutational drift of the two domains which has been proposed to have led to the evolution of modern day, single-chain aspartic proteinases.

Engineering aspartic proteases to probe structure and function relationships

Recently, protein engineering has been used to interconvert homodimeric and homologous single-chain aspartic proteases, with some success. The independent folding of the domains of these proteases has also permitted the engineering of domain-rearranged protease zymogens and the use of individual domains as probes for structural denaturation. In addition, site-directed mutagenesis has provided insights into the catalytic mechanism and specificity of this family of proteases.

Characterization of HIV-1 protease mutants: random, directed, selected

The HIV-1 protease is becoming one of the most important proteins in medicine. It is perhaps the most attractive target for development of an anti-HIV-1 therapeutic drug. Given its pre-eminent position in biomedical research, many aspects of the protease are currently coming under close scrutiny. Protease is available from recombinant sources, and numerous structures of the enzyme (with and without bound inhibitors) have now been determined by crystallographic methods, enabling the full utilization of mutational analysis in the study of protease function. In addition, the selection of HIV-1 mutants with reduced sensitivity to protease inhibitors is further complementing research on this enzyme.

Dissociation and association of the HIV-1 protease dimer subunits: equilibria and rates

The kinetics and equilibrium properties were investigated for the interconversion between the active dimer of human immunodeficiency virus 1 (HIV-1) protease and its inactive monomeric subunits. The equilibrium dissociation constant (Kd) of the dimeric protease as well as the monomer association rate were obtained by monitoring the fluorescence change of an active-site-directed fluorescent probe (L-737244) upon its binding to the protease. The Kd of the HIV-1 protease is strongly pH dependent. At pH 5.5 where the enzyme is most active catalytically, the extrapolated values of Kd are 0.75 and 3.4 nM at 30 and 37 degrees C, respectively. The rate constant for HIV-1 monomer association, approximately 4 x 10(5) M-1 s-1, is within the range commonly observed for protein-protein interactions. Dimer dissociation was further scrutinized in the presence of an inactive, point mutant form of the enzyme. As a result of subunit exchange between the native and mutant enzymes and the formation of an inactive heterodimer, there was a time-dependent decrease in the activity of the native protease. Enzyme activity could be reinstated with the addition of an active-site-directed inhibitor (L-365862) which selectively binds active dimers. The rate of dimer dissociation was found to also decrease with pH. At pH 5.5 and 30 degrees C, the half-life for subunit dissociation is about 0.5 h. The slow dissociation, coupled with the high stability for dimer association, attests to the importance of allowing sufficient time for dimer-monomer equilibration in kinetic assays in order to avoid reaching erroneous conclusions in studies of dimer dissociation.

Stability of dimeric retroviral proteases

The determination of dimer stabilities for the retroviral proteases has proved more challenging than anticipated, but it is a tractable problem when careful attention is made to potential interferences. For investigations of retroviral proteases not yet characterized, the fundamentally rigorous sedimentation equilibrium and other biophysical techniques may yet provide useful Kd values. They are preferable to the indirect methods emphasized in this chapter but nevertheless should be coupled with basic considerations such as recovery of activity at the end of an experiment and the relevance of values obtained to other situations. In the likely event that nanomolar Kd values are encountered in new investigations, the assay techniques provide the most readily available methods for many laboratories. Because these methods are sensitive to anything that affects enzyme activity, the use of complementary methods to verify dimerization constants is imperative. Inactivating reactions not due to monomer formation should be explored, and the potential impact of those reactions on the constants being measured should be estimated. Most of the Kd and dimerization rate data available for retroviral proteases are obtained with the HIV-1 protease, with each investigator choosing methods and solvent conditions different from the others. The confusing diversity of results should be the impetus for a direct comparison of methods for the identification of the sources of differences. If more comprehensive and rigorous measures of the kinetics and thermodynamics of subunit aggregation are obtained, they might be coupled with the large volume of detailed structural data accumulating for this class of protein to provide insights into more general problems of protein-folding chemistry.

Synthetic "interface" peptides alter dimeric assembly of the HIV 1 and 2 proteases

Retroviral proteases are obligate homodimers and play an essential role in the viral life cycle. Dissociation of dimers or prevention of their assembly may inactivate these enzymes and prevent viral maturation. A salient structural feature of these enzymes is an extended interface composed of interdigitating N- and C-terminal residues of both monomers, which form a four-stranded beta-sheet. Peptides mimicking one beta-strand (residues 95-99), or two beta-strands (residues 1-5 plus 95-99 or 95-99 plus 95-99) from the human immunodeficiency virus 1 (HIV1) interface were shown to inhibit the HIV1 and 2 proteases (PRs) with IC50's in the low micromolar range. These interface peptides show cognate enzyme preference and do not inhibit pepsin, renin, or the Rous sarcoma virus PR, indicating a degree of specificity for the HIV PRs. A tethered HIV1 PR dimer was not inhibited to the same extent as the wild-type enzymes by any of the interface peptides, suggesting that these peptides can only interact effectively with the interface of the two-subunit HIV PR. Measurements of relative dissociation constants by limit dilution of the enzyme show that the one-strand peptide causes a shift in the observed Kd for the HIV1 PR. Both one- and two-strand peptides alter the monomer/dimer equilibrium of both HIV1 and HIV2 PRs. This was shown by the reduced cross-linking of the HIV2 PR by disuccinimidyl suberate in the presence of the interface peptides. Refolding of the HIV1 and HIV2 PRs with the interface peptides shows that only the two-strand peptides prevent the assembly of active PR dimers. Although both one- and two-strand peptides seem to affect dimer dissociation, only the two-strand peptides appear to block assembly. The latter may prove to be more effective backbones for the design of inhibitors directed toward retroviral PR dimerization in vivo.

Potential role of the viral protease in human immunodeficiency virus type 1 associated pathogenesis

Infection with the human immunodeficiency virus type 1 (HIV-1) results in a variety of pathological changes culminating in the acquired immune deficiency syndrome (AIDS). While most of these changes can readily be accounted for either by direct effects of HIV-1 on the immune system or by indirect effects of secondary infectious agents as a result of faulty immune surveillance, the direct cause for a number of disease states, including some neuropathies, myopathies, nephropathy, thrombocytopenia, wasting syndromes and increased incidence of cancers (primarily lymphoma) has remained an enigma. We have recently shown that the HIV-1 protease, a viral encoded enzyme necessary for virus maturation and infectivity, can cleave a variety of host cell cytoskeletal proteins in vitro. Potential substrates for the HIV-1 protease are found in all of the cell types affected in these unexplained diseases. Recent proposals suggest that elements of the cytoskeleton may play an important role in the regulation of large scale genetic regulation. We propose that some of the degenerative changes associated with infection by HIV-1 are a direct consequence of cleavage of host cell cytoskeletal proteins, which in turn may be responsible for the increased incidence of cancer in HIV-1 infected individuals as a result of the perturbation of the regulation of gene expression by cytoskeletal components.

The HIV-1 protease as a therapeutic target for AIDS

HIV produces a small , dimeric aspartyl protease which specifically cleaves the polyprotein precursors encoding the structural proteins and enzymes of the virus. This proteolytic activity is absolutely required for the production of mature, infectious virions and is therefore an attractive target for therapeutic intervention. This review summarizes the strategies and multidisciplinary efforts that have been applied to date to the identification of specific inhibitors of this critical viral enzyme. These inhibitors include rationally designed peptide substrate analogs, compounds conceived from tertiary structure information on the enzyme and natural products. Future directions in the discovery and development of HIV-1 protease inhibitors are also discussed.

Human immunodeficiency virus type 1 and type 2 protease monomers are functionally interchangeable in the dimeric enzymes

Human immunodeficiency virus type 1 (HIV-1) and HIV-2 proteases are dimers of identical subunits. We made a construct for the expression of recombinant one-chain HIV-2 protease dimer, which, like the previously described one-chain HIV-1 protease dimer, is fully active. The constructs for the one-chain dimers of HIV-1 and HIV-2 proteases were modified to produce hybrid one-chain dimers consisting of both HIV-1 and HIV-2 protease monomers. Although the monomers share only 47.5% sequence identity, the hybrid one-chain dimers are fully active, suggesting that the folding of both HIV-1 and HIV-2 protease monomers is functionally similar.

Continuous assay of the hydrolytic activity of human immunodeficiency virus-1 protease

A rapid sensitive method for the quantitation in vitro of HIV-1 protease activity has been developed. A fluorogenic compound, N alpha-benzoyl-Arg-Gly-Phe-Pro-MeO-beta-naphthylamide, which contains Phe-Pro, a dipeptide bond recognized by HIV-1 protease, was used as substrate. The substrate was hydrolyzed by HIV-1 protease into a fluorescent naphthylated product (Pro-MeO-beta-naphthylamide). Fluorescence due to the release of Pro-MeO-beta-naphthylamide was measured continuously by spectrofluorometry. This oligopeptide was found to be a good substrate for HIV-1 protease. The Km and kappa cat for the hydrolysis of N alpha-benzoyl-Arg-Gly-Phe-Pro-MeO-beta- naphthylamide by HIV-1 protease were calculated to be 2.0 +/- 0.2 mM and 75 +/- 6 s-1, respectively. These values are comparable with those of other natural substrates of HIV-1 protease. The method is highly sensitive, reproducible, and suited to a variety of applications, including the analysis of large numbers of samples for detailed enzymological studies.

trans-acting viral protease is necessary and sufficient for activation of avian leukosis virus reverse transcriptase

The structural and enzymatic components of retroviral cores are formed by proteolytic cleavage of precursor polypeptides, mediated by the viral protease (PR). We described previously the construction of PR-defective avian leukosis viruses. These mutant viruses are noninfectious, and their major internal components are the uncleaved gag and gag-pol polyproteins (Pr76gag and Pr180gag-pol). The reverse transcriptase (RT) activity associated with the PR-defective virions is approximately 500-fold reduced relative to that of wild-type virions, suggesting that specific cleavages activate RT activity. To gain a better understanding of the role that PR plays in the processing and activation of RT, we performed complementation experiments wherein wild-type or PR mutant gag precursors were separately coexpressed with frame-corrected wild-type or PR mutant gag-pol precursors. The results demonstrate that, as in other retrovirus systems, gag-pol precursors can be assembled into virions only when they are rescued by a gag precursor. If the gag precursor is wild type, then the rescued Pr180gag-pol is completely and properly matured, irrespective of whether its embedded PR domain is wild type or mutant. In both cases, the virions produced are fully and equally infectious. This indicates that an active-site mutation in the PR domain of the gag-pol precursor has no effect on avian leukosis virus infectivity when particles are assembled from wild-type gag precursors. In contrast, if the gag precursor has an active-site mutation in PR or is deleted for PR, then the virions are noninfectious and the gag and gag-pol precursors remain unprocessed, even if the embedded PR domain of Pr180gag-pol is wild type. Thus, in this system, virion-associated Pr180gag-pol displays no detectable cis- or trans-acting PR activity. As assayed with an exogenous template, virions with processed gag-pol polyprotein display high levels of RT activity while those with unprocessed Pr180gag-pol display greatly reduced RT activity. These results demonstrate that during virion assembly, the PR supplied by a gag precursor is both necessary and sufficient for trans-activation of RT through proteolytic maturation of copackaged gag-pol polyprotein.