Structure-based design of a novel peptide inhibitor of HIV-1 integrase: a computer modeling approach

The insertion of viral DNA into the host chromosome is an essential step in the replication of HIV-1, and is carried out by an enzyme, HIV-1 integrase (IN). Since the latter has no human cellular counterpart, it is an attractive target for antiviral drug design. Several IN inhibitors having activities in the micromolar range have been reported to date. However, no clinically useful inhibitors have yet been developed. Recently reported diketo acids represent a novel and selective class of IN inhibitors. These are the only class which appear to selectively target integrase and two of the inhibitors, L-708,906 and L-731,988, are the most potent inhibitors of preintegration complexes described to date.The X-ray crystal structure of the IN catalytic domain complexed with a diketo acid derivative inhibitor, 5CITEP, has recently been determined. Although the structure is of great value as a platform for drug design, experimental data suggest that crystal packing effects influence the observed inhibitor position. This has been confirmed by computational docking studies using the latest version (3.0) of the AutoDock program, which has been shown to give results largely consistent with available experimental data. Using AutoDock 3.0 and SYBYL6.6 we have modeled the complexes of IN with the diketo acid inhibitors so as to identify the enzyme binding site. In the quest for novel, potent and selective small molecule inhibitors, we present here a new approach to peptide inhibitor design using a, b- unsaturated (dehydro) residues, which confer a unique conformation on a peptide sequence. Based on the above models, we selected a tetrapeptide sequence containing a dehydro-Phe residue, which was found to have an open conformation as ascertained from its X-ray crystal structure. Docking results on this peptide led us to propose a modification at the C-terminal end. The modified peptide was found to dock in a similar position as the diketo acid inhibitors and was predicted to have a comparable potency.     

A folding inhibitor of the HIV-1 protease

Because the human immunodeficiency virus type 1 protease (HIV-1-PR) is an essential enzyme in the viral life cycle, its inhibition can control AIDS. The folding of single-domain proteins, like each of the monomers forming the HIV-1-PR homodimer, is controlled by local elementary structures (LES, folding units stabilized by strongly interacting, highly conserved, as a rule hydrophobic, amino acids). These LES have evolved over myriad generations to recognize and strongly attract each other, so as to make the protein fold fast and be stable in its native conformation. Consequently, peptides displaying a sequence identical to those segments of the monomers associated with LES are expected to act as competitive inhibitors and thus destabilize the native structure of the enzyme. These inhibitors are unlikely to lead to escape mutants as they bind to the protease monomers through highly conserved amino acids, which play an essential role in the folding process. The properties of one of the most promising inhibitors of the folding of the HIV-1-PR monomers found among these peptides are demonstrated with the help of spectrophotometric assays and circular dichroism spectroscopy.     

Probing the role of interfacial residues in a dimerization inhibitor of HIV-1 protease.

The importance of each side chain of a cross-linked interfacial peptide inhibitor of HIV-1 protease was evaluated using an alanine scanning approach. Whereas the parent inhibitor has an IC50 value of 350 nM, values for the mutations reported here range from 280-9200 nM. The relative importance or each residue was thus assigned and correlated to the solvent accessible surface area (SASA) exposed upon mutation.     

A cell-penetrating helical peptide as a potential HIV-1 inhibitor

The capsid domain of the human immunodeficiency virus type 1 (HIV-1) Gag polyprotein is a critical determinant of virus assembly, and is therefore a potential target for developing drugs for AIDS therapy. Recently, a 12-mer α-helical peptide (CAI) was reported to disrupt immature- and mature-like capsid particle assembly in vitro; however, it failed to inhibit HIV-1 in cell culture due to its inability to penetrate cells. The same group reported the X-ray crystal structure of CAI in complex with the C-terminal domain of capsid (C-CA) at a resolution of 1.7 Å. Using this structural information, we have utilized a structure-based rational design approach to stabilize the α-helical structure of CAI and convert it to a cell-penetrating peptide (CPP). The modified peptide (NYAD-1) showed enhanced α-helicity. Experiments with laser scanning confocal microscopy indicated that NYAD-1 penetrated cells and colocalized with the Gag polyprotein during its trafficking to the plasma membrane where virus assembly takes place. NYAD-1 disrupted the assembly of both immature- and mature-like virus particles in cell-free and cell-based in vitro systems. NMR chemical shift perturbation analysis mapped the binding site of NYAD-1 to residues 169-191 of the C-terminal domain of HIV-1 capsid encompassing the hydrophobic cavity and the critical dimerization domain with an improved binding affinity over CAI. Furthermore, experimental data indicate that NYAD-1 most likely targets capsid at a post-entry stage. Most significantly, NYAD-1 inhibited a large panel of HIV-1 isolates in cell culture at low micromolar potency. Our study demonstrates how a structure-based rational design strategy can be used to convert a cell-impermeable peptide to a cell-permeable peptide that displays activity in cell-based assays without compromising its mechanism of action. This proof-of-concept cell-penetrating peptide may aid validation of capsid as an anti-HIV-1 drug target and may help in designing peptidomimetics and small molecule drugs targeted to this protein.     

Crystal structure of a cross-reaction complex between an anti-HIV-1 protease antibody and an HIV-2 protease peptide

The monoclonal antibody 1696, elicited by HIV-1 protease, inhibits the activity of both HIV-1 and HIV-2 proteases with inhibition constants in the low nanomolar range. The antibody cross-reacts with peptides derived from the N-terminal region of both proteases. The crystal structure of the recombinant single-chain Fv fragment of 1696 complexed with an N-terminal peptide from the HIV-2 protease has been determined at 1.88A resolution. Interactions of the peptide with scFv1696 are compared with the previously reported structure of scFv1696 in complex with the corresponding peptide from HIV-1 protease. The origin of cross-reactivity of mAb1696 with HIV proteases is discussed.     

Design of a folding inhibitor of the HIV-1 protease

A novel way to inhibit HIV-1 protease by destabilizing its native state is discussed. A simplified protein model is used together with Monte Carlo simulations, to assess the destabilizing effect of peptides displaying the same sequence as specific fragments of the protein which are essential for its stability. Model calculations also show that it is unlikely that the protein can escape the inhibitory peptide by point mutations.     

Relation between sequence and structure of HIV-1 protease inhibitor complexes: a model system for the analysis of protein flexibility.

The flexibility of different regions of HIV-1 protease was examined by using a database consisting of 73 X-ray structures that differ in terms of sequence, ligands or both. The root-mean-square differences of the backbone for the set of structures were shown to have the same variation with residue number as those obtained from molecular dynamics simulations, normal mode analyses and X-ray B-factors. This supports the idea that observed structural changes provide a measure of the inherent flexibility of the protein, although specific interactions between the protease and the ligand play a secondary role. The results suggest that the potential energy surface of the HIV-1 protease is characterized by many local minima with small energetic differences, some of which are sampled by the different X-ray structures of the HIV-1 protease complexes. Interdomain correlated motions were calculated from the structural fluctuations and the results were also in agreement with molecular dynamics simulations and normal mode analyses. Implications of the results for the drug-resistance engendered by mutations are discussed briefly.     

A peptide inhibitor of HIV-1 assembly in vitro

Formation of infectious HIV-1 involves assembly of Gag polyproteins into immature particles and subsequent assembly of mature capsids after proteolytic disassembly of the Gag shell. We report a 12-mer peptide, capsid assembly inhibitor (CAI), that binds the capsid (CA) domain of Gag and inhibits assembly of immature- and mature-like capsid particles in vitro. CAI was identified by phage display screening among a group of peptides with similar sequences that bind to a single reactive site in CA. Its binding site was mapped to CA residues 169-191, with an additional contribution from the last helix of CA. This result was confirmed by a separate X-ray structure analysis showing that CAI inserts into a conserved hydrophobic groove and alters the CA dimer interface. The CAI binding site is a new target for antiviral development, and CAI is the first known inhibitor directed against assembly of immature HIV-1.     

Crystal structure of a complex of HIV-1 protease with a dihydroxyethylene-containing inhibitor: comparisons with molecular modeling.

The structure of a crystal complex of recombinant human immunodeficiency virus type 1 (HIV-1) protease with a peptide-mimetic inhibitor containing a dihydroxyethylene isostere insert replacing the scissile bond has been determined. The inhibitor is Noa-His-Hch psi [CH(OH)CH(OH)]Vam-Ile-Amp (U-75875), and its Ki for inhibition of the HIV-1 protease is < 1.0 nM (Noa = 1-naphthoxyacetyl, Hch = a hydroxy-modified form of cyclohexylalanine, Vam = a hydroxy-modified form of valine, Amp = 2-pyridylmethylamine). The structure of the complex has been refined to a crystallographic R factor of 0.169 at 2.0 A resolution by using restrained least-squares procedures. Root mean square deviations from ideality are 0.02 A and 2.4 degrees, for bond lengths and angles, respectively. The bound inhibitor diastereomer has the R configurations at both of the hydroxyl chiral carbon atoms. One of the diol hydroxyl groups is positioned such that it forms hydrogen bonds with both the active site aspartates, whereas the other interacts with only one of them. Comparison of this X-ray structure with a model-built structure of the inhibitor, published earlier, reveals similar positioning of the backbone atoms and of the side-chain atoms in the P2-P2' region, where the interaction with the protein is strongest. However, the X-ray structure and the model differ considerably in the location of the P3 and P3' end groups, and also in the positioning of the second of the two central hydroxyl groups. Reconstruction of the central portion of the model revealed the source of the hydroxyl discrepancy, which, when corrected, provided a P1-P1' geometry very close to that seen in the X-ray structure.     

Isolation and structure of a novel peptide inhibitor of HIV-1 integrase from marine polychaetes

A homogeneous peptide with a mass of 683 Da which inhibits HIV-1 integrase with IC₅₀ 3 × 10^?5 M was separated from aqueous extracts of a marine worm Eunicidae sp. by multistage chromatography purification. The Asp-Leu-Hse-His-Ala-Gln structure was proposed for this peptide according to amino acid analysis, automated amino acid Edman sequences, and TLC with witness homoserine and MS/MS fragmentation. The proposed structure is the first example of a natural peptide containing an amino acid homoserine residue.     

Serpin-serine protease binding kinetics: alpha 2-antiplasmin as a model inhibitor.

We have examined in detail the kinetics of binding of the serpin alpha 2-antiplasmin to the serine proteases alpha-chymotrypsin and plasmin. These represent model systems for serpin binding. We find, in contrast to earlier published results with alpha 2-antiplasmin and plasmin, that binding is reversible, and slow binding kinetics can be observed, under appropriate conditions. Binding follows a two-step process with both enzymes, with the formation of an initial loose complex which then proceeds to a tightly bound complex. In the absence of lysine and analogues, equilibrium between alpha 2-antiplasmin and plasmin is achieved rapidly, with an overall inhibition constant (Ki') of 0.3 pM. In the presence of tranexamic acid or 6-aminohexanoic acid, lysine analogues that mimic the effects of fibrin, plasmin binding kinetics are changed such that equilibrium is reached slowly following a lag phase after mixing of enzyme and inhibitor. The Ki' is also affected, rising to 2 pM in the presence of 6-aminohexanoic acid concentrations above 15 mM. Thus extrapolation to the in vivo situation indicates that complex formation in the presence of fibrin will be delayed, allowing a burst of enzyme activity following plasmin generation, but a tight, pseudoirreversible complex will result eventually. Chymotrypsin is more weakly inhibited by alpha 2-antiplasmin, exhibiting an overall Ki' of 0.1 nM, after two-stage complex formation. The inhibition constant for the initial loose complex (Ki) is very similar for both enzymes. The difference in binding strength between the two enzymes is accounted for by the dissociation rate constant of the second step of complex formation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Primary structure of human alpha 2-antiplasmin, a serine protease inhibitor (serpin)

The plasma protein alpha 2-antiplasmin is the main physiological inhibitor of the serine protease plasmin, which is responsible for the dissolution of fibrin clots. We have determined the primary structure of mature human alpha 2-antiplasmin by DNA sequencing of overlapping cDNA fragments prepared from human liver mRNA. cDNA clones were identified by hybridization with a 48-base pair deoxyoligonucleotide probe deduced from the sequence of a 16-amino acid peptide of alpha 2-antiplasmin. Mature human alpha 2-antiplasmin contains 452 amino acids. It is homologous (23-28%) with five other proteins belonging to the serine protease inhibitor (serpin) superfamily. Its reactive site, i.e. the peptide bond cleaved by reaction with its primary target enzyme, plasmin, consists of Arg364-Met365. This dipeptide corresponds to the reactive site Met358-Ser359 of the archetypal serpin, alpha 1-antitrypsin.     

Determination of amprenavir, a HIV-1 protease inhibitor, in human seminal plasma using high-performance liquid chromatography-tandem mass spectrometry

A HPLC-MS-MS method to measure amprenavir in human seminal plasma has been developed and validated. The procedure uses stable, isotopically labeled 13C6-amprenavir as an internal standard and 100 microl of sample. The method is accurate (bias less than or equal to 7.2%) and precise (within- and between-day RSDs less than or equal to 4.2%) over the dynamic range of 30-4,000 ng/ml. Recently, this simple and sensitive method was used to determine amprenavir concentrations in seminal samples collected from HIV-1 positive subjects receiving amprenavir antiretroviral therapy as part of a multicenter clinical trial.     

Three-dimensional structure of protein C inhibitor predicted from structure of alpha 1-antitrypsin with computer graphics

The three-dimensional structure of a proteolytically modified protein C inhibitor, a member of the serine protease inhibitor superfamily, was constructed with computer graphics based on its amino acid sequence homology with that of the modified alpha 1-antitrypsin whose structure had been elucidated by X-ray crystallography. The intact form of protein C inhibitor was predicted with an alpha-carbon model based on its hydrophilicity and hydrogen bond pattern. Furthermore, a model of its interaction with activated protein C was constructed based on the structure of the complex between trypsin and its inhibitor, which had been determined by X-ray crystallography.     

Crystal structure of chemically synthesized HIV-1 protease and a ketomethylene isostere inhibitor based on the p2/NC cleavage site

Here we report the X-ray structures of chemically synthesized HIV-1 protease and the inactive [D25N]HIV-1 protease complexed with the ketomethylene isostere inhibitor Ac-Thr-Ile-Nle psi[CO-CH(2)]Nle-Gln-Arg.amide at 1.4 and 1.8A resolution, respectively. In complex with the active enzyme, the keto-group was found to be converted into the hydrated gem-diol, while the structure of the complex with the inactive D25N enzyme revealed an intact keto-group. These data support the general acid-general base mechanism for HIV-1 protease catalysis.