Effect of prime-site sequence of retro-inverso-modified HTLV-1 protease inhibitor

The effects of additional substituents covering the prime-site of retro-inverso (RI)-modified HTLV-1 protease inhibitors containing a hydroxyethylamine isoster were clarified. Stereo-selective construction of the most potent isoster backbone was achieved by the Evans-aldol reaction. Addition of N-acetylated d-amino acid corresponding to the P₂′ site gave an RI-modified inhibitor showing superior inhibitory activity to the previous inhibitor. Inhibitory activities of the newly synthesized inhibitors suggest that partially modified RI inhibitors would interact with HTLV-1 protease in the same manner as the parent hydroxyethylamine inhibitor.     

Evaluations of substrate specificity and inhibition at PR/p3 cleavage site of HTLV-1 protease

Core sequences necessary for substrate recognition and its inhibition at the PR/p3 site of HTLV-1 protease were clarified for the first time. From the cleavage rates of peptides containing a part of the PR/p3 site, a heptapeptide was found to be the minimal sequence required for substrate recognition. The use of synthetic inhibitors containing hydroxyethylamine dipeptide isostere indicated that a tetrapeptide sequence was necessary to achieve potent inhibition.     

Narrow substrate specificity and sensitivity toward ligand-binding site mutations of human T-cell Leukemia virus type 1 protease

Human T-cell leukemia virus type 1 (HTLV-1) is associated with a number of human diseases; therefore, its protease is a potential target for chemotherapy. To compare the specificity of HTLV-1 protease with that of human immunodeficiency virus type 1 (HIV-1) protease, oligopeptides representing naturally occurring cleavage sites in various retroviruses were tested. The number of hydrolyzed peptides as well as the specificity constants suggested a substantially broader specificity of the HIV protease. Amino acid residues of HTLV-1 protease substrate-binding sites were replaced by equivalent ones of HIV-1 protease. Most of the single and multiple mutants had altered specificity and a dramatically reduced folding and catalytic capability, suggesting that mutations are not well tolerated in HTLV-1 protease. The catalytically most efficient mutant was that with the flap residues of HIV-1 protease. The inhibition profile of the mutants was also determined for five inhibitors used in clinical practice and inhibitor analogs of HTLV-1 cleavage sites. Except for indinavir, the HIV-1 protease inhibitors did not inhibit wild type and most of the mutant HTLV-1 proteases. The wild type HTLV-1 protease was inhibited by the reduced peptide bond-containing substrate analogs, whereas the mutants showed various degrees of weakened binding capability. Most interesting, the enzyme with HIV-1-like residues in the flap region was the most sensitive to the HIV-1 protease inhibitors and least sensitive to the HTLV-1 protease inhibitors, indicating that the flap plays an important role in defining the specificity differences of retroviral proteases.     

Design and synthesis of potent HIV-1 protease inhibitors incorporating hydroxyprolinamides as novel P2 ligands

A series of new HIV-1 protease inhibitors with the hydroxyethylamine core and different hydroxyprolinamide P2 ligands were designed and synthesized. Variation of substitutions at the P2 significantly affected the enzyme inhibitory potency of the inhibitors. Compounds 2a and 2d showed excellent enzyme inhibitory activity with IC₅₀ values in the nanomolar range. An active site binding model for inhibitors 2a and 2d was suggested based upon the computational-docking results of the ligand with HIV-1 protease. This model offers molecular insights regarding ligand-binding site interactions of the hydroxyprolinamide-derived novel P2-ligand.     

Mechanism of action of aspartic proteases. III. Conformational characteristics of HIV-1 protease inhibitor JG-365]

A set of conformations was shown to be characteristic of the free-state spatial structure of substrate-like inhibitor JG-365 for aspartic protease from HIV-1. Among them, the lowest-energy conformations have a folded form of the peptide backbone. The inhibitor has a noncleavable hydroxyethylamine group with an additional chiral center in its structure. Our calculations showed that only the S-isomer of the inhibitor displays conformational characteristics that practically coincide with those of the native substrate for HIV-1 protease. One of the calculated conformations with a completely extended main chain and a relative energy of 9.5 kcal/mol very closely mimics the experimentally observed structure of the inhibitor in the enzyme-inhibitor complex. The realization of this structure is unlikely for a free inhibitor, because it has only a small number of interresidual noncovalent interactions in the extended conformation; these are presumably compensated for by intermolecular interactions at the active site of the enzyme.     

BACE-1 hydroxyethylamine inhibitors using novel edge-to-face interaction with Arg-296

Inhibition of the aspartyl protease BACE-1 has the potential to deliver a disease-modifying therapy for Alzheimer’s disease. Herein, is described a series of potent inhibitors based on an hydroxyethylamine (HEA) transition state mimetic template. These inhibitors interact with the non prime side of the enzyme using a novel edge-to-face interaction with Arg-296.     

Role of hydroxyl group and R/S configuration of isostere in binding properties of HIV-1 protease inhibitors.

The crystal structure of the complex between human immunodeficiency virus type 1 (HIV-1) protease and a peptidomimetic inhibitor of ethyleneamine type has been refined to R factor of 0.178 with diffraction limit 2.5 A. The peptidomimetic inhibitor Boc-Phe-Psi[CH2CH2NH]-Phe-Glu-Phe-NH2 (denoted here as OE) contains the ethyleneamine replacement of the scissile peptide bond. The inhibitor lacks the hydroxyl group which is believed to mimic tetrahedral transition state of proteolytic reaction and thus is suspected to be necessary for good properties of peptidomimetic HIV-1 protease inhibitors. Despite the missing hydroxyl group the inhibition constant of OE is 1.53 nm and it remains in the nanomolar range also towards several available mutants of HIV-1 protease. The inhibitor was found in the active site of protease in an extended conformation with a unique hydrogen bond pattern different from hydroxyethylene and hydroxyethylamine inhibitors. The isostere nitrogen forms a hydrogen bond to one catalytic aspartate only. The other aspartate forms two weak hydrogen bridges to the ethylene group of the isostere. A comparison with other inhibitors of this series containing isostere hydroxyl group in R or S configuration shows different ways of accommodation of inhibitor in the active site. Special attention is devoted to intermolecular contacts between neighbouring dimers responsible for mutual protein adhesion and for a special conformation of Met46 and Phe53 side chains not expected for free protein in water solution.     

C-terminal residues of mature human T-lymphotropic virus type 1 protease are critical for dimerization and catalytic activity

HTLV-1 [HTLV (human T-cell lymphotrophic virus) type 1] is associated with a number of human diseases. HTLV-1 protease is essential for virus replication, and similarly to HIV-1 protease, it is a potential target for chemotherapy. The primary sequence of HTLV-1 protease is substantially longer compared with that of HIV-1 protease, and the role of the ten C-terminal residues is controversial. We have expressed C-terminally-truncated forms of HTLV-1 protease with and without N-terminal His tags. Removal of five of the C-terminal residues caused a 4-40-fold decrease in specificity constants, whereas the removal of an additional five C-terminal residues rendered the protease completely inactive. The addition of the N-terminal His tag dramatically decreased the activity of HTLV-1 protease forms. Pull-down experiments carried out with His-tagged forms, gel-filtration experiments and dimerization assays provided the first unequivocal experimental results for the role of the C-terminal residues in dimerization of the enzyme. There is a hydrophobic tunnel on the surface of HTLV-1 protease close to the C-terminal ends that is absent in the HIV-1 protease. This hydrophobic tunnel can accommodate the extra C-terminal residues of HTLV-1 protease, which was predicted to stabilize the dimer of the full-length enzyme and provides an alternative target site for protease inhibition.     

Crystal Structures of Inhibitor Complexes of Human T-Cell Leukemia Virus (HTLV-1) Protease

Human T-cell leukemia virus type 1 (HTLV-1) is a retrovirus associated with several serious diseases, such as adult T-cell leukemia and tropical spastic paraparesis/myelopathy. For a number of years, the protease (PR) encoded by HTLV-1 has been a target for designing antiviral drugs, but that effort was hampered by limited available structural information. We report a high-resolution crystal structure of HTLV-1 PR complexed with a statine-containing inhibitor, a significant improvement over the previously available moderate-resolution structure. We also report crystal structures of the complexes of HTLV-1 PR with five different inhibitors that are more compact and more potent. A detailed study of structure-activity relationships was performed to interpret in detail the influence of the polar and hydrophobic interactions between the inhibitors and the protease.     

Insights from atomic-resolution X-ray structures of chemically synthesized HIV-1 protease in complex with inhibitors

The human immunodeficiency virus 1 (HIV-1) protease (PR) is an aspartyl protease essential for HIV-1 viral infectivity. HIV-1 PR has one catalytic site formed by the homodimeric enzyme. We chemically synthesized fully active HIV-1 PR using modern ligation methods. When complexed with the classic substrate-derived inhibitors JG-365 and MVT-101, the synthetic HIV-1 PR formed crystals that diffracted to 1.04- and 1.2-A resolution, respectively. These atomic-resolution structures revealed additional structural details of the HIV-1 PR's interactions with its active site ligands. Heptapeptide inhibitor JG-365, which has a hydroxyethylamine moiety in place of the scissile bond, binds in two equivalent antiparallel orientations within the catalytic groove, whereas the reduced isostere hexapeptide MVT-101 binds in a single orientation. When JG-365 was converted into the natural peptide substrate for molecular dynamic simulations, we found putative catalytically competent reactant states for both lytic water and direct nucleophilic attack mechanisms. Moreover, free energy perturbation calculations indicated that the insertion of catalytic water into the catalytic site is an energetically favorable process.     

Comparison of the substrate specificity of the human T-cell leukemia virus and human immunodeficiency virus proteinases.

Human T-cell leukemia virus type-1 (HTLV-1) is associated with a number of human diseases. Based on the therapeutic success of human immunodeficiency virus type 1 (HIV-1) PR inhibitors, the proteinase (PR) of HTLV-1 is a potential target for chemotherapy. To facilitate the design of potent inhibitors, the subsite specificity of HTLV-1 PR was characterized and compared to that of HIV-1 PR. Two sets of substrates were used that contained single amino-acid substitutions in peptides representing naturally occurring cleavage sites in HIV-1 and HTLV-1. The original HIV-1 matrix/capsid cleavage site substrate and most of its substituted peptides were not hydrolyzed by the HTLV-1 enzyme, except for those with hydrophobic residues at the P4 and P2 positions. On the other hand, most of the peptides representing the HTLV-1 capsid/nucleocapsid cleavage site were substrates of both enzymes. A large difference in the specificity of HTLV-1 and HIV-1 proteinases was demonstrated by kinetic measurements, particularly with regard to the S4 and S2 subsites, whereas the S1 subsite appeared to be more conserved. A molecular model of the HTLV-1 PR in complex with this substrate was built, based on the crystal structure of the S9 mutant of Rous sarcoma virus PR, in order to understand the molecular basis of the enzyme specificity. Based on the kinetics of shortened analogs of the HTLV-1 substrate and on analysis of the modeled complex of HTLV-1 PR with substrate, the substrate binding site of the HTLV-1 PR appeared to be more extended than that of HIV-1 PR. Kinetic results also suggested that the cleavage site between the capsid and nucleocapsid protein of HTLV-1 is evolutionarily optimized for rapid hydrolysis.     

Identification of the RT-RH/IN cleavage site of HTLV-I

Human T-cell leukemia virus type 1 (HTLV-1) is a type C human retrovirus and is the causative agent of adult T-cell leukemia and other diseases. The enzymatic and structural proteins of HTLV-I are synthesized as part of a Gag-Pro-Pol precursor polyprotein, and the mature proteins are released by proteolytic processing catalyzed by HTLV-I protease. The locations of most of the proteolytic cleavage sites are known, however, the site that creates the N-terminus of HTLV-1 integrase has not been previously identified. A 15 residue peptide corresponding to junction of the C-terminus of RNaseH and N-terminus of integrase (DALLITPVLQLSPAF-OH) was incubated with HTLV-1 protease. Analysis of the cleavage products by LC-MS revealed fragments Ac-DALLITPVLQL-OH and H(2)N-SPAF-OH were produced, indicating cleavage between the leucine and serine. This is the first physical identification of the N-terminal amino acid sequence of the integrase of HTLV-1.     

Design and synthesis of highly potent HIV-1 protease inhibitors with novel isosorbide-derived P2 ligands

The design, synthesis, and biological evaluation of a series of six HIV-1 protease inhibitors incorporating isosorbide moiety as novel P2 ligands are described. All the compounds are very potent HIV-1 protease inhibitors with IC₅₀ values in the nanomolar or picomolar ranges (0.05–0.43 nM). Molecular docking studies revealed the formation of an extensive hydrogen-bonding network between the inhibitor and the active site. Particularly, the isosorbide-derived P2 ligand is involved in strong hydrogen bonding interactions with the backbone atoms.     

Synthesis and SAR of indole-and 7-azaindole-1,3-dicarboxamide hydroxyethylamine inhibitors of BACE-1

Heterocyclic replacement of the isophthalamide phenyl ring in hydroxyethylamine (HEA) BACE-1 inhibitors was explored. A variety of indole-1,3-dicarboxamide HEAs exhibited potent BACE-1 enzyme inhibition, but displayed poor cellular activity. Improvements in cellular activity and aspartic protease selectivity were observed for 7-azaindole-1,3-dicarboxamide HEAs. A methylprolinol-bearing derivative (10n) demonstrated robust reductions in rat plasma Aβ levels, but did not lower rat brain Aβ due to poor central exposure. The same analog exhibited a high efflux ratio in a bidirectional Caco-2 assay and was likely a substrate of the efflux transporter P-glycoprotein. X-ray crystal structures are reported for two indole HEAs in complex with BACE-1.     

Molecular modeling studies and comparative analysis on structurally similar HTLV and HIV protease using HIV-PR inhibitors

Abstract

Retroviruses are most perilous viral family, which cause much damage to the Homo sapiens. HTLV-1 mechanism found to more similar with HIV-1 and both retroviruses are causative agents of severe and fatal diseases including adult T-cell leukemia (ATL) and the acquired immune deficiency syndrome (AIDS). Both viruses code for a protease (PR) that is essential for replication and therefore represents a key target for drugs interfering with viral infection. In this work, the comparative study of HIV-1 and HTLV-1 PR enzymes through sequence and structural analysis is reported along with approved drugs of HIV-PR. Conformation of each HIV PR drugs have been examined with different parameters of interactions and energy scorings parameters. MD simulations with respect to timescale event of 20?ns favors that, few HIV-PR inhibitors can be more active inside the HTLV-1 PR binding pocket. Overall results suggest that, some of HIV inhibitors like Tipranavir, Indinavir, Darunavir and Amprenavir are having good energy levels with HTLV-1. Due to absence of interactions with MET37, here we report that derivatives of these compounds can be much better inhibitors for targeting HTLV-1 proteolytic activity.     

Lysine derivatives as potent HIV protease inhibitors. Discovery, synthesis and structure-activity relationship studies

A screening assay program on HIV-protease was carried out on more than fifty commercially available N-protected amino acids and has revealed that those with a long side chain such as lysine, ornithine and arginine exhibited significant inhibition of HIV protease enzyme. The presence of an Fmoc group was found to be essential to obtain micromolar inhibitors and the addition of an alkyl group at the Nalpha-position resulted in the discovery of the lead compound 11 displaying a 5 nM inhibition constant. Although this new inhibitor series is not categorized among those mimicking the substrate with a non-hydrolyzable transition-state isoster, it was found very specific to inhibit HIV protease enzyme in comparison to the mammalian aspartyl proteases pepsin, renin and cathepsin. Furthermore, these inhibitors did not show any cytotoxicity at a concentration below 75 microM.     

Potent piperazine hydroxyethylamine HIV protease inhibitors containing novel P3 ligands

The 2-isopropyl thiazolyl group is a highly optimized P₃ ligand for C₂ symmetry-based HIV protease inhibitors, as exemplified in the drug ritonavir. Here we report that incorporation of this P₃ ligand into a piperazine hydroxyethylamine series also yielded novel, highly potent inhibitors. In tissue culture assays, the presence of human serum was less deleterious to the activity of these inhibitors than to that of ritonavir. Furthermore, potent activity against ritonavir resistant HIV was observed.     

Studies on Substrate Specificity at PR/p3 Cleavage Site of HTLV-1 Protease

Substrate specificities for recognition at the PR/p3 site of HTLV-1 protease were clarified using small libraries of substrate peptides. Specificities at P₁ and P₁′ positions were examined by parallel synthesis/digestion of synthetic peptides covering the PR/p3 site (KGPPVILPIQA). Specificities at P₂ to P₄ positions were examined by split and mix syntheses of olefin-peptide libraries containing the substrate sequence (PPVILPIQ). The solid-phase Horner-Emmons reaction was successfully applied to syntheses of multi-component substrates for library preparation. From the digestion of substrate peptides by a chemically synthesized mutant of HTLV-1 protease (C2A HTLV-1 PR), it was found for the first time that the preference for Pro at the P₁′ position and for Ile at the P₂ position is unique for this enzyme. We dedicate this article to Prof. Bruce Merrifield for his great role and impact on solid-phase chemistry.