195 In silico study on HIV-PRIs substructures to terminate proteolytic activity in HTLV

Human T-lymphotropic virus (HTLV) is RNA retrovirus, which causes CD3?+?and CD4?+?T-cell type leukemia and demyelinating diseases, like tropical spastic myelopathy. The replicative stage of the virus is one of the critical stages for the development of the disease. At present, there are no approved therapeutic agents targeting HTLV. The HTLV mechanism of malignant cell growth in adult T-cell leukemia (ATL)/lymphoma, and the HTLV-PR has been an attractive target for anticancer drug design. In comparison with other retroviruses, HTLV also encodes protease (PR) enzyme which is essential for maturation. Both the HIV and HTLV proteases show high structural similarity but known inhibitors of HIV-PR are not able to inhibit the HTLV-PR, while comparing the binding pocket of both proteases, MET37 of HTLV shows repulsive role with known HIV inhibitors. Functional analysis of M37A mutation clearly shows that MET37 is highly important for the protease function. Available inhibitors were tested against the HTLV-PR binding pocket and failed to interact with MET37. Screening of similar libraries of known compounds provides better interactions with MET37 and further validation with in vivo and in vitro studies on these screened compounds will provide more strength in discovering potent inhibitor for HTLV-PR.     

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.     

Development of [Ile40]HTLV‐I protease inhibition assay using novel fluorogenic and chromogenic substrate

HTLV‐I is a debilitating and/or lethal retrovirus that causes HTLV‐I‐associated myelopathy/tropical spastic paraparesis, adult T‐cell leukemia and several inflammatory diseases. HTLV‐I protease is an aspartic retropepsin involved in HTLV‐I replication and its inhibition could treatHTLV‐I infection. A recombinant L40I mutant HTLV‐I protease was designed and obtained from Escherichia coli, self‐processingand purification by ion‐exchange chromatography. The protease was refolded by a one‐step dialysis and recovered activity. The cleavage efficiency of the [Ile⁴⁰]HTLV‐I protease was at least 300 times higher for a fluorescent substratethan that of our previously reported recombinant His‐tagged non‐mutated HTLV‐I protease. In addition, we designed and synthesized a substrate containing a highly fluorescent Mca moiety in the fragment before the scissile bond, and a chromogenic p‐nitrophenylalanine moiety after the scissile bond that greatly amplified spectrometry detection and improved the HTLV‐I protease inhibition potency assay. The HTLV‐I protease inhibition assay with the [Ile⁴⁰]HTLV‐I protease and fluorogenic substrate requires distinctively less protease, substrate, inhibitor and assay time than our previous methods. This means our new assay is more cost‐effective and more time‐efficient while being reproducible and less labor‐intensive. Copyright © 2011 European Peptide Society and John Wiley & Sons, Ltd.     

Revealing the dimer dissociation and existence of a folded monomer of the mature HIV‐2 protease

Purification and in vitro protein‐folding schemes were developed to produce monodisperse samples of the mature wild‐type HIV‐2 protease (PR2), enabling a comprehensive set of biochemical and biophysical studies to assess the dissociation of the dimeric protease. An E37K substitution in PR2 significantly retards autoproteolytic cleavage during expression. Furthermore, it permits convenient measurement of the dimer dissociation of PR2_E37K (elevated K_d ～20 nM) by enzyme kinetics. Differential scanning calorimetry reveals a T_m of 60.5 for PR2 as compared with 65.7°C for HIV‐1 protease (PR1). Consistent with weaker binding of the clinical inhibitor darunavir (DRV) to PR2, the T_m of PR2 increases by 14.8°C in the presence of DRV as compared with 22.4°C for PR1. Dimer interface mutations, such as a T26A substitution in the active site (PR2_T26A) or a deletion of the C‐terminal residues 96–99 (PR2_1–95), drastically increase the K_d (>10⁵‐fold). PR2_T26A and PR2_1–95 consist predominantly of folded monomers, as determined by nuclear magnetic resonance (NMR) and size‐exclusion chromatography coupled with multiangle light scattering and refractive index measurements (SMR), whereas wild‐type PR2 and its active‐site mutant PR2_D25N are folded dimers. Addition of twofold excess active‐site inhibitor promotes dimerization of PR2_T26A but not of PR2_1–95, indicating that subunit interactions involving the C‐terminal residues are crucial for dimer formation. Use of SMR and NMR with PR2 facilitates probing for potential inhibitors that restrict protein folding and/or dimerization and, thus, may provide insights for the future design of inhibitors to circumvent drug resistance.     

Ultra-high resolution crystal structure of HIV-1 protease mutant reveals two binding sites for clinical inhibitor TMC114

TMC114 (darunavir) is a promising clinical inhibitor of HIV-1 protease (PR) for treatment of drug resistant HIV/AIDS. We report the ultra-high 0.84 A resolution crystal structure of the TMC114 complex with PR containing the drug-resistant mutation V32I (PR(V32I)), and the 1.22 A resolution structure of a complex with PR(M46L). These structures show TMC114 bound at two distinct sites, one in the active-site cavity and the second on the surface of one of the flexible flaps in the PR dimer. Remarkably, TMC114 binds at these two sites simultaneously in two diastereomers related by inversion of the sulfonamide nitrogen. Moreover, the flap site is shaped to accommodate the diastereomer with the S-enantiomeric nitrogen rather than the one with the R-enantiomeric nitrogen. The existence of the second binding site and two diastereomers suggest a mechanism for the high effectiveness of TMC114 on drug-resistant HIV and the potential design of new inhibitors.     

Multi-drug resistance profile of PR20 HIV-1 protease is attributed to distorted conformational and drug binding landscape: molecular dynamics insights

The PR20 HIV-1 protease, a variant with 20 mutations, exhibits high levels of multi-drug resistance; however, to date, there has been no report detailing the impact of these 20 mutations on the conformational and drug binding landscape at a molecular level. In this report, we demonstrate the first account of a comprehensive study designed to elaborate on the impact of these mutations on the dynamic features as well as drug binding and resistance profile, using extensive molecular dynamics analyses. Comparative MD simulations for the wild-type and PR20 HIV proteases, starting from bound and unbound conformations in each case, were performed. Results showed that the apo conformation of the PR20 variant of the HIV protease displayed a tendency to remain in the open conformation for a longer period of time when compared to the wild type. This led to a phenomena in which the inhibitor seated at the active site of PR20 tends to diffuse away from the binding site leading to a significant change in inhibitor–protein association. Calculating the per-residue fluctuation (RMSF) and radius of gyration, further validated these findings. MM/GBSA showed that the occurrence of 20 mutations led to a drop in the calculated binding free energies (ΔG_bind) by ~25.17 kcal/mol and ~5 kcal/mol for p2-NC, a natural peptide substrate, and darunavir, respectively, when compared to wild type. Furthermore, the residue interaction network showed a diminished inter-residue hydrogen bond network and changes in inter-residue connections as a result of these mutations. The increased conformational flexibility in PR20 as a result of loss of intra- and inter-molecular hydrogen bond interactions and other prominent binding forces led to a loss of protease grip on ligand. It is interesting to note that the difference in conformational flexibility between PR20 and WT conformations was much higher in the case of substrate-bound conformation as compared to DRV. Thus, developing analogues of DRV by retaining its key pharmacophore features will be the way forward in the search for novel protease inhibitors against multi-drug resistant strains.     

Raltegravir flexibility and its impact on recognition by the HIV‐1 IN targets

HIV‐1 IN is a pertinent target for the development of AIDS chemotherapy. The first IN‐specific inhibitor approved for the treatment of HIV/AIDS, RAL, was designed to block the ST reaction. We characterized the structural and conformational features of RAL and its recognition by putative HIV‐1 targets – the unbound IN, the vDNA, and the IN?vDNA complex – mimicking the IN states over the integration process. RAL binding to the targets was studied by performing an extensive sampling of the inhibitor conformational landscape and by using four different docking algorithms: Glide, Autodock, VINA, and SurFlex. The obtained data evidenced that: (i) a large binding pocket delineated by the active site and an extended loop in the unbound IN accommodates RAL in distinct conformational states all lacking specific interactions with the target; (ii) a well‐defined cavity formed by the active site, the vDNA, and the shortened loop in the IN?vDNA complex provide a more optimized inhibitor binding site in which RAL chelates Mg²⁺ cations; (iii) a specific recognition between RAL and the unpaired cytosine of the processed DNA is governed by a pair of strong H‐bonds similar to those observed in DNA base pair G‐C. The identified RAL pose at the cleaved vDNA shed light on a putative step of RAL inhibition mechanism. This modeling study indicates that the inhibition process may include as a first step RAL recognition by the processed vDNA bound to a transient intermediate IN state, and thus provides a potentially promising route to the design of IN inhibitors with improved affinity and selectivity. Copyright © 2013 John Wiley & Sons, Ltd.     

Synthesis,Biological Evaluation,and Molecular Docking Studies of Novel 4‐[4‐Arylpyridin‐1(4H)‐yl]benzoic Acid Derivatives as Anti‐HIV‐1 Agents

The structural similarities between N1 substituted 1,4‐dihydropyridines and the known gp41 inhibitors, NB ‐2 and NB ‐64 , were considered in the current research for the design of some novel anti‐HIV‐1 agents. A series of novel 4‐[4‐arylpyridin‐1(4H)‐yl]benzoic acid derivatives were synthesized and after a comprehensive structural elucidation were screened for in vitro anti‐HIV‐1 activity. Most of the tested compounds displayed moderate to good inhibitory activity against HIV‐1 growth and were evaluated for in vitro cytotoxic activity using XTT assay at the concentration of 100 μm . Among the tested compounds, 1c , 1d and 1e showed potent anti‐HIV‐1 activity against P24 expression at 100 μm with inhibition percentage of 84.00%, 76.42% and 80.50%, respectively. All the studied compounds possessed no significant cytotoxicity on MT‐2 cell line. The binding modes of these compounds to gp41 binding site were determined through molecular docking study. Docking studies proved 1a as the most potent compound and binding maps exhibited that the activities might be attributed to the electrostatic and hydrophobic interactions and additional H‐bonds with the gp41 binding site. The Lipinski's ‘rule of five’ and drug‐likeness criteria were also calculated for the studied compounds. All derivatives obeyed the Lipinski's ‘rule of five’ and had drug‐like features. The findings of this study suggest that novel 4‐[4‐arylpyridin‐1(4H)‐yl]benzoic acid might be a promising scaffold for the discovery and development of novel anti‐HIV‐1 agents.     

Highly conserved glycine 86 and arginine 87 residues contribute differently to the structure and activity of the mature HIV‐1 protease

The structural and functional role of conserved residue G86 in HIV‐1 protease (PR) was investigated by NMR and crystallographic analyses of substitution mutations of glycine to alanine and serine (PR_G86A and PR_G86S). While PR_G86S had undetectable catalytic activity, PR_G86A exhibited ～6000‐fold lower catalytic activity than PR. ¹H‐¹⁵N NMR correlation spectra revealed that PR_G86A and PR_G86S are dimeric, exhibiting dimer dissociation constants (K_d) of ～0.5 and ～3.2 μM, respectively, which are significantly lower than that seen for PR with R87K mutation (K_d > 1 mM). Thus, the G86 mutants, despite being partially dimeric under the assay conditions, are defective in catalyzing substrate hydrolysis. NMR spectra revealed no changes in the chemical shifts even in the presence of excess substrate, indicating very poor binding of the substrate. Both NMR chemical shift data and crystal structures of PR_G86A and PR_G86S in the presence of active‐site inhibitors indicated high structural similarity to previously described PR/inhibitor complexes, except for specific perturbations within the active site loop and around the mutation site. The crystal structures in the presence of the inhibitor showed that the region around residue 86 was connected to the active site by a conserved network of hydrogen bonds, and the two regions moved further apart in the mutants. Overall, in contrast to the role of R87 in contributing significantly to the dimer stability of PR, G86 is likely to play an important role in maintaining the correct geometry of the active site loop in the PR dimer for substrate binding and hydrolysis. Proteins 2010. © 2009 Wiley‐Liss, Inc.     

Solvation effects are responsible for the reduced inhibitor affinity of some HIV-1 PR mutants.

The formulation of HIV-1 PR inhibitors as anti-viral drugs has been hindered by the appearance of protease strains that present drug resistance to these compounds. The mechanism by which the HIV-1 PR mutants lower their affinity for the inhibitor is not yet fully understood. We have applied a modified Poisson-Boltzmann method to the evaluation of the molecular interactions that contribute to the lowering of the inhibitor affinity to some polar mutants at position 82. These strains present drug resistance behavior and hence are ideally suited for these studies. Our results indicate that the reduction in binding affinity is due to the solvation effects that penalize the binding to the more polar mutants. The inhibitor binding ranking of the different mutants can be explained from the analysis of the different components of our free energy scoring function.     

Autocatalytic maturation, physical/chemical properties, and crystal structure of group N HIV-1 protease: Relevance to drug resistance

The mature protease from Group N human immunodeficiency virus Type 1 (HIV‐1) (PR1_N) differs in 20 amino acids from the extensively studied Group M protease (PR1_M) at positions corresponding to minor drug‐resistance mutations (DRMs). The first crystal structure (1.09 Å resolution) of PR1_N with the clinical inhibitor darunavir (DRV) reveals the same overall structure as PR1_M, but with a slightly larger inhibitor‐binding cavity. Changes in the 10s loop and the flap hinge propagate to shift one flap away from the inhibitor, whereas L89F and substitutions in the 60s loop perturb inhibitor‐binding residues 29–32. However, kinetic parameters of PR1_N closely resemble those of PR1_M, and calorimetric results are consistent with similar binding affinities for DRV and two other clinical PIs, suggesting that minor DRMs coevolve to compensate for the detrimental effects of drug‐specific major DRMs. A miniprecursor (TFR 1 - 54 ‐PR1_N) comprising the transframe region (TFR) fused to the N‐terminus of PR1_N undergoes autocatalytic cleavage at the TFR/PR1_N site concomitant with the appearance of catalytic activity characteristic of the dimeric, mature enzyme. This cleavage is inhibited at an equimolar ratio of precursor to DRV (～6 μM), which partially stabilizes the precursor dimer from a monomer. However, cleavage at L34/W35 within the TFR, which precedes the TFR 1 - 54 /PR1_N cleavage at pH ≤ 5, is only partially inhibited. Favorable properties of PR1_N relative to PR1_M include its suitability for column fractionation by size under native conditions and >10‐fold higher dimer dissociation constant (150 nM). Exploiting these properties may facilitate testing of potential dimerization inhibitors that perturb early precursor processing steps.     

Altered Substrate Specificity of Drug-Resistant Human Immunodeficiency Virus Type 1 Protease

Resistance to human immunodeficiency virus type 1 protease (HIV PR) inhibitors results primarily from the selection of multiple mutations in the protease region. Because many of these mutations are selected for the ability to decrease inhibitor binding in the active site, they also affect substrate binding and potentially substrate specificity. This work investigates the substrate specificity of a panel of clinically derived protease inhibitor-resistant HIV PR variants. To compare protease specificity, we have used positional-scanning, synthetic combinatorial peptide libraries as well as a select number of individual substrates. The subsite preferences of wild-type HIV PR determined by using the substrate libraries are consistent with prior reports, validating the use of these libraries to compare specificity among a panel of HIV PR variants. Five out of seven protease variants demonstrated subtle differences in specificity that may have significant impacts on their abilities to function in viral maturation. Of these, four variants demonstrated up to fourfold changes in the preference for valine relative to alanine at position P2 when tested on individual peptide substrates. This change correlated with a common mutation in the viral NC/p1 cleavage site. These mutations may represent a mechanism by which severely compromised, drug-resistant viral strains can increase fitness levels. Understanding the altered substrate specificity of drug-resistant HIV PR should be valuable in the design of future generations of protease inhibitors as well as in elucidating the molecular basis of regulation of proteolysis in HIV.     

Fullerene‐based inhibitors of HIV‐1 protease

A series of Fmoc‐Phe(4‐aza‐C₆₀)‐OH of fullerene amino acid derived peptides have been prepared by solid phase peptide synthesis, in which the terminal amino acid, Phe(4‐aza‐C₆₀)‐OH, is derived from the dipolar addition to C₆₀ of the Fmoc‐Nα‐protected azido amino acids derived from phenylalanine: Fmoc‐Phe(4‐aza‐C₆₀)‐Lys₃‐OH ( 1 ), Fmoc‐Phe(4‐aza‐C₆₀)‐Pro‐Hyp‐Lys‐OH ( 2 ), and Fmoc‐Phe(4‐aza‐C₆₀)‐Hyp‐Hyp‐Lys‐OH ( 3 ). The inhibition constant of our fullerene aspartic protease PRIs utilized FRET‐based assay to evaluate the enzyme kinetics of HIV‐1 PR at various concentrations of inhibitors. Simulation of the docking of the peptide Fmoc‐Phe‐Pro‐Hyp‐Lys‐OH overestimated the inhibition, while the amino acid PRIs were well estimated. The experimental results show that C₆₀‐based amino acids are a good base structure in the design of protease inhibitors and that their inhibition can be improved upon by the addition of designer peptide sequences. Copyright © 2015 European Peptide Society and John Wiley & Sons, Ltd.     

Design,Synthesis, and Anti‐HIV‐1 Evaluation of a Novel Series of 1,2,3,4‐Tetrahydropyrimidine‐5‐Carboxylic Acid Derivatives

A series of tetrahydropyrimidine derivatives ( 2a – 2l ) were designed, synthesized, and screened for anti‐HIV‐1 properties based on the structures of HIV‐1 gp41 binding site inhibitors, NB ‐2 and NB ‐64 . A computational study was performed to predict the pharmacodynamics, pharmacokinetics, and drug‐likeness features of the studied molecules. Docking studies revealed that the carboxylic acid group in the molecules forms salt bridges with either Lys574 or Arg579. Physiochemical properties (e.g., molecular weight, number of hydrogen bond donors, number of hydrogen bond acceptors, and number of rotatable bonds) of the synthesized compounds confirmed and exhibited that these compounds were within the range set by Lipinski's rule of five. Compounds 2e and 2k with 4‐chlorophenyl substituent and 4‐methylphenyl group at C(4) position of the tetrahydropyrimidine ring was the most potent one among the tested compounds. This suggests that these compounds may serve as leads for development of novel small‐molecule HIV‐1 inhibitors.     

Identification of a PAI‐1‐binding site within an intrinsically disordered region of vitronectin

The serine protease inhibitor, plasminogen activator inhibitor Type‐1 (PAI‐1) is a metastable protein that undergoes an unusual transition to an inactive conformation with a short half‐life of only 1–2 hr. Circulating PAI‐1 is bound to a cofactor vitronectin, which stabilizes PAI‐1 by slowing this latency conversion. A well‐characterized PAI‐1‐binding site on vitronectin is located within the somatomedin B (SMB) domain, corresponding to the first 44 residues of the protein. Another PAI‐1 recognition site has been identified with an engineered form of vitronectin lacking the SMB domain, yet retaining PAI‐1 binding capacity (Schar, Blouse, Minor, Peterson. J Biol Chem. 2008;283:28487–28496). This additional binding site is hypothesized to lie within an intrinsically disordered domain (IDD) of vitronectin. To localize the putative binding site, we constructed a truncated form of vitronectin containing 71 amino acids from the N‐terminus, including the SMB domain and an additional 24 amino acids from the IDD region. This portion of the IDD is rich in acidic amino acids, which are hypothesized to be complementary to several basic residues identified within an extensive vitronectin‐binding site mapped on PAI‐1 (Schar, Jensen, Christensen, Blouse, Andreasen, Peterson. J Biol Chem. 2008;283:10297–10309). Steady‐state and stopped‐flow fluorescence measurements demonstrate that the truncated form of vitronectin exhibits the same rapid biphasic association as full‐length vitronectin and that the IDD hosts the elusive second PAI‐1 binding site that lies external to the SMB domain of vitronectin.     

Effect of flap mutations on structure of HIV-1 protease and inhibition by saquinavir and darunavir

HIV-1 (human immunodeficiency virus type 1) protease (PR) and its mutants are important antiviral drug targets. The PR flap region is critical for binding substrates or inhibitors and catalytic activity. Hence, mutations of flap residues frequently contribute to reduced susceptibility to PR inhibitors in drug-resistant HIV. Structural and kinetic analyses were used to investigate the role of flap residues Gly48, Ile50, and Ile54 in the development of drug resistance. The crystal structures of flap mutants PR_I50V (PR with I50V mutation), PR_I54V (PR with I54V mutation), and PR_I54M (PR with I54M mutation) complexed with saquinavir (SQV) as well as PR_G48V (PR with G48V mutation), PR_I54V, and PR_I54M complexed with darunavir (DRV) were determined at resolutions of 1.05-1.40 Å. The PR mutants showed changes in flap conformation, interactions with adjacent residues, inhibitor binding, and the conformation of the 80s loop relative to the wild-type PR. The PR contacts with DRV were closer in PR_G48V-DRV than in the wild-type PR-DRV, whereas they were longer in PR_I54M-DRV. The relative inhibition of PR_I54V and that of PR_I54M were similar for SQV and DRV. PR_G48V was about twofold less susceptible to SQV than to DRV, whereas the opposite was observed for PR_I50V. The observed inhibition was in agreement with the association of G48V and I50V with clinical resistance to SQV and DRV, respectively. This analysis of structural and kinetic effects of the mutants will assist in the development of more effective inhibitors for drug-resistant HIV.     

Relation between flexibility and positively selected HIV‐1 protease mutants against inhibitors

The antiretroviral chemotherapy helps to reduce the mortality of HIVs infected patients. However, RNA dependant virus replication has a high mutation rate. Human immunodeficiency virus Type 1 protease plays an essential role in viral replication cycle. This protein is an important target for therapy with viral protein inhibitors. There are few works using normal mode analysis to investigate this problem from the structural changes viewpoint. The investigation of protein flexibility may be important for the study of processes associated with conformational changes and state transitions. The normal mode analysis allowed us to investigate structural changes in the protease (such as flexibility) in a straightforward way and try to associate these changes with the increase of fitness for each positively selected HIV‐1 mutant protease of patients treated with several protease inhibitors (saquinavir, indinavir, ritonavir, nelfinavir, lopinavir, fosamprenavir, atazanavir, darunavir, and tripanavir) in combination or separately. These positively selected mutations introduce significant flexibility in important regions such as the active site cavity and flaps. These mutations were also able to cause changes in accessible solvent area. This study showed that the majority of HIV‐1 protease mutants can be grouped into two main classes of protein flexibility behavior. We presented a new approach to study structural changes caused by positively selected mutations in a pathogen protein, for instance the HIV‐1 protease and their relationship with their resistance mechanism against known inhibitors. The method can be applied to any pharmaceutically relevant pathogen proteins and could be very useful to understand the effects of positively selected mutations in the context of structural changes. Proteins 2012; © 2012 Wiley Periodicals, Inc.     

Profiling the interaction of 1‐phenylbenzimidazoles to cyclooxygenases

In the design of 1‐phenylbenzimidazoles as model cyclooxygenase (COX) inhibitors, docking to a series of crystallographic COX structures was performed to evaluate their potential for high‐affinity binding and to reproduce the interaction profile of well‐known COX inhibitors. The effect of ligand‐specific induced fit on the calculations was also studied. To quantitatively compare the pattern of interactions of model compounds to the profile of several cocrystallized COX inhibitors, a geometric parameter, denominated ligand‐receptor contact distance (LRCD), was developed. The interaction profile of several model complexes showed similarity to the profile of COX complexes with inhibitors such as iodosuprofen, iodoindomethacin, diclofenac, and flurbiprofen. Shaping of high‐affinity binding sites upon ligand‐specific induced fit mostly determined both the affinity and the binding mode of the ligands in the docking calculations. The results suggest potential of 1‐phenylbenzimidazole derivatives as COX inhibitors on the basis of their predicted affinity and interaction profile to COX enzymes. The analyses also provided insights into the role of induced fit in COX enzymes. While inhibitors produce different local structural changes at the COX ligand binding site, induced fit allows inhibitors in diverse chemical classes to share characteristic interaction patterns that ensure key contacts to be achieved. Different interaction patterns may also be associated with different inhibitory mechanisms.     

Development and evaluation of human T‐cell leukemia virus‐1 and ‐2 multiplex quantitative PCR

The diagnosis of human T ‐cell leukemia virus type 1 (HTLV‐1) infection in Japan is usually performed by serological testing, but the high rate of indeterminate results from western blotting makes it difficult to assess the infection accurately. Nucleic acid tests for HTLV‐1 and/or HTLV‐2 are used to confirm infection with HTLV‐1 and/or HTLV‐2 and are also used for the follow‐up of HTLV‐1 related diseases. To prepare a highly sensitive method that can discern infection with HTLV‐1 and HTLV‐2, a multiplex quantitative polymerase chain reaction (qPCR) by large‐scale primer screening was developed. Sensitivity and specificity were evaluated by serial dilution of cell lines and by testing with known clinical samples. The resulting multiplex qPCR can detect about four copies of HTLV‐1 provirus per 10⁵ cells. Moreover, HTLV‐1 provirus could be detected in 97.2% (205 of 211) of HTLV‐1 seropositive clinical samples. These sensitivities were sufficiently high compared with the methods reported previously. Also, all the HTLV‐2 seropositive clinical samples tested were found to be positive by this method (three of three). In conclusion, this method can successfully and simultaneously detect both types of HTLV‐1 and HTLV‐2 provirus with extremely high sensitivity.