CC chemokine receptor 5 (CCR5), a member of G protein-coupled receptors (GPCRs), not only plays a significant role in inflammatory responses, but also correlates with HIV-1 infection and cancer progression. Recently, blocking of CCR5 has been considered as an effective strategy in HIV-1/cancers therapy. So far, only Maraviroc has been approved by FDA in 2007, while the other CCR5 inhibitors have failed in their clinical trials. In this study, a highly selective structure-based pharmacophore model was constructed, validated, and applied for virtual screening to retrieve novel CCR5 inhibitors from NCI database. Finally, one potential CCR5 inhibitor candidate, NSC13165, was identified after molecular docking, molecular dynamics (MD) simulations, binding free energy analyses and ADMET prediction. Docking and MD simulation results not only suggested that NSC13165 reserves the common binding mode of the most known CCR5 inhibitors, but also provided important insights toward the allosteric inhibition mechanism of CCR5. The results of binding free energy analyses indicated that the binding affinity of NSC13165 is much better than that of Maraviroc and that van der Waals interaction is the key driving force during the binding process. ADMET prediction suggested that NSC13165 exhibits very low risk of causing lethal side effects. Altogether, our results strongly suggest that NSC13165 has great potential to serve as a novel CCR5 inhibitor, which may be further tested in vitro/in vivo as a drug target for HIV-1/cancers therapy or be used as a lead compound for improving its efficacy through chemical modifications.
CC chemokine receptor 5 (CCR5), a member of the seven-transmembrane domain G protein-coupled receptors (GPCRs) family, is mainly expressed on the surface of white blood cells and plays an important role in the human inflammatory responses to infection. Besides, CCR5 also involves in many autoimmune diseases, such as organ transplant rejection [
The discovery and implication of CCR5 in HIV-1 infection, cancer progression and several inflammatory diseases have triggered the development of various CCR5 inhibitors, such as Maraviroc [
In the past few years, due to the lack of CCR5 crystal structure, the strategies for developing novel CCR5 inhibitors were limited to ligand-based level, such as quantitative-structure activity relationship (QSAR) [
The crystal structure of the CCR5-Maraviroc binding complex (PDB ID: 4MBS) [
A group of 41 known CCR5 inhibitors, characterized by their excellent experimental performances (IC50 ≤ 10 nM), including Maraviroc, Ancriviroc, Aplaviroc, INCB-9471 and SCH-350634 (
In this study, both LibDock and CDOCKER embedded in DS 2016 and Schrödinger Maestro 11.3 were employed for molecular docking experiments and data analyses. LibDock was used for rapid rigid docking of the screened compounds while CDOCKER was used for more accurate and precise flexible docking. Before our docking experiments, Maraviroc was removed from the refined 4MBS structure and the binding site was defined as a sphere radius of 10 Å from the position of Maraviroc. Most of the docking parameters were set to default for both LibDock and CDOCKER, except for the conformation parameter, which was set to Fast for LibDock.
To obtain comprehensive information of the ligand-receptor binding complexes, each of the 40 known inhibitors (except Maraviroc) was docked into the CCR5 binding site and a maximum of 10 binding poses was generated using CDOCKER. Among these docking poses, only 64 out of 400 poses that contained similar CCR5 binding interactions [23 , 40 - 45] along with the refined 4 MBS were selected for the generation of structure-based pharmacophore models using the Common Feature Pharmacophore Generation of DS 2016. For each binding complex, a maximum of 10 pharmacophore models with 4 - 6 pharmacophore features were automatically generated using default parameters. Finally, a total of 38 structure-based pharmacophore models were constructed.
To select the best pharmacophore model among these 38 structure-based pharmacophore models, a test 3D database comprising both 41 known CCR5 inhibitors and 393 decoys was constructed using Build 3D Database (maximum 255 conformations for each compound) of DS 2016. Then, these models were used for screening the test 3D database using Screen Library with default parameters except that energy threshold was set to 5 in DS 2016. The screening results of each model were evaluated using the Güner-Henry scoring method [
To enhance the drug-likeness of our screening result, the prepared NCI database was filtered by the Lipinski rule of five and Veber rule using DS 2016. Then the filtered NCI database was built into 3D database (maximum 255 conformations for each compound) for virtual screening by Model_1 using Screen Library protocol of DS 2016. Compounds that successfully mapped all the pharmacophore features of Model_1 were considered as potential hits, which were further submitted to molecular docking studies with LibDock and CDOCKER. Finally, only compounds that map well with Model_1, have higher docking scores comparing to inhibitor A, and contain similar binding mode and critical interactions with the key residues were considered as potential CCR5 inhibitor candidates.
After virtual screening, the CDOCKER binding complex of each potential CCR5 inhibitor candidate was used as the initial conformation for MD simulations to ensure the optimal molecular interactions with CCR5. All MD simulations were performed using GROMACS 2016.3 [
The molecular mechanics energies combined with the Poisson-Boltzmann and surface area continuum solvation (MM/PBSA) method was applied to calculate the binding free energies through g_mmpbsa for GROMACS-5.1.X [
Many drug candidates have failed in the early stage of clinical trials due to poor ADME or toxicity profile [
During the early stage of CCR5 inhibitor development, lethal side effects, bad ADMET properties and lack of efficacy are the major problems in clinical trials [
Structure-based pharmacophore models are derived from the structure of the target protein-ligand complex by investigating important interaction and excluded volumes in the binding site and translated into pharmacophore features. Comparing to 3D QSAR and ligand-based approaches, structure-based approach has advantages of more precise prediction, good filter to remove decoys and finding structurally novel ligands [
| Parameters | Model_1 |
|---|---|
| Total molecules (D) | 434 |
| Total actives (A) | 41 |
| Total hits (Ht) | 47 |
| True positives (Ha) | 40 |
| True negatives | 386 |
| False negatives | 1 |
| False positives | 7 |
| Sensitivity | 0.976 |
| Specificity | 0.982 |
| Goodness of hit (GH) score* | 0.866 |
* G H = ( H a ( 3 A + H t ) 4 H t A ) ( 1 − H t − H a D − A ) . GH score higher than 0.7 suggests a very good pharmacophore model.
Virtual screening is a useful technique to discover potential candidates that are able to block or trigger the activity of the selected drug target. Comparing to docking-based virtual screening, pharmacophore-based virtual screening considers more about protein flexibility and reduces the impact of insufficiently designed or optimized docking scoring functions [
Molecular docking was performed to investigate the binding conformation of each selected compound. To obtain the hits with better binding affinity, the LibDock score (118.396) and CDOCKER score (CDOCKER interaction energy, −50.6996 kcal・mol−1) of inhibitor A were set as threshold values (
Recent studies have indicated that CCR5 inhibitors are allosteric inhibitors, sharing a similar binding site on CCR5 [45 , 57]. The known CCR5 inhibitors all establish an extensive binding interaction network with several CCR5 key residues in the binding pocket, such as Leu33, Tyr37, Trp86, Tyr108, Phe109, Phe112, Gln194, Thr195, Ile198, Trp248, Tyr251, Glu283, Thr284 and Met287 [23 , 40 , 44 , 45 , 57 - 60]. Through the site-specific mutagenesis studies, Trp86, Tyr108, Ile198, Tyr251 and Glu283 have been identified as critical residues for CCR5 inhibition [45 , 57]. Among these critical residues, Glu283 is the most important residue for CCR5 inhibition. Besides, the π-π stacking interactions between Trp86, Tyr108 and Phe109 residues of CCR5 and ligands also help to stabilize the binding process [
Molecular dynamics (MD) simulations are able to predict the atomic motion of protein-ligand complex, such as identification of the binding site, validation of the docking results and calculation of the binding free energy, and thus play an important role in drug discovery. To determine and compare the binding stabilities of compounds 1-7, inhibitor A and Maraviroc, their CDOCKER docking complexes were subjected to 50 ns MD simulations (MD I) in an explicit hydration environment.
The dynamic stabilities and MD simulation trajectories of these complexes were explored by their backbone root-mean-square deviations (RMSD). Backbone RMSD with small fluctuations and constant value suggests a stable binding system. As shown in
To explore the protein residues flexibility throughout the MD simulation, the root-mean-squared fluctuations (RMSF) of individual CCR5 residues were calculated. As shown in
Binding affinity describes the interactions of the ligands with the binding pocket, which can be evaluated through binding free energy calculation. In general, compounds with high binding affinities have a higher degree of ligand occupancy in the binding site than compounds with low binding affinities. Thus, binding free energies (ΔGbind) of compounds 1-7, inhibitor A and Maraviroc were further calculated to determine their binding affinities towards CCR5 using g_mmpbsa in this study and the results are shown in
Prediction of the compound ADMET properties describes the disposition of a pharmaceutical compound within the human body. Considering that most of previously developed CCR5 inhibitors failed in their clinical trials due to bad ADMET properties [
Since the US Food and Drug Administration (FDA) published the first in vitro/in vivo drug interaction guidance documents in 1997 and 1999, respectively, off-target transporter interactions and drug-drug interactions (DDIs) have become the major challenges for drug development [
Based on the ADMET prediction, compound 1 not only exhibits better ADMET properties than that of Maraviroc, but also shows great improvement in lowering the risk of causing both lethal CYP450 superfamily inhibition and hERG inhibition. Combining with the results of MD I, binding free energy calculation and ADMET prediction, compound 1 is considered as the most potential CCR5 inhibitor candidate.
| Compds. Properties | Maraviroc | 1 | 2 | 3 | 4 | 5 | 6 | 7 |
|---|---|---|---|---|---|---|---|---|
| Human Intestinal Absorption a | + | + | − | + | + | + | + | + |
| Blood Brain Barrier b | + | + | − | + | + | + | − | − |
| Renal organic cation transporter c | − | − | − | − | − | − | − | − |
| CYP450 1A2 inhibitor c | − | − | − | − | − | − | − | − |
| CYP450 2C9 inhibitor c | + | − | − | + | + | − | + | + |
| CYP450 2D6 inhibitor c | − | − | − | − | − | − | − | − |
| CYP450 2C19 inhibitor c | + | − | − | + | − | − | − | − |
| CYP450 3A4 inhibitor c | + | − | − | − | − | + | − | − |
| CYP450 inhibitory promiscuity | high | low | low | high | high | low | high | high |
| hERG inhibition I c | − | − | − | − | − | − | − | − |
| hERG inhibition II c | + | − | − | + | + | + | + | + |
| Ames test d | − | − | − | + | + | − | − | − |
| Carcinogenicity e | − | − | − | − | − | − | − | − |
| Aqueous solubility (Log S) | −3.7479 | −3.8727 | −2.4736 | −3.9044 | −3.7491 | −3.3937 | −4.3616 | −4.1589 |
a+ for positive and − for negative. b+ for penetrable and − for non-penetrable. c+ for inhibitor and − for non-inhibitor. d+ for toxic and − for non-toxic. e+ for carcinogens and − for non-carcinogens.
To gain insights into the binding interaction between CCR5 and its inhibitors, the initial binding complexes of compound 1 and Maraviroc were investigated through their 3D structures and 2D-interaction maps (
The 2D-interaction maps showed that Maraviroc formed one hydrogen bond with Glu283 (
The results of binding interaction analyses indicate that compound 1 and Maraviroc share similar binding interactions with CCR5 although compound 1 exhibits a totally different chemical structure than Maraviroc (see
To ensure the reliability and precision of MD simulations and binding free energy calculations, the MD production of both compound 1 and Maraviroc were extended from 50 ns in MD I to 200 ns in MD II. In order to explore the dynamic stability of CCR5-inhibitor complexes, the RMSD values of the entire systems and RMSF values of each CCR5 residue were investigated. The total binding free energy were also decomposed into four individual free energy components and break down into the contribution from each residue to elucidate the binding mechanism in detail. Comparing to molecular docking, these MD-based analyses allow to provide the important insights of the allosteric mechanism of CCR5 inhibition and validate the binding affinity of the selected CCR5 inhibitor.
1) RMSD Analysis
To monitor the overall stability of the binding complexes, the RMSD values of the entire protein-ligand backbone atoms were calculated. As shown in
2) RMSF Analysis
The RMSF provides a measure of CCR5 local flexibility after binding with allosteric CCR5 inhibitors. The results of RMSF analyses for compound 1 and Maraviroc are given in
The RMSF values of CCR5 key residues (Leu33, Tyr37, Trp86, Tyr108, Phe109, Phe112, Gln194, Thr195, Ile198, Trp248, Tyr251, Glu283, Thr284 and Met287) were also investigated. As shown in
| Compds. | ΔGvdw | ΔGelec | ΔGpolar | ΔGnonpolar | ΔGbinding |
|---|---|---|---|---|---|
| Maraviroc | −61.39 | −11.42 | 48.38 | −50.71 | −75.14 |
| 1 | −73.57 | −33.19 | 73.60 | −55.51 | −88.67 |
*all energies were calculated by g_mmpbsa and in kcal・mol−1.
3) Binding Free Energy Calculation
Binding free energy was calculated by the MM/PBSA method, which provides more detailed information on the interactions of compound 1 and Maraviroc towards CCR5. Negative values for binding free energies indicate high thermodynamic stability and good binding affinity. Higher binding affinity of a drug target indicates lower concentration required during treatment, which can reduce the risk of side effects caused by binding to off-target proteins. The results of the predicted binding free energies and energy components of compound 1 and Maraviroc from MD II are shown in
4) Binding Free Energy Decomposition Analysis
Binding free energy can be decomposed into four individual components (ΔGvdw, ΔGelec, ΔGpolar and ΔGnonpolar) to investigate the effect of these energy terms toward binding.
Although CCR5 inhibitors have been proven to exhibit great potential in the treatment of HIV-1 infection and cancer progressions, the only FDA-approved Maraviroc still has a risk of causing life-threatening side effects, including heart attack, skin reaction, liver damage, and allergic reaction [
The authors thank the Ministry of Science and Technology (MOST 104-2221-E-027 -073 -MY3) and National Taipei University of Technology and Taipei Medical University (NTUT-TMU-101-10 and NTUT-TMU-102-10) for their financial supports.
The authors declare no conflicts of interest regarding the publication of this paper.