Molecular docking analysis of curcumin analogues as human neutrophil elastase inhibitors

  • Radhakrishnan Narayanaswamy Laboratory of Natural Products, Institute of Bioscience (IBS), Universiti Putra Malaysia (UPM), 43400 Serdang, Selangor, Malaysia
  • Lam Kok Wai Faculty of Pharmacy, Universiti Kebangsaan Malaysia (UKM), Jalan Raja Muda Abdul Aziz, 50300 Kuala Lumpur, Malaysia
  • Faridah Abas Laboratory of Natural Products, Institute of Bioscience (IBS), Universiti Putra Malaysia (UPM), 43400 Serdang, Selangor, Malaysia and Department of Food Science, Faculty of Food Science and Technology, Universiti Putra Malaysia (UPM), 43400 Serdang, Selangor, Malaysia
  • Intan Safinar Ismail Laboratory of Natural Products, Institute of Bioscience (IBS), Universiti Putra Malaysia (UPM), 43400 Serdang, Selangor, Malaysia and Department of Chemistry, Faculty of Science, Universiti Putra Malaysia (UPM), 43400 Serdang, Selangor, Malaysia
Keywords: Anti-inflammatory, Curcumin analogue, Docking, Human neutrophil elastase
DOI: 10.3329/bjp.v9i1.17474

Abstract

In the present study, we aimed to dock 17 different ligands of curcumin analogues with that of human neutrophil elastase. Molecular descriptors analysis using Molinspiration online tool was carried out including investigation on human neutrophil elastase putative binding sites using Discovery Studio. The molecular physicochemical analysis revealed that all of the curcumin analogues complied well with the five rules of thumb. With regard to bioactivity score, compound 17 has exhibited least score towards nuclear receptor ligand (0.05) and enzyme inhibitor (0.10) compared to all other ligands. Compounds 2, 4 and 13 exhibited the maximum interaction energy (-40 kcal/mol). Interestingly, seven compounds namely 3, 11-14, 16 and 17 interacted well with Arg147 amino acid residue. The present study outcomes therefore might provide new insight in understanding these 17 curcumin analogues as potential candidates for human neutrophil elastase inhibitory agents.

Introduction

Curcumin has a salient chemical structure containing two ferulic acid residues joined by a methylene bridge. It has two hydrophobic phenyl domains that are connected by a flexible (seven carbon) linker. Although curcumin has unique structure feature, however it lacks in stability (Wang et al., 1997) and bioavailability features (Gupta et al., 2011). Hence, numerous curcumin analogues were synthesized wherein to-date several natural and synthetic analogues of curcumin have been reported to possess therapeutic applications (Furnessb et al., 2005) in which some of them are used as potential anti-inflammatory agents (Mukhopadhyay et al., 1982). Molecular docking studies have found that curcumin can adopt many different structural conformations suitable for maximizing hydrophobic contacts with the macromolecule to which it is bound. For instance, the phenyl rings of curcumin can participate in π-π van der Waals interactions with aromatic amino acid side chains of macromolecules. Even though curcumin generally is hydrophobic in nature, the phenolic and carbonyl moiety located at the end and the center of the molecule could participate in hydrogen bonding with that of targeted macromolecules. The keto-enol tautomerization also contributes to curcumin additional unique chemical functionality with a strong and direct electrostatic interaction to increase favorable free energies of association. Molecular modeling study carried out by Nirmal et al (2008) showed that curcumin could bind at the active site of bovine pancreatic phospholipase A2 (PLA2) which is one of the key enzymes in inflammatory pathway. A few other reports also supported that curcumin and its analogues could bind to various enzymes which includes human immunodeficiency virus type-I protease (Sui et al., 1993), cyclooxygenase-1 (Selvam et al., 2005), DNA polymerase λ (Takeuchi et al., 2006), platelet-12-lipoxygenase (Jankun et al., 2006), cyclooxygenase-2 (Padhye et al., 2009), DNA methyl transferase-1 (Liu et al., 2009), xanthine oxidase (Shen and Ji, 2009), dipeptydyl peptidase-4 (Istyastono, 2009), glycogen synthase kinase-3β (Bustanji et al., 2009), ribonuclease A (Sahoo et al., 2009), glyoxalase-I (Liu et al., 2010), protein kinase C (Majhi et al., 2010) and matrix metalloproteinases (Girija et al., 2010).

Although curcumin and analogues have been reported to bind with various enzymes, till date no report is available for human neutrophil elastase inhibitory activity. Human neutrophil elastase has recently gained a lot of attention worldwide as it has a potential therapeutic target for the treatment of inflammation-related diseases. This prompted us to carry out the present study on a selected 17 curcumin analogues among the 47 which were grouped under three major types of a) pentadiene-3-one, b) dibenzyldiene cyclohexanone and c) dibenzyldiene cyclopentanone. Some of these compounds were subsequently reported for various biological activities such as anti-inflammatory, antioxidant, anti-tyrosinase (Lee et al., 2009), chemotactic (Jantan et al., 2011) and anti-melanogenesis (Hosoya et al., 2012). The selected compounds are a) 2,5-bis (2,3-dimethoxy benzylidene) cyclopentanone; b) 2,6-bis (3,4,5-trimethoxy benzylidene) cyclohexanone; c) 2,6-bis (2,4,6-trimethoxy benzylidene) cyclohexanone; d) 2,6-bis (2,3,4-trimethoxybenzylidene) cyclohexa-none; e) 2,6-bis (2,6-dimethoxy benzylidene) cyclohexanone; f) 2,6-bis (2,5-dimethoxy benzylidene) cyclohexanone; g) 2,6-bis (2,4-dimethoxybenzylidene) cyclohexanone; h) 2,6-bis (2,3-dimethoxy benzylidene) cyclohexanone; i) 2,6-bis (benzylidene) cyclohexanone; j) 2,6-bis (4-hydroxy benzylidene) cyclohexanone; k) 2,6-bis (4-hydroxy-3-methoxy benzylidene) cyclohexanone; l) 1,5-diphenyl-(E, E)-1,4 pentadiene-3-one; l) 1,5-bis (2,4,6-trimethoxy phenyl)-1,4-pentadiene-3-one; m) 1,5-bis (2,6-dimethoxy phenyl)-1,4-pentadiene-3-one; n) 1,5-bis (2,4-dimethoxy phenyl)-1,4-pentadiene-3-one; o) 1,5-bis (2,3-dimethoxy phenyl)-1,4-pentadiene-3-one and p) 1,5-bis (2-hydroxyphenyl)-1,4-pentadiene-3-one, were evaluated on the docking behaviour of human neutron-phil elastase. Investigation was also done on human neutrophil elastase putative binding sites using Discovery Studio Version 3.1 whereby the results from the present study would give some useful information for the researchers to design potent and selective human neutrophil elastase inhibitors of curcumin analogues in the near future.

Materials and Methods

Target protein identification and preparation:

The three dimensional structure of the human neutrophil elastase (PDB ID: 1H1B with resolution of 2.00 Ã…) was obtained from the Research collaborator for structural bioinformatics (RCSB) Protein data bank (www.rcsb.org). A chain of protein was pre-processed separately by deleting the chain B, ligand, as well as the crystallographically observed water molecules (water without hydrogen bonds).

Molecular descriptors calculation:

Molinspiration online database was used to calculate thirteen descriptors (www.molinspiration.com), which are logP, polar surface area, molecular weight, number of atoms, number of O or N, number of OH or NH, number of rotatable bonds, volume, drug likeness includes G protein coupled receptors (GPCR) ligand, ion channel modulator, kinase inhibitor and nuclear receptor ligand, and number of violations to Lipinski’s rule, for all selected ligands except two (2,6-bis (4-hydroxy benzylidene) cyclohexanone and 2,6-bis (4-hydroxy-3-methoxy benzylidene) cyclohexanone) which have been reported earlier.

Docking studies:

Docking studies were carried out on the crystal structure of human neutrophil elastase retrieved from Protein Data Bank using the CDOCKER protocol under the protein-ligand interaction section in Discovery Studio® 3.1 (Accelrys, San Diego, USA). In general, CDOCKER is a grid-based molecular docking method that employs CHARMM force fields. This protein was firstly held rigid while the ligands were allowed to flex during the refinement. Two hundred random ligand conformations were then generated from the initial ligand structure through high temperature molecular dynamics, followed by random rotations, refinement by grid-based (GRID I) simulated annealing, and a final grid-based or full force field minimisation (Wu et al., 2003). In this experiment, the ligand was heated to a temperature of 700 K in 2,000 steps. The cooling steps were set to 5,000 steps with 300 K cooling temperature. The grid extension was set to 10 Å. Hydrogen atoms were added to the structure and all ionisable residues were set at their default protonation state at a neutral pH. For each ligand, top ten ligand binding poses were ranked according to their CDOCKER energies, and the predicted binding interactions were analysed.

Result and Discussion

Medicinal and computational chemists proposed the concept of “drug-likeness”, which is valuable tool to select more promising lead candidates by predicting (or) evaluating their drug-likeness property in the early stage of drug discovery and development (Lipinski et al., 2001). The rules of drug-likeness were proposed by analyzing the physic-chemical properties of known drugs. The most famous drug-likeness filter is Lipinski’s “rule-of-five”. In the present study violation of Lipinski’s “rule-of-five” was recorded using Molinspiration online tool, if Log P ˃5, Molecular weight (MW) ˃500, number of N and O (hydrogen bond acceptors) ˃10, number of OH and NH (hydrogen bond donors) ˃5 and number of rotatable bonds ˃15. Interestingly, all the 15 ligands complied with five rules of thumb as tabulated in Table I.

Table I: Molecular descriptors analysis of 15 ligands using Molinspiration online software tool

Ligand Log Aa TPSAb Natomsc MWd noNe nOH NHf Nviolationsg Nrotbh Volumei
Compound 1 3.74 54.00 28 380 5 0 0 6 354.2
Compound 2 4.23 72.47 33 454 7 0 0 8 422.1
Compound 3 4.66 72.47 33 454 7 0 0 8 422.1
Compound 4 4.26 72.47 33 454 7 0 0 8 422.1
Compound 5 4.64 54.00 29 394 5 0 0 6 371.0
Compound 6 4.69 54.00 29 394 5 0 0 6 371.0
Compound 7 4.69 54.00 29 394 5 0 0 6 371.0
Compound 8 4.24 54.00 29 394 5 0 0 6 371.0
Compound 9 4.96 17.00 21 274 1 0 0 2 268.8
Compound 12 4.18 17.07 18 234 1 0 0 4 229.2
Compound 13 3.87 72.47 30 414 7 0 0 10 382.5
Compound 14 3.86 54.00 26 354 5 0 0 8 331.4
Compound 15 3.90 54.00 26 354 5 0 0 8 331.4
Compound 16 3.46 54.00 26 354 5 0 0 8 331.4
Compound 17 3.70 57.00 20 266 3 2 0 4 245.3
aOctanol-Water partition coefficient; bPolar surface area; cNumber of non hydrogen atoms; dMolecular weight; eNumber of hydrogen bond acceptors [O and N atoms]; fNumber of hydrogen bond donors [OH and NH groups]; gNumber of rule of 5 violations; hNumber of rotatable bonds; iMolecular volume

The molecular physicochemical and the drug-likeness properties of two ligands which are 2, 6-bis (4-hydroxy benzylidene) cyclohexanone (Lam et al., 2012) and 2, 6-bis (4-hydroxy-3-methoxy benzylidene) cyclohexanone (Lam et al., 2012; Sangeetha et al., 2013) were already been reported. In addition, Sangeetha et al. (2013) also has reported the molecular physicochemical and the drug-likeness properties of curcumin, the parent compound.

With regard to bioactivity score, 1, 5-bis (2-hydroxy phenyl)-1,4-pentadiene-3-one (compound 17) has exhibited least score towards nuclear receptor ligand (0.05) and enzyme inhibitor (0.10) compared to all other ligands as shown in the Table II.

Table II:Bioactivity score calculation of 15 ligands using Molinspiration online software tool

Ligand GPCR ligand Ion channel modulator Kinase inhibitor Nuclear receptor ligand Protease inhibitor Enzyme inhibitor
Compound 1 -0.29 -0.25 -0.38 -0.11 -0.13 -0.07
Compound 2 -0.12 -0.24 -0.28 -0.13 -0.08 -0.02
Compound 3 -0.10 -0.27 -0.28 -0.08 -0.04 0.01
Compound 4 -0.13 -0.27 -0.31 -0.16 -0.11 -0.06
Compound 5 -0.11 -0.29 -0.32 -0.11 -0.03 0.01
Compound 6 -0.12 -0.29 -0.35 -0.06 -0.08 -0.05
Compound 7 -0.12 -0.29 -0.34 -0.05 -0.08 -0.04
Compound 8 -0.13 -0.29 -0.36 -0.14 -0.10 -0.06
Compound 9 -0.14 -0.26 -0.44 -0.13 -0.09 0.03
Compound 12 -0.25 -0.27 -0.37 -0.17 -0.27 0.04
Compound 13 -0.08 -0.28 -0.14 -0.00 -0.04 0.04
Compound 14 -0.08 -0.30 -0.16 -0.03 -0.04 0.05
Compound 15 -0.09 -0.30 -0.18 0.04 -0.09 -0.01
Compound 16 -0.11 -0.30 -0.20 -0.06 -0.11 -0.03
Compound 17 -0.13 -0.26 -0.23 0.05 -0.15 0.10

Human neutrophil elastase is a 30kD molecular weight glycoprotein and synthesized as zymogen (proform), which becomes active form after post-translation modification (Pham, 2006). Human neutrophil elastase has specificity towards small hydrophobic amino acids. The potent catalytic activity is facilitated by a catalytic triad that is conserved among all serine proteinase, which consists of His, Asp and Ser amino acid residues forming a charge relay system. During proteolysis, the side chain of the peptide is located in the S1 specificity pocket while its backbone carbonyl is placed in the ‘oxy anion hole’ and forms hydrogen bonds with the amino group of Gly193 and Ser195 amino acid residues, thus stabilizing the charge transition state (Bode et al., 1989).

Several studies have been conducted recently to examine the binding interaction of inhibitors to the human neutrophil elastase structure (Siedle et al., 2002; Sivamani et al., 2012; Lucas et al., 2012; Crocetti et al., 2013; Radhakrishnan et al., 2013). In the present study, the aim is to understand the binding interactions between curcumin analogues and the active site of the human neutrophil elastase. The crystal structure of human neutrophil elastase (1H1B with resolution of 2.00 Å) was retrieved and then prepared according to the standard protocol implemented in Discovery Studio® 3.1. Subsequently the docking and interaction results were tabulated in Table III, in which 2,6-bis (3,4,5-trimethoxy benzylidene) cyclohexanone (compound 2), 2,6-bis (2,3,4-trimethoxy benzylidene) cyclohexanone (compound 4) and 1,5-bis (2,4,6-trimethoxy phenyl)-1,4-pentadiene-3-one (compound 13) exhibited the maximum interaction energy (-40 kcal/mol). In contrast, 1,5-diphenyl-(E, E)-1, 4 pentadiene-3-one (compound 12) and 2, 6-bis (4-hydroxy-3-methoxy benzylidene) cyclohexanone (compound 9) showed very least interaction energy of -23.7 and -24.7 kcal/mol respectively compared to all other ligands (-28.3 to -37.3 kcal/mol) as shown in the Table III.

Table III:The interaction energy analysis of 17 ligands docked with that of human neutrophil elastase using Discovery Studio ®;3.1

Ligand name cDocker interaction energy* (kcal/mol) Interaction with amino acid residue Bond distance (Ã…)
Compound 1 -29.9 No interactions -
Compound 2 -40.0 Phe192 3.2
Compound 3 -37.3 Arg147 2.8
Compound 4 -40.0 Phe192 3.0
Compound 5 -33.5 Gly219 3.0
Compound 6 -35.1 Val216 3.0
Compound 7 -37.7 No interactions -
Compound 8 -32.4 No interactions -
Compound 9 -24.7 No interactions -
Compound 10 -30.2 No interactions -
Compound 11 -33.8 Arg177, Phe192 3.2, 3.1
Compound 12 -23.7 Arg147 2.7
Compound 13 -40.1 Arg147 Not analyzed
Compound 14 -33.7 Arg147, Gly219 2.9, 3.0
Compound 15 -36.8 No interactions -
Compound 16 -35.1 Arg147, Gly218 2.8, 3.0
Compound 17 -28.3 Arg147, Val216 2.8, 1.9
*Calculated interaction energy for the highest ranked, docking pose

Whereby 1) 2,5-bis (2,3-dimethoxy benzylidene) cyclopentanone, 2) 2,6-bis (3,4,5-trimethoxy benzylidene) cyclohexanone, 3) 2,6-bis (2,4,6-trimethoxybenzylidene) cyclohexanone, 4) 2,6-bis (2,3,4-trimethoxy benzylidene) cyclohexanone, 5) 2,6-bis (2,6-dimethoxybenzylidene) cyclohexanone, 6) 2,6-bis (2,5-dimethoxybenzylidene) cyclohexanone, 7) 2,6-bis (2,4-dimethoxybenzylidene) cyclohexanone and 8) 2,6-bis (2,3-dimethoxybenzylidene) cyclohexanone. Hydrogen atoms have been omitted in the two dimensional diagram for better clarity. The pink line indicates the hydrogen bond interaction. In addition to these, bond distances are indicated in angstroms (Ã…) unit.

The ligands are 9) 2,6-bis (benzylidene) cyclohexanone, 10) 2,6-bis (4-hydroxybenzylidene) cyclohexanone, 11) 2,6-bis (4-hydroxy-3-methoxybenzylidene) cyclohexanone, 12) 1,5-diphenyl-(E, E)-1,4 pentadiene-3-one, 13) 1,5-bis (2,4,6-trimethoxyphenyl)-1,4-pentadiene-3-one, 14) 1,5-bis (2,6-dimethoxy phenyl)-1,4-pentadiene-3-one, 15) 1,5-bis (2,4-dimethoxy phenyl)-1,4-pentadiene-3-one and 16) 1,5-bis (2,3-dimethoxyphenyl)-1,4-pentadiene-3-one. Hydrogen atoms have been omitted in the two dimensional diagram for better clarity. The pink line indicates charge interaction. In addition to these, bond distances are indicated in angstroms (Ã…) unit. The 17 ligand is 1, 5-bis (2-hydroxyphenyl)-1,4-pentadiene-3-one. Hydrogen atoms have been omitted in the two dimensional diagram for better clarity. The pink line indicates the charge interaction. In addition to these, bond distances are indicated in angstroms (Ã…) unit.

Among the 17 ligands studied, five compounds namely compounds 7-10 (2,6-bis (2,4-dimethoxybenzylidene) cyclohexanone; 2,6-bis (2,3-dimethoxybenzylidene) cyclohexanone; 2,6-bis(benzylidene) cyclohexanone; 2,6-bis (4-hydroxybenzylidene) cyclohexanone) and 15 (1,5-bis (2,4-dimethoxyphenyl)-1,4-pentadiene-3-one) did not exhibit any interaction with any of amino acid residues active site (Table III). On other hand, we found that seven ligands (3, 11-14, 16, 17) interacted with Arg147 amino acid residue. Interestingly, none of the ligands was found to be interacted with Ser195 amino acid residue. No reports are available for elastase inhibitory activity of these 17 curcumin analogues till date. However parent compound (curcumin) has been reported to inhibit metalloelastase (MMP-12) using both, molecular docking and wet laboratory studies by Singh et al., (2012).

Conclusion

The results of this present study might provide new insight in understanding these 17 ligands (curcumin analogues) as potential candidates for human neutrophil elastase inhibitory agents. To our knowledge, we are the first to report the binding of these 12 curcumin analogues with that of human neutrophil elastase structure even though various enzymes were known to bind to the parent compound (curcumin).

References

Anonymous. Chemspider ( http://www.chemspider.com)

Anonymous. ACD, ChemSketch Version 12, Advanced Chemistry Development Inc., Toronto, ON, Canada, 2009

Anonymous. Research collaborator for structural bioinformatics Protein data bank (RCSB PDB)

Anonymous, Molinspiration Database .

Bode W, Meyer EJr, Powers JC. Human leukocyte and porcine pancreatic elastase: X-ray crystal structures, mechanism, substrate specificity, and mechanism-based inhibitors. Biochemistry 1989; 28: 1951-63.

Bustanji Y, Taha MO, Almasri IM, Al-Ghussein MA, Mohammad MK, Alkhatib HS. Inhibition of glycogen synthase kinase by curcumin: Investigation by simulated molecular docking and subsequent in vitro/in vivo evaluation. J Enzyme Inhib Med Chem. 2009; 24: 771-78.

Crocetti L, Schepetkin IA, Cilibrizzi A, Graziano A, Vergelli C, Giomi D, Khlebnikov AI, Quinn MT, Giovannoni MP. Optimization of N-benzoylindazole derivatives as inhibitors of human neutrophil elastase. J Med Chem. 2013; 56: 6259-72.

Furness MS, Robinson TP, Ehlers T, Hubbard RB, Arbiser JL, Goldsmith DJ, Bowen JP. Antiangiogenic agents: studies on fumagillin and curcumin analogs. Curr Pharm Des. 2005; 11: 357-73.

Girija CR, Karunakar P, Poojari CS, Begum NS, Syed AA. Molecular docking studies of curcumin derivatives with multiple protein targets for procarcinogen activating enzyme inhibition. J Proteomics Bioinform. 2010; 3: 200-03.

Gupta SC, Prasad S, Kim JH, Patchva S, Webb LJ, Priyadarsini IK, Aggarwal BB. Multi-targeting by curcumin as revealed by molecular interaction studies. Nat Prod Rep. 2011; 28: 1937-55.

Hosoya T, Nakata A, Yamasaki F, Abas F, Shaari K, Lajis NH, Morita H. Curcumin-like diarylpentanoid analogues as melanogenesis inhibitors. J Nat Med. 2012; 66: 166-76.

Istyastono EP. Docking studies of curcumin as a potential lead compound to develop novel dipeptydyl peptidase-4 inhibitors. Indo J Chem. 2009; 9: 132-36.

Jankun J, Aleem AM, Malgorzewicz S, Szkudlarek M, Zavodszky MI, Dewitt DL, Feig M, Selman SH, Skrzypczak-Jankun E. Synthetic curcuminoids modulate the arachidonic acid metabolism of human platelet 12-lipoxygenase and reduce sprout formation of human endothelial cells. Mol Cancer Ther. 2006; 5: 1371-82.

Jantan I, Bukhari SN, Lajis NH, Abas F, Wai LK, Jasamai M. Effects of diarylpentanoid analogues of curcumin on chemiluminescence and chemotactic activities of phagocytes. J Pharm Pharmacol. 2012; 64: 404-12.

Lam KW, Tham CL, Liew CY, Israf DA, Syahida A, Mohd Abdul Rahman B, Lajis NH. Synthesis and evaluation of DPPH and anti-inflammatory activities of 2, 6 bis benzylidenecyclohexanone and pyrazoline derivatives. Med Chem Res. 2012; 21: 333-44.

Lee KH, Ab Aziz FH, Syahida A, Abas F, Shaari K, Israf DA, Lajis NH. Synthesis and biological evaluation of curcumin-like diarylpentanoid analogues for anti-inflammatory, antioxidant and anti-tyrosinase activities. Eur J Med Chem. 2009; 44: 3195-3200.

Lipinski CA, Lombardo F, Dominy BW, Feeney PJ. Experimental and computational approaches to estimate solubility and permeability in drug discovery and development settings. Adv Drug Deliv Rev. 2001; 46: 3-26.

Liu M, Yuan M, Luo M, Bu X, Luo HB, Hu X. Binding of curcumin with glyoxalase I: Molecular docking, molecular dynamics simulations, and kinetics analysis. Biophys Chem. 2010; 147: 28-34.

Liu Z, Xie Z, Jones W, Pavlovicz RE, Liu S, Yu J, Li PK, Lin J, Fuchs JR, Marcucci G, Li C, Chan KK. Curcumin is a potent DNA hypomethylation agent. Bioorg Med Chem Lett. 2009; 19: 706-09.

Lucas SD, Costa E, Guedes RC, Moreira R. Structure based virtual screening for discovery of novel human neutrophil elastase inhibitors. Med Res Rev. 2013; 33: E73-101.

Majhi A, Rahman GM, Panchal S, Das J. Binding of curcumin and its long chain derivatives to the activator binding domain of novel protein kinase C. Bioorg Med Chem. 2010; 18: 1591-98.

Mukhopadhyay A, Basu N, Ghatak N, Gujral PK. Anti-inflammatory and irritant activities of curcumin analogues in rats. Agents Actions. 1982; 12: 508-15.

Nirmal N, Praba GO, Velmurugan D. Modeling studies on phospholipase A2-inhibitor complexes. Indian J Biochem Biophys. 2008; 45: 256-62.

Padhye S, Banerjee S, Chavan D, Pandye S, Swamy KV, Ali S, Li J, Dou QP, Sarkar FH. Fluorocurcumins as cyclooxygenase-2 inhibitor: Molecular docking, pharmacokinetics and tissue distribution in mice. Pharm Res. 2009; 26: 2438-45.

Pham CT. Neutrophil serine proteases: specific regulators of inflammation. Nat Rev Immunol. 2006; 6: 541-50.

Radhakrishnan N, Lam KW, Intan SI. Molecular docking analysis of natural compounds as Human neutrophil elastase (HNE) inhibitors. J Chem Pharm Res. 2013; 5: 337-41.

Sangeetha S, Ranjitha S, Murugan K, Ramesh kumar G. Breast cancer specific histone deacetylase inhibitors and lead discovery using molecular docking and descriptor study. Trends in Bioinform. 2013; 6: 25-44.

Sahoo BK, Gosh KS, Dasgupta S. An investigation of the molecular interactions of diacetylcurcumin with ribonuclease A. Protein Pept Lett. 2009; 16: 1485-95.

Selvam C, Jachak SM, Thilagavathi R, Chakraborti AK. Design, synthesis, biological evaluation and molecular docking of curcumin analogues as antioxidant, cyclooxygenase inhibitory and anti-inflammatory agents. Bioorg Med Chem Lett. 2005; 15: 1793-97.

Siedle B, Cisielski S, Murillo R, Loser B, Castro V, Klaas CA, Hucke O, Labahn A, Melzig MF, Merfort I. Sesquiterpene lactones as inhibitors of human neutrophil elastase. Bioorg Med Chem. 2002; 10: 2855-61.

Sivamani P, Singaravelu G, Thiagarajan V, Jayalakshmi T, Rameshkumar G. Comparative molecular docking analysis of essential oil constituents as elastase inhibitors. Bioinform. 2012; 8: 457-60.

Singh A, Mishra A, Gautam MK, Verma S, Goel RK. Regulation of wound strength by Curcuma longa: In silico and in vivo evidences. J Pharm Res. 2012; 5: 4734-38.

Shen L, Ji HF. Insights into the inhibition of xanthine oxidase by curcumin. Bioorg Med Chem Lett. 2009; 19: 5990-93.

Sui Z, Salto R, Li J, Craik C, Ortiz de Montellano PR. Inhibition of the HIV-1 and HIV-2 proteases by curcumin and curmumin boron complexes. Bioorg Med Chem. 1993; 1: 415-22.

Takeuchi T, Ishidoh T, Iijima H, Kuriyama I, Shimazaki N, Koiwai O, Kuramochi K, Kobayashi S, Sugawara F, Sakaguchi K, Yoshida H, Mizushina Y. Structural relationship of curcumin derivatives binding to the BRCT domain of human DNA polymerase lambda. Genes Cells. 2006; 11: 223-35.

Wang YJ, Pan MH, Cheng AL, Lin LI, Ho YS, Hsieh CY, Lin JK. Stability of curcumin in buffer solutions and characterization of its degradation products. J Pharm Biomed Anal. 1997; 15: 1867-76.

Wu G, Robertson DH, Brooks CL, Vieth M. Detailed analysis of grid-based molecular docking: A case study of Cdocker-A CHARMm-based MD docking algorithm. J Comput Chem. 2003; 24: 1549-62.

Published
2014-03-20

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