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International Journal of Biological Sciences logoLink to International Journal of Biological Sciences
. 2015 Jan 1;11(1):75–87. doi: 10.7150/ijbs.9872

Ligands Binding and Molecular Simulation: the Potential Investigation of a Biosensor Based on an Insect Odorant Binding Protein

Xin Yi 1, Yanbo Zhang 1, Peidan Wang 1, Jiangwei Qi 1, Meiying Hu 1, Guohua Zhong 1,
PMCID: PMC4278257  PMID: 25552932

Abstract

Based on mimicking biological olfaction, biosensors have been applied for the detection of various ligands in complex environment, which could represent one of the most promising research fields. In this study, the basic characters of one insect odorant binding protein (OBP) as a biosensor were explored. To explore the molecular recognition process, the tertiary structure of the protein was modeled and the protein-ligand interactions with 1,536,550 chemicals were investigated by the molecular docking. The availability of large amount of recombinant SlitOBP1 overcame the difficulty to obtain biological sensing material. After obtained the purified recombinant protein, the result of fluorescence binding assays proved the candidate protein has good affinities with the majority of the tested chemicals. With the aid of simulation docking, the key conserved amino acids within the binding site were identified and then mutated to alanine. After mutation, the protein-ligand binding characteristics were recorded, and the competitive binding assays were carried out to provide experimental verification. The detailed information on its structure and affinities investigated in this study could allow the design of specific mutants with desired characteristics, which provides a solid base for tailoring OBP for biosensor and provides a role model for screening the other elements in olfactory system for different applications.

Keywords: Odorant binding protein, Biosensors, Molecular simulation, Fluorescence binding, Site-directed mutagenesis.

Introduction

The demand for versatile technologies that can be used as sensors for the detection of volatile chemicals has rapidly increased in the last decade for various applications, including homeland security 1, environmental pollution control, health and wellness 2. These sensors possess features including precision, reversibility, selectivity, low cost, versatile sensing and compactness 3. Biological olfactory system are highly sensitive and have broad detection spectra 4, and thus represent excellent candidates for biomimetic sensors 5-8. Indeed, the sensor based on biological olfactory system only requires a protein with reversible binding capability 9. However, intensive efforts have been taken to determine the pharmacological profile and ligands specificities of individual olfactory receptors, until now, only a few studies focus on the odorant binding proteins (OBPs). OBPs are important components of chemosensory system 10, 11, 12, and have attracted increasing attention in recent years due to their great potential as biosensing elements 13-15. Indeed the increasing understanding of biochemical, physiological and behavioral aspects of ligands sensation could promote the development of biosensor 16, 17. The exceptional stability of OBPs to thermal denaturation and proteolytic degradation also made these proteins ideal for use in sensing devices 18, 19. However, there are only limited research papers describing the basic characteristics of OBPs as biosensors.

In fact, in insects, OBPs have two major roles: detection and delivery of chemical stimuli. They are associated to olfaction, chemoreception and highly concentrated in the lymph of chemosensilla in insects 20. Insect OBPs have a highly conserved folding pattern that is completely different from their counterparts in vertebrates 19. Particularly, the accurate detection of surrounding environment is crucial for insects to survive, thus, many insects have developed intricate, sensitive and specific tuned olfactory systems to detect the differentiate compounds at high resolution 21, 22. Moreover, due to the high complexity of the chemical language used by Spodoptera litura to communicate, investigation of the olfactory system in OBPs of this insect is of particular interest and insect OBPs are perhaps best known in the order Lepidoptera 23. Each OBP could recognize a range of semiochemicals with vastly different molecular shapes and sizes, functional groups, charge, hydrophobicity and even concentration 24. A better understanding of the selectivity of these OBPs towards different semiochemicals could facilitate the design of sensor for specific chemicals.

Previously, Spodoptera litura OBP1 was cloned and the expression was investigated by our team. The OBP1 showed distinct conservation in the evolution and this specific protein showed 78.1%, 87.6% and 79.9% identity to the OBP1 of the Helicoverpa assulta, Heliothis virescens and Helicoverpa armigera, respectively 25. In addition, among the 16 known OBPs in S. litura, OBP1 was found to be up-regulated in response to several chemicals (Unpublished data), which indicated it equipped diverse sensing abilities. Together with previously established characteristics, the OBP1 from S. litura is a promising candidate. In this study, a three dimensional (3D) model of OBP1 was constructed by homologous modeling, and the plausible binding modes between the model protein and 1,536,550 molecules were then inferred by docking simulation to determine its affinities to different molecules. Large amount of chemicals were screened in this study to demonstrate the binding activities of SlitOBP1 as a multisensor, and using the identified binding characters, the SlitOBP1 could be specifically modified to use as biosensors in monitoring certain ligands. This study demonstrated insect OBPs have broad ligand sensing capabilities and can be modified to be used as specific chemical biosensors to provide foundation for fabricating biosensor as well as other biotechnological applications and to provide a potent method for building multisensor device for ligands discriminations.

Materials and Methods

Insect

An artificial diet was applied for rearing S. litura (F.) 26 at 25 ± 1 ℃ in a 14:10 light : dark photoperiod and 60-70% relative humidity (RH). The new emerged adults were transferred to Chinese cabbage [Brassica campestris L.ssp. Chinensis (L.)] and raised at 25 ℃ and 60-70% RH. Three and four days after emergence, the adult moths were used for extraction of RNA.

Chemicals

The Available Chemicals Directory (ACD, Asinex Ltd Moscow, Russia), comprising 1,579,000 compounds, were used to investigate the binding affinities of SlitOBP1 in simulation docking. 21 ligands with the highest purity were purchased from Sigma (St Louis, USA) and stored according to the manufacturer's instructions to investigate the ligand-binding activities of SlitOBP1.

Sample preparation and RNA isolation

The total RNA from S.litura was extracted by the E.Z.N.A.TM total RNA isolation system kit (Omega, USA) according to the manufacturer's instructions. The M-MLV reverse transcriptase (TaKaRa, China) and oligo(dT)18 was used to transcribe the isolated RNA to first-strand cDNA at 42 ℃ for 60 min. After heating at 95 ℃ for 5 min, the reaction was terminated, and then stored at -20 ℃.

Alignment and homology modeling

A blast search of the full length of cloned SlitOBP1 (accession number EF159978) was conducted against the current Protein Data Bank (PDB; http://www.rcsb.org) to find structural template. The initial model was constructed by DS MODELER 27 in Discovery Studio 2.1 (Accelrys Software Inc.). To refine the initial homology model, the CHARMm force field was employed and three energy minimization procedures were processed. After performing 1000 steps of steepest descend (SD) and 2000 steps of conjugate gradient (CG) minimization, a molecular dynamic (MD) simulation was carried out to examine the quality of the model structure. First, minimization was carried out while all of the hydrogen atoms were relaxed and the other atoms were fixed. Then, the side-chains were energy-minimized while the main chain was restrained. Finally, minimization was performed while all the atoms were relaxed. The non-bond cutoff distance of 7 Å was used, and the long-range electrostatic interaction was calculated using the spherical cutoff method 28. The final 3D model was evaluated by PDF total energy, verify score 29 and Ramachardran plot 30.

Molecular docking

The compounds in the Available Chemicals Directory (ACD) database were screened by the Lipinski's rule of five in the ISIS BASE. The 'rule of five' stated that: poor absorption or permeation are more likely when: there are more than 5 H-bond donors (expressed as the sum of OHs and NHs); The MWT is over 500; The log P is over 5 (or MLogP is over 4.15); There are more than 10 H-bond acceptors (expressed as the sum of Ns and Os). The active site pockets of the receptor were found automatically by the Binding site in Discovery Studio 2.1. Binding site uses a CHARMm-based molecular dynamics scheme to seek for the optimal binding sites for docking 31. Based on the analysis of the geometry shape of the surface of the protein, the cavity which could bind to the substrate was identified, and the potential binding sites were predicted. Then, the optimal binding site was chosen based on the shape and location of the cavity, the location of the residue and the conserved acid amino. A site sphere radius was set to assign the entire binding pocket. Other parameters were set as default. The docking program Ligandfit and CDOCKER were used to perform the automated molecular simulation. The 'Number of Monte Carlo Trials' and 'Energy Grid' in the Ligandfit were used to first round screening. Electrostatic energy was excluded in the calculation of the ligand internal energy. Other parameters were set as default, the Extension from site was set as 3.0, the Nonbonded cutoff distance was set as 10.0, the Maximum internal energy was set as 10000, the RMS threshold for ligand/site match was set as 2.0, the rigid body SD iterations was set as 10, the Rigid Body BFGS iterations was set as 20, and four scoring function were applied. Subsequently, the CDOCKER was used for second screening. The Top hits was set as 10, the Random Conformations was set as 10. The top compounds were ranked by the corresponding values of -CDOCKER energy, -CDOCKER interaction energy, -PLP1 and Ligscore1, and all the values were preserved to find the most probable binding mode. During the analysis of the screened chemicals, the two scoring functions, PLP1 and LigScore1 appeared to be more precisely than other two functions. After evaluating the scores, conformation and detailed binding mode by these two functions, and combining with other two, 21 chemicals were selected for the subsequent analysis.

Expression of Recombinant and Purification for SlitOBP1

By using gene-specific primers with the restriction enzyme sites (F-5'-CGCGAATTCATGTTGCTGTTGTTGCGCGC-3', R-5'-CCGCTCGAGTCAGCGCGCCTCAGCCTCCA-3'), the sequence encoding SlitOBP1 was amplified with ExTaq DNA polymerase (TaKaRa, Japan). By T4 DNA ligase (Takara, China), the PCR product was connected to pET28a (Invitrogen, US) and then transformed to BL21 (DE3) competent cells (Takara, China). After the identification by PCR, the positive clone was inoculated in liquid LB overnight at 37 ℃. When its OD600 reached 0.4-0.6, 1 mM Isopropyl-D-thiogalactoside (IPTG) was added to incubate for another 12 h at 28 ℃. The total protein was purified from the supernatant by affinity chromatography using HisTrap columns (GE Healthcare). After dialysis in Tris-HCl (pH=7.4) overnight, the Bovine Enterokinase was used to remove the His-tag. The purified protein was collected and examined by 12% SDS-PAGE and Western blot. Bradford method was used to determine protein concentration 32.

Fluorescence-Based Ligand Binding Assays

The F-4500 FL Fluorescence Spectrophotometer (HITACHI) was used to record fluorescence spectra in a 1 cm light path quartz cuvette at 23 ℃. The slit width of 5 nm was used for excitation and emission. The final 21 ligands of different structure and rational binding modes appeared in four scoring functions, and available to purchase, were selected to be the candidates in the competitive binding assay. Chromatographic purity grade methanol was used to dissolve the fluorescent probe N-phenyl-1-naphthylamine (1-NPN) and all ligands used in competition experiments. By exciting the fluorescence of 2 μM 1-NPN in 50 mM Tris-HCl at 337 nm, the affinity of 1-NPN to SlitOBP1 was measured and recorded the emission spectra between 350 nm and 480 nm. In presence of SlitOBP1 at 2 μM and 1-NPN at 2 μM, the affinities of the selected 21 chemicals were measured by competitive binding assays by adding ligands from 0 to 20 μM. All values reported were obtained from three independent measurements.

To calculate the binding constants, the corresponding to the maximum fluorescence emission was plotted against the ligand concentrations. The amount of bound ligand was measured using the values of fluorescence intensity with a stoichiometry of 1:1 protein: ligand. The curves were linearized by Scatchard plots. The dissociation constants of the competitors were calculated using the corresponding IC50 values according to the equation: Ki = [IC50]/(1 + [1-NPN]/K1-NPN), where [1-NPN] is the free concentration of 1-NPN and K1-NPN is the dissociation constant of the complex protein/1-NPN 33.

Simulation of site-direct mutagenesis

All the residues which were within 4.0 Å distances around the molecule in the molecular docking were represented as sites of binding, and the binding free energy between the active site and ligand was calculated by the Calculate Interaction Energy program. When the absolute values of Van der Waals forces interaction energy and Electrostatic interaction energy with ligands were above 2.5 kcal/mol 34, or formed hydrogen bond or conjugation effect with the ligands, the amino acids were considered as key residues and were selected for mutagenesis study. These key residues were mutated to alanine, respectively. The structural models of the mutants were re-constructed by Discovery Studio as described previously. The binding activities were measured by the simulation docking as previously described. The downrange of the scores in docking were calculated by the formula:

The downrange score after mutation (%)= (The score before mutant- The score after mutant) / (The score before mutant) ×100

Molecular dynamics was applied to evaluate the stability of the binding. The model was used the TIP3P force filed 35. Na+ and Cl- were added to regulate the value of PH. The Energy minimization for optimization of residue geometry was applied until the gradient tolerance was satisfied.

Expression of mutants

The SlitOBP1 protein was mutated to yield the mutants SlitOBP1 Trp37 (tryptophan to alanine), SlitOBP1 Phe12 (phenylalanine to alanine), SlitOBP1 Ile52 (isoleucine to alanine), SlitOBP1 Thr9 (threonine to alanine), SlitOBP1 Glu98 (glutamic to alanine) by using the quickchange site-directed mutagenesis kit (Agilent) as the recommended procedure. The correct insertion of mutations was verified by DNA sequencing. Expressions of the proteins were carried fout as described previously. SDS-PAGE was used to monitor protein expression and purification. The binding activities were also investigated by the competitive binding assays as previously described.

Results

Molecular modeling

In order to obtain a template for modeling the structure of SlitOBP1, we searched the PDB database using the amino acid sequence of SlitOBP1 as query. There were 35 hits in total and the best one was the A chain of Bombyx mori GOBP2 which showed a consistency of 53%, similarity of 72%, E-value of 1.05167E-59, and bit score of 225.713. In addition, the full length of this template protein was 141 amino acids, the resolution was 1.40 Å, which meet the requirement of the homologous modeling. Therefore, the solution structure of GOBP in Bombyx mori (PDB code: 2WCJ) was selected as template (Fig. 1A) and the 3D model of SlitOBP1 was predicted by homology modeling using the alignment between SlitOBP1 and BmorGOBP. After refinement, the heavy atoms root mean square deviation (RMSD) between the model and the template was 1.5 Å up and down fluctuations, suggesting that the differences between the model and the template in the overall structure were negligible (Fig. 1B). The Verify Score of the final SlitOBP1 model determined by Profiles-3D was 66.29 (Fig. 1C), which is close to the expected verification score of 64.68. The Verify Score of the final SlitOBP1 was above 0, and the Ramachardran plot showed the structure of 99.3% amino acid residues were in allowed regions (Fig. 1D), implying that the overall quality of the predicted SlitOBP1 structure was reliable.

Figure 1.

Figure 1

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Three-dimensional (3D) model of SlitOBP1. (A)Sequence alignment of SiltOBP1 and BmorOBP. Strictly identical are highlighted with red background. (B) Root-mean square deviation obtained from the 1 ns molecular dynamics trajectory for SlitOBP1. (C) The Verify Score (Profile-3D) of the protein model of SlitOBP1. Residues with positive compatibility score are reasonably folded. (D) The Ramachandran plot of SlitOBP1. (E) The model of the SlitOBP1. Ribbon represented the selected conformer of the SlitOBP1. The three disulfide bridges are represented as yellow sticks. The secondary structures are labeled. A, B, C, D, E, F showed the six α-helices. (F) The hydrophobic and hydrophilic model of the SiltOBP1. The protein was folded and formed a spherical structure. The solid surface of the protein was covered by the hydrophilic residues, while the hydrophobic residues formed a hydrophobic cavity in inside of the protein (the white mesh surface).

Six α-helices were present in the predicted 3D structure of SlitOBP1, located between residues 1-24 (A), 33-38 (B), 46-79 (C), 83-101 (D), 107-126 (E) and 134-139 (F). Three pairs of disulfide bridges connected Cys19 and Cys54, Cys50 and Cys108, Cys97 and Cys117 (Fig. 1E). In this model, the hydrophilic residues were mostly present on the surface of the protein, while the hydrophobic residues formed a hydrophobic cavity inside of the protein (Fig. 1F).

Molecular docking

Based on the principle of five rules in the ISIS BASE, the unreasonable and repetitive compounds were removed and the 1,625,185 compounds were used for the subsequent screening. Five potential binding sites were identified by the Binding site program (Fig. 2). The one was chosen as the binding site for screening for its localization in the hydrophobic cavity, and other binding sites were deviated from the cavity. After evaluated by the five scoring functions, the 20% default ligands (the ligands could form the complex with the receptor protein) stand for 42% of the total number. This suggested that the method and parameters setting applied in this screening is rational and efficient. After docking by the Ligandfit, 1,536,550 compounds could be docking successfully with the SlitOBP1. By the established method, the top 20% compounds ranking by the Consensus Score were selected for the second screening. Subsequently, 23765 out of 23940 compounds were docking successfully by the CDOCKER. The compounds without the CAS numbers were ruled out, and the final 2040 compounds were selected. Based on the scoring functions, including -CDOCKER interaction energy, -CDOCKER energy, -PLP1 and LigScore1, the ranking top 100 compounds were shown in the Table 1. These compounds, which could bind to SlitOBP1, displayed a variety of different structures, including terpenoids, linear aldehydes, ketone, and aromatic compounds. The results showed the SlitOBP1 possesses broad spectra of ligand-binding activities to many compounds in various applications. The result of detailed binding mode of one selected chemical (45234-02-4) with the protein was showed in Fig. 3.

Figure 2.

Figure 2

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The five binding sites prediction of SlitOBP1. The five binding sites were identified based on the Binding Site Program in DS. The green one was represented as Binding site 1, the red one was for Binding site 2, the blue one was for Binding site 3, the purple one was for Binding site 4 and the white one was for Binding site 5.

Table 1.

Chemicals screened by four score functions in the docking analysis with SlitOBP1.

CAS No. -CDOCKER
energy		 -CDOCKER
Interaction energy		 -PLP1 LigScore1 CAS No. -CDOCKER
energy		 -CDOCKER
Interaction energy		 -PLP1 LigScore1
375-95-1 5.66456 38.6991 92.32 2.72 678-39-7 12.0627 40.6552 90.46 1.29
754-96-1 14.7061 41.5673 93.99 2.88 865-79-2 8.13773 39.7778 91.82 2.83
2342-09-8 10.4978 35.2783 87.04 2.52 2545-89-3 65.1184 43.2304 76.22 4.07
5545-52-8 53.468 43.9979 80.33 1.31 5891-53-2 70.7165 42.5603 72.4 2.45
6099-08-7 58.9235 40.5716 72.36 2.18 10567-86-9 23.4187 32.8927 70.36 3.45
15080-84-9 49.5768 41.7062 70.14 2.14 17355-09-8 53.8239 43.7485 70.44 2.85
20556-13-2 58.3522 41.7623 69.74 3.28 23680-31-1 48.4742 41.8875 69.35 1.45
24305-27-9 42.031 48.771 79.74 2.5 30670-30-5 14.3854 40.0041 89.06 2.53
42406-77-9 42.2214 37.7094 76.02 1.5 45234-02-4 70.5762 38.7205 72.96 2.97
157843-41-9 9.39257 42.3274 82.27 3.41 203303-01-9 15.3247 37.8305 85.54 2.59
430447-82-8 49.3832 39.6555 76.22 1.91 145-13-1 -17.066 48.341 75.36 3.31
298-25-9 -6.811 51.013 67.29 3.45 974-23-2 -13.646 48.085 68.93 3.29
97970-92-8 44.108 46.643 75.11 3.6 18797-79-0 -1.93 48.604 83.49 2.3
50-24-8 -29.79 47.565 77.92 2.96 53-03-2 -17.895 48.297 77.04 3.26
3546-11-0 25.128 43.484 77.76 3.83 898792-70-6 21.233 42.774 82.88 1.89
5220-98-4 25.443 49.026 75.47 2.46 474-45-3 -7.417 47.362 75.51 3.15
3788-44-1 57.871 46.901 75.49 3.79 516-54-1 -5.032 49.098 76.06 3.11
37481-42-8 31.588 45.445 82.44 1.98 75522-73-5 11.787 46.752 78.41 2.06
655256-70-5 24.284 45.997 76.16 3.6 80-75-1 -13.706 46.877 77.04 3.18
1923-27-9 1.291 48.813 78.64 2.77 2681-55-2 -9.172 46.323 76.15 3.13
596-69-0 -70.85 44.134 75 2.73 975-53-1 -26.872 49.709 79.06 3.36
103335-41-7 -5.825 48.346 78.29 2.84 4777-62-2 -20.033 50.85 80.3 3.29
1239-31-2 5.09 47.713 80.84 2.71 23930-19-0 -1.695 50.498 75.75 3.31
1482-78-6 -4.581 48.931 79.12 2.84 1600-76-6 -9.031 46.425 81.35 2.72
38398-44-6 -7.135 51.478 80.82 3.11 10388-62-2 -71.942 44.895 75.7 2.63
3684-84-2 -3.216 45.385 82.21 3.25 22733-60-4 -10.97 46.621 76.02 3.11
35100-44-8 -18.866 48.178 79.19 2.95 19427-36-2 -7.934 47.701 80.58 3.24
103303-35-1 -23.264 49.377 79.87 3.2 82419-52-1 31.319 42.116 76.37 3.13
264218-23-7 5.133 40.165 78.34 2.83 566-42-7 -17.567 48.278 80.88 3.82
641-78-1 -13.068 47.328 76.24 2.79 1000776-27-1 46.836 52.262 80.15 2.65
143691-84-3 14.767 49.475 79.53 4.08 75263-33-1 39.288 49.301 77.73 2.43
56258-32-3 21.974 44.602 84.84 3.43 1241-87-8 18.77 45.665 80.06 3.82
124858-35-1 30.042 48.353 89.21 2.7 71795-44-3 35.502 47.371 80.02 2.33
317807-10-6 19.695 42.542 78.37 2.43 75530-60-8 13.451 51.474 83.8 3
806-29-1 -18.711 45.22 81.24 3.01 433690-46-1 35.43 49.76 81.93 3.11
533922-44-0 34.501 46.763 82.18 3.64 571-67-5 -3.522 43.374 82.71 2.58
532940-59-3 26.991 47.063 85.01 2.93 435282-71-6 31.114 45.625 80.64 3.52
34061-33-1 10.708 38.643 70.23 2.14 913835-39-9 32.066 39.347 72.31 3.31
957060-97-8 31.913 38.511 70.17 3.27 72666-14-9 30.778 39.451 69.72 3.93
520-17-2 23.067 37.483 68.93 2.71 72617-60-8 -15.525 38.467 68.02 2.83
1881-37-4 0.168 38.988 71.87 2.81 331759-58-1 36.648 38.6 75.12 3.03
67034-83-7 -15.668 43.242 71.73 3.1 946049-56-5 31.732 38.083 76.39 2.96
3569-77-5 28.344 38.857 68.79 3.35 4747-99-3 38.789 42.468 67.33 3.47
21178-57-4 -0.063 39.578 74.35 3.57 145915-60-2 2.558 37.71 83.67 3.36
5189-96-8 -5.336 40.639 69.93 3.21 89875-86-5 -20.632 36.333 69.09 2.66
38734-38-2 12.374 43.012 76.64 2.28 98067-16-4 27.058 44.607 66.55 2.67
53-43-0 -15.654 43.182 71.73 3.1 175448-32-5 -9.385 36.938 69.51 3.13
532940-59-3 27.684 45.391 85.01 2.93 913835-39-9 32.066 39.347 72.31 3.31
21178-57-4 -0.66 38.778 67.46 3.33 530133-81-4 20.029 39.874 91.04 2.98
161987-77-5 10.727 36.739 78.46 2.32 36271-80-4 -4.822 41.479 77.9 3.07
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Figure 3.

Figure 3

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Detailed binding mode of one selected chemical (45234-02-4) with the SlitOBP1. (A) The binding mode between the ligand and SlitOBP1; (B) The position of 45234-02-4 in the binding pocket of SlitOBP1; (C) The 3D binding mode between 45234-02-4 and the key residues in the SlitOBP1; (D) The 2D binding mode between 45234-02-4 and the key residues in the SlitOBP1. The arrows point to the hydrogen bonds, and conjugated effects were showed by yellow lines.

Fluorescence Binding Assays

The SlitOBP1 was induced and expressed successfully (21.9 μg/μl). The purified protein was resolved as a single band with molecular weight of 25 kDa as determined by SDS-PAGE and Western blot (Fig. 4A (a)&(b)). By titrating SlitOBP1 with increasing concentration of 1-NPN, a saturation and linear Scatchard plot (Fig. 4B) were observed. The SlitOBP1 could bind to the probe with a dissociation constant of 3.237 ± 0.20 μM (Fig. 4B). By using 1-NPN as the fluorescent reporter, the affinity of SlitOBP1 to a series of compounds was measured (Fig. 4C&D). The IC50 values (the concentration of the ligand that yielded 50% of the initial fluorescence value) and calculated binding constants were reported in Table 2. The SlitOBP1 showed high affinities with most of the tested compounds, including 375-95-1, 50-24-8, 53-03-2 and 865-79-2, while some chemicals showed no binding potential to the receptor protein, such as 2342-09-8 and 30670-30-5.

Figure 4.

Figure 4

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Competitive binding study of SlitOBP1 to a series of selected compounds. (A) Expression and purification of SlitOBP1. (a) The blot showed one specific band at around 25 KDa in agreement with the predicted value. SlitOBP1 was induced and expressed in pET-28a vector. Purification was accomplished by HisTrap affinity columns; Lane 1-2 showed the protein after renaturation; Lane 3-6 showed purified inclusion body of the protein. M: molecular weight marker of 20.1, 29.0, 44.3, 66.4 and 97.3 KDa. (b) Western blot analysis of the SlitOBP. Immunoblotted with serum (diluted 1: 2000) and visualized by ECL. M: molecular weight marker of 20.1, 29.0, 44.3, 66.4 and 97.3 KDa. 1: control. 2: Purified protein. (B) The binding curve of 1-NPN and relative Scatchard plot analysis (inset). To measure the affinity of 1-NPN to SlitOBP1, the fluorescence of 2 μM 1-NPN in 50 mM Tris-HCl was excited at 337 nm and emission spectra were recorded between 350 nm and 480 nm. Then, 2 μM of protein was added and titrated with aliquots of 1 mM 1-NPN to final concentrations of 2 to 20 μM. The experiment was replicated for at least three times, and the data were analyzed using Prism software and indicated the presence of a single binding site. The dissociation constant was 3.237 (±0.20 SEM). (C)&(D) The solution was excited at 337 nm. Competitive binding of the selected ligands with SlitOBP1. Final solutions of 2 μM SlitOBP1 protein and 2 μM 1-NPN were titrated with 1 mM solution of each ligand in methanol to final concentrations of 0-20 μM. The figure reported averages of three replicates.

Table 2.

Key residues of the interaction between SlitGOBP1 and candidate compounds.

Interaction Key residues
VDW interacton energy Thr9, Phe12, Ile52, Met68, Ile94, Phe118, Leu61, Leu62, Phe12, Phe36, Phe33, IAla115, Trp37, Val114
Electrostatic interacton energy Arg110, Ser56, Thr73, Thr9, Arg110, Met5, Glu98
hydrogen bond Thr9, Trp37, Ser56
conjugated effect Phe12, Ala115, Phe118, Phe33
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The marked bold represented the selected key residues for the following experiment.

Key residues and simulation of site-directed mutagenesis

The structural studies provided insight into the ligand-binding mechanism of SlitOBP1. During the binding of SlitOBP1 with various ligands, the hydrogen bond, van der Waals interactions, electrostatic force and conjugative effect were crucial for binding activities. After docking with the screened compounds, nine amino acids of SlitOBP1 were identified as key residues for the ligand binding specificity (Table 3). The nine key amino acids were mutated to alanine, respectively, and the binding activities of each mutant to the 21 compounds were evaluated. The result showed the Phe12, Ile52, Ile94 and Phe118 could affect the formation of Van der Waals interactions, while Thr9, Trp37, Ser56, Glu98 and Arg110 could affect the formation of electrostatic force and hydrogen bond, eventually could affect the conformation of the cavity to the final binding affinities of the protein. The results showed majority of the scores of binding activities of mutations were reduced significantly, which suggested these key residues could be responsible in regulating the binding activities of the SlitOBP1 to the compounds. The Table 4 showed the docking scores of partial compounds by comparison of the wild type model and mutant model. The analysis of 1 ns molecular dynamics revealed that these complexes of SlitOBP1 and compounds were stable, which suggested the obtained result was reliable (Fig.5A&B).

Table 3.

Fluorescence competitive binding affinities of selected components to recombinant SlitOBP1.

Ligands CAS SlitOBP1
IC50 Ki
Alcohols
1H,1H,2H,2H-perfluoro-1-decanol 678-39-7 5.97 3.69
1H,1H,10H,10H-perfluoro-1,10-decanediol 754-96-1 6.68 4.13
1H,1H,9H,9H-perfluoro-1,9-nonanediol 203303-01-9 9.45 5.84
Acids
Perfluorononanoic acid 375-95-1 6.08 3.76
9-Chlorohexadecafluorononanoic acid 865-79-2 6.00 3.73
H-Lys-Glu-OH 45234-02-4 5.86 3.62
H-Glu-Lys-OH 5891-53-2 - -
H-Gly-Tyr-Gly-OH 6099-08-7 6.11 3.78
H-Phe-Met-OH 15080-84-9 - -
H-Lys-Ile-OH 20556-13-2 7.52 4.65
H-Tyr-Glu-OH 2545-89-3 - -
N-Cbz-L-Aspartic acid 4-tert-butyl ester 5545-52-8 6.70 4.14
Ketones
1,2-Dehydrocortisone 53-03-2 5.00 3.09
Delta-5-pregnenolone 145-13-1 14.77 9.13
11β,17α,21-trihydroxypregna-1,4-diene-3,20-dione 50-24-8 5.02 3.10
Heterocyclic compounds
16,17-epoxypregnenolone 974-23-2 8.28 5.12
Corynoline 18797-79-0 - -
Pyr-His-Pro-NH2 24305-27-9 7.18 4.44
L-Tyrosine benzyl ester 42406-77-9 7.23 4.47
Others
Perfluorosebaconitrile 2342-09-8 - -
1H,1H,2H,2H-perfluorodecylamine 30670-30-5 - -
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Table 4.

comparison between the docking score using original model and mutant model.

Mutant
amino acid		 CAS No. Decreasing auplitude of
score after mutant (%)		 Mutant
amino acid		 CAS No. Decreasing auplitude of
score after mutant (%)		 Mutant
amino acid		 CAS No. Decreasing auplitude of
score after mutant (%)
Phe12 42406-77-9 7.37 974-23-2 15.38 53-03-2 19.11
974-23-2 64.76 754-96-1 39.70 50-24-8 12.82
754-96-1 40.04 53-03-2 -0.73 2545-89-3 3.67
53-03-2 27.54 50-24-8 6.08 6099-08-7 -6.84
50-24-8 13.70 2545-89-3 3.06 865-79-2 45.33
2545-89-3 4.15 6099-08-7 -9.06 Trp37 754-96-1 23.66
20556-13-2 4.15 20556-13-2 0.02 53-03-2 37.71
45234-02-4 5.84 45234-02-4 -0.61 50-24-8 17.79
24305-27-9 14.87 24305-27-9 13.82 2545-89-3 5.59
678-39-7 48.92 678-39-7 29.77 6099-08-7 -0.63
375-95-1 112.54 375-95-1 16.61 678-39-7 -0.41
5545-52-8 13.67 5545-52-8 1.55 5545-52-8 6.64
865-79-2 43.73 865-79-2 20.39 865-79-2 38.21
Ile52 974-23-2 17.22 Phe118 42406-77-9 -0.69 Ser56 42406-77-9 -2.34
754-96-1 27.26 974-23-2 20.37 2545-89-3 -0.11
53-03-2 26.82 754-96-1 26.04 6099-08-7 -2.53
50-24-8 7.82 53-03-2 45.92 20556-13-2 6.19
2545-89-3 -0.58 50-24-8 15.24 45234-02-4 2.20
6099-08-7 0.68 6099-08-7 -1.05 24305-27-9 5.38
45234-02-4 3.07 20556-13-2 6.51 Glu98 974-23-2 36.12
24305-27-9 2.02 24305-27-9 1.86 2545-89-3 2.63
678-39-7 17.08 678-39-7 6.38 6099-08-7 -9.45
375-95-1 44.88 375-95-1 30.92 375-95-1 -82.33
5545-52-8 5.24 5545-52-8 2.77 Arg110 754-96-1 -10.06
865-79-2 79.73 865-79-2 35.38 53-03-2 35.25
Ile94 42406-77-9 -11.82 Thr9 754-96-1 1.63 50-24-8 6.95
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Figure 5.

Figure 5

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Evaluation of the complexes by molecular dynamics. (A) Potential energy with respect to simulation time for 1ns molecular dynamic of the complex of SlitGOBP1 with partial selected candidates; (B) Root-mean square deviation obtained from the 1ns molecular dynamics trajectory for the complex of SlitGOBP1 with partial selected candidates.

Site-directed mutagenesis of SlitOBP1 and binding specificities of mutants

By the site-directed mutagenesis, the residues (Phe12, Ile52, Thr9, Trp37, Glu98) were replaced with the alanine. When analyzed by SDS-PAGE, the expressed mutant protein showed band with similar molecular weight with wild-type protein (Supplementary Fig. 1). Probed by 1-NPN, the saturation and linear Scatchard plot was observed, and saturation binding curves analysis revealed that the dissociation constants for 1-NPN to mutants Phe12, Ile52, Thr9, Glu98 and Trp37 were 6.78 ± 0.25 μM, 5.43 ± 0.31 μM, 4.21 ± 0.19 μM, 3.67 ± 0.25 μM and 4.54± 0.28 μM, respectively. Affinities of the mutant proteins to these 21 chemicals were measured by competitive binding assays. The result showed that, after mutanting the key amino acids, many ligands could not compete with 50% of the 1-NPN even when their concentration reached 20 μM. Interestingly, in mutant Phe12 and Ile52, all the ligands could not bind to the OBP1. As predicted by computer simulation, most of the ligands showed poor binding affinities to the mutants, while some chemicals also showed better binding activities, such as the 6099-08-7 with mutant Thr9, mutant Glu98 and 678-39-7 with mutant Trp37 (Fig. 6).

Figure 6.

Figure 6

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Binding affinities of the ligands to the SlitOBP1 mutants. (A) Binding affinities of mutant Thr9. (B) Binding affinities of mutant Glu98. (C) Binding affinities of mutant Trp37. Final solutions of 2 μM SlitOBP1 protein and 2 μM 1-NPN were titrated with 1 mM solution of each ligand in methanol to final concentrations of 0-20 μM. The figure reported averages of three replicates. (D) The Ki values of the binding affinities. Values are means of three independent experiments. Ligands concentration > 20μM for half-maximal relative fluorescence intensity was represented as “-“.

Discussion

Far and wide, the inspired biosensor offers potential applications for environmental monitoring, agriculture, anti-bioterrorism, disease diagnostics, and food safety 36. The intrinsic properties of OBPs make them excellent candidates for biosensors 17. Ramoni et al 37 investigated the possibility of utilizing a mutant of OBP as nano-biosensors for the indication of hazardous compounds. Pietrantonio et al 13 presented biosensors for vapor phase detection based on surface acoustic wave resonators coated with OBPs 17, and a biosensor based on OBP was designed with its ligands detected by electrochemical impedance sensing 12. The application of these proteins in ligands detection is very appealing, and the focus of this study is to explore an insect OBP on the basis of its broad binding activities. Moreover, the design of mutants with desired characteristics enables more specific and efficient detections.

The way in which organisms detect volatile compounds within the environment has been of interest to scientists for decades 38. For their crucial role of OBPs in olfaction, structural properties are the main target of future investigations. Homology modeling is an efficient method for 3D construction, which can provide a structural basis for evaluating and designing ligand sensors 36. As demonstrated in this study, the SlitOBP1 is composed of six α-helical domains arranging in a very compact structure, which encloses a hydrophobic cavity. Compared to vertebrate OBPs, the presence of three interlocked disulphide bridges in insect OBPs confers limited flexibility to the structure, which prevents insect OBP from thermal denaturation and proteolysis 19. This long C terminus structure of SlitOBP1 may be enough to form the seventh α-helix as previously mentioned 20,38, which could form a “molecular switch” at low pH to provide a fast, efficient way of releasing the ligand and restoring the functionality of the biosensor element 19.

The OBPs could be presented as ideal sensor material due to their versatile sensing and detecting abilities. The identification of potential binding modes and poses can be obtained by the molecular docking accurately 40. To investigate the ligand binding process, the molecular recognition was simulated by molecular docking 41. Based on the conformation of protein and ligands, the detailed binding modes were doped out. The method described previously in the Cheng 42 was applied for the parameter settings in the Ligandfit, and the results showed the binding efficiency was depended on the number of Monte Carlo Trials and different energy grid. For screening the chemicals in the first round by the Ligandfit, the scoring function, the PLP1 showed better evaluation ability than others. By taking the PLP1 scoring function as the prior evaluation, the number of chemicals is reduced from 1,536,550 to 23,940 by the first round screening, only accounting for 1/64 of the original number. Thus, the molecular docking could be applied for eliminating improper ligands 36. Instead of reducing the number of the chemical, the aim of the second round screening is to identify the chemicals which have better and more rational binding mode with the protein. Although the simulation method applied here could not identify the best binding candidate, it still represents a reliable, convenient and rapid way to screen the candidate chemicals. 23765 out of 1,625,185 compounds were found to have good affinities with SlitOBP1, including aliphatic alcohols, ketones, aldehydes, esters and acid, as well as heterocyclic and aromatic compound derivatives. It is significant to investigate the dynamic state by the molecular dynamics simulation considering the ligand and the receptor protein as a complex as all the proteins are dynamic in solution and have structural flexibility. In this study, the complexes of the protein and the compounds were investigated by the 1ns molecular dynamics simulation. The potential energy and root-mean square deviation showed the compounds could form stable complex with the protein. The fact that SlitOBP1 can bind to large number of natural and synthetic structurally unrelated organic compounds suggests that the protein can be applied to detect diverse chemicals in many fronts, including threatening compounds for human health in the air and in water, volatile organic compounds (VOCs) or chemicals have potential impact on climate and long-term health effect.

To validate the reliability of simulation docking, the top 21 ligands of different structure and rational binding modes appeared in four scoring functions were selected to be the candidate ligands in the competitive binding assay. In the previous studies, the compounds used as binding candidate ligands with the tested OBPs were sex pheromones and plant volatiles, and the aim is at illuminating the role of OBPs in the perception of such chemicals in insect olfactory system 43,44. To our knowledge, many compounds investigated here were the first time used to evaluate the use of OBP as a biosensor. These compounds were selected based on their relevance to environment, biology and biosensor, etc. For example, the chemical 678-39-7 was reported to have the ability to combine bioaccumulative potential, toxic effects and extreme persistence 45, the chemical 375-95-1 was reported to be water surface-active fluorocarbon derivatives 46, the 45234-02-4 was an excitatory transmitter of major significance in the mammalian central nervous system 47, the chemical 53-03-2 was applied for prostate cancer 48.

Consistent with the result of the simulation docking, the SlitOBP1 could reversibly bind to most of identified chemicals in the competitive fluorescence binding assays. A number of compounds, namely, 53-03-2, 45234-02-4, 375-95-1, 865-79-2 and 50-24-8, could effectively displace 1-NPN, suggesting that these compounds have high affinities with SlitOBP1. In line with results in the simulation docking, most of the selected compounds could bind to the protein. The only three exceptions are 2343-09-8, 30670-3-5 and 15080-84-9, which may be due to the strengthening the fluorescence emission by Trp109 on the surface of the protein. Generally speaking, the aliphatic compounds and ketone showed better consistency, while the heterocyclic compounds and chemicals with halogen showed opposite results against previous demonstrated in the simulation docking. This may be due to the complex structure and the formation of other covalent coordination bond. The consistency of the most tested chemical compounds between the simulation docking and experimental data suggested the result of the molecular docking was reliable and the method could be applied in the future screening to save manpower and time. Moreover, the results demonstrated the OBP possesses board affinities to bind and detect various chemicals. The broad binding activities of OBP is presumably due to the peculiar characteristics of its ligand binding site, i.e., a hydrophobic cavity lined with hydrophobic amino acid residues. The fact that the 20 lipophilic amino acids exist inside the protein may explain its binding activities to some lipid solubility compounds.

Besides its broad binding spectrum, in particular, this class of proteins has another advantage that they can be easily modified by genetic engineering techniques to improve their binding specificities 49. The results of the molecular simulation suggested that hydrogen bonds and electrostatic interaction played important roles in increasing the structural stability of the protein-ligand complexes. Oxygen atoms of many ligands, including 45234-02-4, 678-39-7, 754-96-1, could form hydrogen bond with the Thr9, Ser56, and Trp37, which lay in the middle of the binding pocket of the protein. The conjugative effect also plays an important role, for example, in the binding with chemical 45234-02-4, 24305-27-9, 2545-89-3 and 20556-13-2. The surrounding residues, which were close to the interactions, were identified as key residues in the binding activities. After nine key amino acids were mutated to alanine, respectively, the binding activities of these mutants to the screened compounds were evaluated. The evaluations were important in assessing the matching degree between the ligand and SlitOBP1 in orientation and conformation, as well as in comparing the binding modes of different ligands to the protein 50. In this study, four scoring functions were applied to improve the result by reaching the assessment consistency. After mutated these key residues, the mean value of the function scores showed that most of the docking results were lower than the wild-type complexes (Table 3). Moreover, the mutant of both Phe12 and Phe118 resulted in lower docking scores to all the tested ligands. The results suggested these amino acids could regulate the interactions between the protein and the ligands. Thr9, Trp37, Ser56, Glu98 and Arg110 seemed to be indispensable to the formation of hydrogen bonds and electrostatic interaction. The phenomenon was also observed in previous reports; for instance, Ser56 of BmorPBP 51, which was also identified as key amino acid at the binding entrance, and can influence the specific pheromone binding. In addition, the Ser52 and Thr57 of LUSH were found to be able to determine the binding specificity of LUSH by forming hydrogen bonds with hydroxyl of alcohol 52. Moreover, a study proved that the Phe89 could control the access of a ligand inside the binding cavity of the protein 53. Taking together, the results showed that these amino acids at the entrance or middle of the binding cavity are critical for determining the binding specificity of the protein. However, some of the docking results after these mutants showed better scores compared with previous ones. This may be due to the rearrangement and re-conformation of the binding cavity to form new binding site to the ligands with formation of non-covalent forces. And to provide practical verification, the competitive binding assays were carried out. None of the chemicals could compete 50% 1-NPN, even when the ligand concentration reached 20 μM or higher after mutating the Phe12, Ile52. A possible and direct explanation is that the ligands could not be recognized by the mutant and could not enter in the binding cavity due to the loss of hydrogen bonding. The mutation of Thr9, Glu98 and Trp37 showed lower affinities towards most of the ligands compared with the wild type, which was consistent with the result of computer simulation. Perhaps because of the capacity of the mutant to establish new van der Waals interactions or other force, mutant Thr9, Glu98 and Trp37 showed a slight increase in binding to some ligands. Some results showed inconsistency with the computer simulation, such as the binding activity of the mutant Thr9 to 203303-01-9 and the mutant Glu98 to 50-24-8, this may be due to the complex binding mechanism or different binding mode of long chain chemicals, which needs further investigation. Overall, the selectivity and specificity of SlitOBP can be further increased by targeted mutagenesis.

OBPs possess many desirable features such as broad binding affinities to different structure compounds and stable at different pH values, making them suitable for biosensors 54. The fact that the OBP is able to interact with a broad range of compounds could be effectively used in an olfactory element-based biosensor 55,56. In this study, we investigated the binding capabilities of SlitOBP1 using a combination of computer simulation methods, mutagenesis, and competitive binding assay. As a result, SlitOBP1 showed specificities towards diverse organic compounds, which is promising for building a multisensor device for various ligands discrimination. Future work will focus on the strategy to adopt for transducing chemical information encoded in the molecule into electrical signals that could be easily measured, amplified and processed. Moreover, the exploration method of the SlitOBP1 in this study could provide a platform and role model to explore other elements in the olfactory systems as biosensor or other applications.

Supplementary Material

Supplementary Figure 1
Click here for additional data file. (185.1KB, pdf)

Acknowledgments

The work supported by the National Natural Science Foundation of China for funding this work under grant no. 31071713.

References

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