Latest revision as of 16:23, 12 December 2020

Model

Overview

Our goal is to design the peptides of tandem-repeated sequence (PTRSs) to imitate C-type lectin domain, family 5, member A (CLEC5A) docking with dengue virus. In order to ensure the PTRs and the envelope protein (E protein) of dengue virus have an interaction, all the structure of PTRSs and proteins and their interactions were modeled using Rosetta. First, we utilized RosettaCM (Comparative modeling with Rosetta) to generate the structure of E protein from a local strain (PL046) based on the crystal structure (PDB: 1OAN). Second, we used the ab initio method to predict the PTRSs structures purely based on their sequences. Then, we utilized the clustering method to cluster the results and find the most probable structure of the PTRS. Finally, we verified the interactions between these predicted PTRSs and the E protein based on the global protein-protein docking. Figure 1 shows the flow of our simulation.

Figure 1. The flow of our simulation procedures

Protocols

RosettaCM (Comparative modeling with Rosetta)

Purpose: To generate the structure of E protein (PL046)

Create a threaded model

Input:

Target sequence in a fasta file
Sequence alignment file in the Grishin format
Template PDB file

Output: A PDB file of threaded template.

Commands and Flags

Run the hybridization mover

Input:

Target sequence in a fasta file
RosettaScripts xml file:

The weight files
Target sequence fragments files: 3-residue fragments and 9-residue fragments
The PDB file of threaded template from step 1

Output: PDB files after hybridization.

Commands and Flags

Final relax

Input:

Disulfide bond
PDB files generated from step 2

Output: About 10,000 results. (The lowest Rosetta score of the structure is shown in Figure 2)

Commands and Flags

Figure 2. The homology structure of PL046 E protein in cyan based on the deposited structure (PDB: 1OAN) in magenta

Ab initio

Purpose: To generate the structure of the PTRSs

Input:

Protein sequence in fasta format
Fragment library: 3-residue fragments and 9-residue fragments
Psipred-ss2 (optional)

The last two inputs were generated from Robetta Fragment

Output: About 20,000 results. (Two of the representative structures are shown in Figure 3)

Commands and Flags

We did not find the "funnel shape" from the plot of "Rosetta energy score vs RMSD" for the best 1,000 structures, which suggests there might be no single stable conformation.

Results

Figure 3. Two of the representative structures of PTRS

Clustering

Purpose: To cluster the results and find the most probable structure

Rescore the thousands of results

Input: The ab initio results.

Output: The clustering scores.

Commands

Energy cut-off

Input: The clustering scores.

Output: The results passing the energy cut-off.

Commands

Extract the results

Input: The results passing the energy cut-off.

Output: The structures sorted by clustering. (We chose the lowest score to simulate protein and protein docking.)

Commands and Flags

Protein-Protein Docking (global docking)

Purpose: To find the interaction between PTRSs and E Protein

Input: The structures of ligand (PTRS or CLEC5A) and receptor (E protein) in the same input file.

Output: About 10,000 results. (The most 100 frequent docking sites are shown in Figure 4)

Commands and Flags

Figure 4. The best 100 results (based on the Rosetta score) of PTRS-1 or PTRS-2 docking to PL046 E protein (in red). The space above the plane (in grey) indicates the external surface of the virions, where the interactions occur.

Overview

The weakness of our design is that the PTRSs from the gold nanoparticles and the ones from the glass fiber compete for the same binding sites on the E protein. Moreover, if the E proteins on the virus particles are fully covered by the gold nanoparticles, there are no sites available to interact the PTRSs from the glass fiber.

Repulsion between gold nanoparticles

To assess this potential problem, we used DLVO theory to calculate the repulsion between gold nanoparticles to estimate the number of gold nanoparticles that would bind to a virus particle. The structure of dengue virus is icosahedral, and there are three E proteins on each surface. The distances between the potential binding sites can be obtained from the structure in protein data bank (1K4R). DLVO theory can be described as Equation 1.

W_total(D) = W_a(D) + W_r(D) = -AR/12D + 2πεε₀RΨ_δ²exp(-κD) Equation 1.

W_total(D): total energy
W_a(D): van der Waals interaction energy
W_r(D): electrostatic interaction energy
A: Hamaker constant = 2.5×10^-19 J
R: radius = 1.3x10^-8 m (based on the size of gold nanoparticles)
C: center to center distance
D: C-R
ε: permittivity of vacuum = 8.854x10^-12 F/m
ε₀: dielectric of solution = 80.4 (at 20°C)
Ψ_δ²: Stern layer potential (zeta potential) = 1.794 mV
κ^-1: diffuse layer thickness = 7.95x10^-10 m

We took several representative positions on adjoining faces of the icosahedron to calculate the interactions between the gold nanoparticles based on DLVO theory. We found the total energies are all positive (Table 1), and these total energies are also larger than the typical biological interactions (~0.5 kcal/mol or 3.49 x10²¹ J). The results suggest that there will always be free faces on the virus particles to interact with the PTRS-2 conjugated on the test line.

Table 1. The representative energies of the interaction between the gold nanoparticles.


C (nm)	54.58	42.71	31.71	43.24
Attractive energy (10^-21J)	-3.3	-4.6	-7.2	-4.5
Repulsive energy (10^-21J)	51.0	51.3	51.6	51.3
Total energy (10^-21J)	47.7	46.7	44.4	46.8

C (nm)	30.32	31.06	33.19	30.32
Attractive energy (10^-21J)	-7.8	-7.5	-6.7	-7.8
Repulsive energy (10^-21J)	51.7	51.7	51.6	51.7
Total energy (10^-21J)	43.9	44.2	44.9	43.9

References

Combs, Steven A., Deluca, Samuel L., Deluca, Stephanie H., Lemmon, Gordon H., Nannemann, David P., Nguyen, Elizabeth D., Willis, Jordan R., Sheehan, Jonathan H. & Meiler, Jens. (2013). Small-molecule ligand docking into comparative models with Rosetta. Nature Protocols, 8(7), 1277-1298. doi: 10.1038/nprot.2013.074
Raveh, Barak., London, Nir., Zimmerman, Lior. & Schueler-Furman, Ora. (2011). Rosetta FlexPepDockab-initio: Simultaneous folding, docking and refinement of peptides onto their receptors. PLoS ONE, 6(4). doi: 10.1371/journal.pone.0018934
Alam, Nawsad., Goldstein, Oriel., Xia, Bing., Porter, Kathryn A., Kozakov, Dima. & Schueler-Furman, Ora. (2017). High-resolution global peptide-protein docking using fragments-based PIPER-FlexPepDock. PLoS Computational Biology, 13(12), 1-20. doi: 10.1371/journal.pcbi.1005905
Barrientos, Arturo. & Concha, Fernando. (1990). Phenomenological model of classification in conventional hydrocylones. Comminution, 819(1), 287-305. doi: 10.1007/978-1-61779-465-0
Li, Haiou., Lu, Liyao., Chen, Rong., Quan, Lijun., Xia, Xiaoyan. & Lü, Qiang. (2014). PaFlexPepDock: Parallel Ab-initio docking of peptides onto their receptors with full flexibility based on Rosetta. PLoS ONE, 9(5). doi: 10.1371/journal.pone.0094769
Ciemny, Maciej., Kurcinski, Mateusz., Kamel, Karol., Kolinski, Andrzej., Alam, Nawsad., Schueler-Furman, Ora. & Kmiecik, Sebastian. (2018). Protein–peptide docking: opportunities and challenges. Drug Discovery Today, 23(8), 1530-1537. doi: 10.1016/j.drudis.2018.05.006
Elena Pokidysheva, Ying Zhang, Anthony J. Battisti, Carol M. Bator-Kelly, Paul R. Chipman, Chuan Xiao, G. Glenn Gregorio, Wayne A. Hendrickson, Richard J. Kuhn, Michael G. Rossmann. Cryo-EM Reconstruction of Dengue Virus in Complex with the Carbohydrate Recognition Domain of DC-SIGN. Cell Press, 124(3). doi:10.1016
Jörg Polte. Fundamental growth principles of colloidal metal nanoparticles – a new perspective. CrystEngComm, 36. doi:10.1039
Phillip E. Mason, Adrien Lerbret, Marie-Louise Saboungi, George W. Neilson, Christopher E. Dempsey, John W. Brady. Glucose Interactions with a Model Peptide. NCBI, 79(7). doi:10.1002
Taehoon Kim, Kangtaek Lee, Myoung-seon Gong, Sang-Woo Joo. Control of Gold Nanoparticle Aggregates by Manipulation of Interparticle Interaction. ACS Publications. doi:10.1021

@@ Line 37: / Line 37: @@
          <li onclick="display1('nano')"><a href="#ove1">Overview</a></li>
          <li onclick="display1('nano')"><a href="#rep">Repulsion between Gold Nanoparticles</a></li>
+        <br>
+        <li id="abr"><b>Abbreviations</b></li>
+        <li id="abr">E protein: dengue virus envelope protein</li>
+        <li id="abr">PTRS: peptide of tandem-repeated sequence</li>
      </ul>
      <svg class="section-nav-marker" width="200" height="200"></svg>
@@ Line 46: / Line 50: @@
              <section id="ove">
                  <h2>Overview</h2>
-                 <p>Our goal is to design peptides to imitate CLEC5A docking with dengue virus. In order to ensure the peptides and the envelope protein (E protein) of dengue virus have an interaction, all the structure of peptides and proteins and their interactions were modeled using Rosetta. First, we utilized RosettaCM (Comparative modeling with Rosetta) to generate the structure of E protein from a local strain (PL046) based on the crystal structure (PDB: 1OAN). Second, we used the <i>ab initio</i> method to predict the peptide structures purely based on their sequences. Then, we utilized the clustering method to cluster the results and find the most probable structure of the peptide. Finally, we verified the interactions between these predicted peptides and the E protein based on the global protein-protein docking. Figure 1 shows the flow of our simulation.</p>
+                 <p>Our goal is to design the peptides of tandem-repeated sequence (PTRSs) to imitate C-type lectin domain, family 5, member A (CLEC5A) docking with dengue virus. In order to ensure the PTRs and the envelope protein (E protein) of dengue virus have an interaction, all the structure of PTRSs and proteins and their interactions were modeled using Rosetta. First, we utilized RosettaCM (Comparative modeling with Rosetta) to generate the structure of E protein from a local strain (PL046) based on the crystal structure (PDB: 1OAN). Second, we used the <i>ab initio</i> method to predict the PTRSs structures purely based on their sequences. Then, we utilized the clustering method to cluster the results and find the most probable structure of the PTRS. Finally, we verified the interactions between these predicted PTRSs and the E protein based on the global protein-protein docking. Figure 1 shows the flow of our simulation.</p>
                  <br>
                  <div id="imginfo2">
@@ Line 121: / Line 125: @@
                              <li>PDB files generated from step 2</li>
                          </ul>
-                         <p>Output: About 10,000 results. (The lowest Rosetta score of the structure is shown in Figure 2.)</p>
+                         <p>Output: About 10,000 results. (The lowest Rosetta score of the structure is shown in Figure 2)</p>
                          <br>
                          <section id='slide-button3'>Commands and Flags</section>
@@ Line 146: / Line 150: @@
                  <div id="ab">
                      <h3><i>Ab initio</i></h3>
-                     <p>Purpose: To generate the structure of the peptides</p>
+                     <p>Purpose: To generate the structure of the PTRSs</p>
                      <p>Input: </p>
                      <ul>
@@ Line 154: / Line 158: @@
                          <p>The last two inputs were generated from <a href="https://robetta.bakerlab.org/fragmentsubmit.jsp" target="_blank">Robetta</a> Fragment</p>
                      </ul>
-                     <p>Output: About 20,000 results. (Two of the representative structures are shown in Figure 3.)</p>
+                     <p>Output: About 20,000 results. (Two of the representative structures are shown in Figure 3)</p>
                      <br>
                      <section id='slide-button4'>Commands and Flags</section>
@@ Line 242: / Line 246: @@
                  <div id="ppd">
                      <h3>Protein-Protein Docking (global docking)</h3>
-                     <p>Purpose: To find the interaction between peptides and E Protein</p>
+                     <p>Purpose: To find the interaction between PTRSs and E Protein</p>
-                     <p>Input: The structures of ligand (peptide or CLEC5A) and receptor (E protein) in the same input file.</p>
+                     <p>Input: The structures of ligand (PTRS or CLEC5A) and receptor (E protein) in the same input file.</p>
-                     <p>Output: About 10,000 results. (The the most 100 frequent docking sites are shown in Figure 4.)</p>
+                     <p>Output: About 10,000 results. (The most 100 frequent docking sites are shown in Figure 4)</p>
                      <br>
                      <section id='slide-button8'>Commands and Flags</section>
@@ Line 264: / Line 268: @@
                      <div id="imginfo2">
                          <video width="90%" height="auto" muted src="https://static.igem.org/mediawiki/2020/6/62/T--CCU_Taiwan--Model_Rosetta4.mp4" loop autoplay="autoplay"></video>
-                         <p>Figure 4. The lowest 100 Rosetta score results of PTRS-1, PTRS-2 and E protein (PL046) docking respectively. Over the plane is the external surface that can dock with virus.</p>
+                         <p>Figure 4. The best 100 results (based on the Rosetta score) of PTRS-1 or PTRS-2 docking to PL046 E protein (in red). The space above the plane (in grey) indicates the external surface of the virions, where the interactions occur.</p>
                      </div>
                      <br>
@@ Line 275: / Line 279: @@
              <section id="ove1">
                  <h2>Overview</h2>
-                 <p>The weakness of our design is that the peptides from the gold nanoparticles and the ones from the glass fiber compete for the same binding sites on the E protein. Moreover, if the E proteins on the virus particles are fully covered by the gold nanoparticles, there are no sites available to interact the peptides from the glass fiber.</p>
+                 <p>The weakness of our design is that the PTRSs from the gold nanoparticles and the ones from the glass fiber compete for the same binding sites on the E protein. Moreover, if the E proteins on the virus particles are fully covered by the gold nanoparticles, there are no sites available to interact the PTRSs from the glass fiber.</p>
              </section>
              <br>
              <section id="rep">
                  <h2>Repulsion between gold nanoparticles</h2>
-                 <p>To assess this potential problem, we used DLVO theory to calculate the repulsion between gold nanoparticles to estimate the number of gold nanoparticles that would bind to a virus particle. The structure of dengue virus is icosahedral, and there are nine E proteins on each surface. The distances between the potential binding sites can be obtained from the structure in protein data bank (1K4R). DLVO theory can be described as Equation 1.</p>
+                 <p>To assess this potential problem, we used DLVO theory to calculate the repulsion between gold nanoparticles to estimate the number of gold nanoparticles that would bind to a virus particle. The structure of dengue virus is icosahedral, and there are three E proteins on each surface. The distances between the potential binding sites can be obtained from the structure in protein data bank (1K4R). DLVO theory can be described as Equation 1.</p>
                  <br>
-                 <h4>Equation 1. W<sub>total</sub>(D) = W<sub>a</sub>(D) + W<sub>r</sub>(D) = -AR/12D + 2πεε<sub>0</sub>R&Psi;<sub>&delta;</sub><sup>2</sup>exp(-κD)</h4>
+                 <h4>W<sub>total</sub>(D) = W<sub>a</sub>(D) + W<sub>r</sub>(D) = -AR/12D + 2πεε<sub>0</sub>R&Psi;<sub>&delta;</sub><sup>2</sup>exp(-κD) &emsp;&emsp; Equation 1. </h4>
                  <br>
                  <p>W<sub>total</sub>(D): total energy<br>
@@ Line 297: / Line 301: @@
                   </p>
                   <br>
-                  <p>We took several representative positions on adjoining faces of the icosahedron to calculate the interactions between the gold nanoparticles based on DLVO theory. We found the total energies are all positive (Table 1), and these total energies are also larger than the typical biological interactions (~0.5 kcal/mol or 3.49 x10<sup>21</sup> J). The results suggest that there will always be free faces on the virus particles to interact with the peptides conjugated on the test line.</p>
+                  <p>We took several representative positions on adjoining faces of the icosahedron to calculate the interactions between the gold nanoparticles based on DLVO theory. We found the total energies are all positive (Table 1), and these total energies are also larger than the typical biological interactions (~0.5 kcal/mol or 3.49 x10<sup>21</sup> J). The results suggest that there will always be free faces on the virus particles to interact with the PTRS-2 conjugated on the test line.</p>
                   <br>
                   <div id="imginfo2">

Difference between revisions of "Team:CCU Taiwan/Model"

Latest revision as of 16:23, 12 December 2020

Model

Overview

Protocols

RosettaCM (Comparative modeling with Rosetta)

Ab initio

Clustering

Protein-Protein Docking (global docking)

Overview

Repulsion between gold nanoparticles

Wtotal(D) = Wa(D) + Wr(D) = -AR/12D + 2πεε0RΨδ2exp(-κD) Equation 1.

References

W_total(D) = W_a(D) + W_r(D) = -AR/12D + 2πεε₀RΨ_δ²exp(-κD) Equation 1.