Difference between revisions of "Team:Tuebingen/Collaborations"

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{{Tuebingen/SectionStart|id=Introduction|title=Introduction}}
 
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In order to test our deimmunization tool BERT in the context of a meaningful application, we collaborated with the {{Tuebingen/Link|text=iGEM Team Paris-Brettencourt |url=https://2018.igem.org/Team:Paris_Bettencourt}}. Their project focused on the usage of antimicrobial peptides fused together with self-assembling scaffolding proteins as a potential  alternative to classical antibiotic treatment. <br><br>
 
Since biologicals (biopharmaceuticals) often have the problem of being targeted by the immune system by the prescence of specifc anti-drug anitbodies (ADA), we performed our deimmunizaton workflow BERT on a construct of the iGEM team Paris-Brettencourt. A low immunogenicity would be crucial for the application of AMP/scaffolding protein constructs, since in this case binding of ADAs  to the protein would most likely severely impair the self-assembly properties to large complexes.
 
Moreover, this was also a "blind test" for our deimmunization tool, since we applied the steps on a protein which was completely unknown to us. If we solely would have focused on our own botulinum toxin shuttle, with the purpose to optimize the steps of the workflow, there is the risk to lose the general applicability of the workflow arbitrary proteins.<br><br>
 
A second important aspect of this collaboration, was the validation of the structural integrity of the fusion protein we used in our deimmunization workflow. In this external validation we investigated the influence of the AMP on the tertiary structure of the scaffolding protein using MD simulations. Since we have access to the required hardware to run prolonged MD simulation, we were able to share our expertise on this subject and our computational capabilities with the iGEM Team Paris-Brettencourt. Furthermore since both our teams were using MD simulations to model the structure of the proteins in our projects, this collaboration allowed us to exchange knowledge about this topic and help us in the almost never ending process of troubleshooting while simulating complex biological problems.<br><br>
 
For the application of our deimmunization workflow BERT on an AMP/scaffold protein, Paris-Bettencourt provided us with the sequences of their proteins. We focused our approach on a Ovispirin/L-Fucose Mutarotase fusion protein, for multiple reasons. Firstly, this protein has very prominent clusters of epitopes for the three most prevalent MHC class II alleles in central Europe (DRB1*03:01, DRB1*07:01, DRB1*15:01), which allows for very effective reduction in the number of immune epitopes. Secondly, we were able to find many closely and distantly related proteins, leading to an excellent identification of highly conversed residues by our tool, which are in turn avoided in the mutagenesis process. Lastly this fusion protein is of smaller size, which allowed us to include longer MD simulations in our tight schedule for simulation on our hardware.
 
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{{Tuebingen/SectionStart|id=Structural Analysis|title=Structural Analysis}}
 
{{Tuebingen/SingleContent|
 
In the initial step of deimmunization workflow, we required a stable protein structure to be able to  evaluate the influence of possible point mutations. For this purpose, we performed two 50 ns MD simulations, the first using the isolated L-Fucose Mutarotase (PDB ID: 2WCV) domain and the second the L-fucose isomerase/Ovispirin (PDB ID: 1HU5) fusion protein.
 
To simulate the proteins of our collaboration partner,  we used the MD simulation software GROMACS, because it is a widely used tool with an excellent performance. For the force field we chose AMBER99SB, due to the fact that it is generally applicable and well established.
 
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{{Tuebingen/MultiContent|
 
{{Tuebingen/MultiContent|

Revision as of 16:27, 17 October 2018

Collaborations

“Well let me tell you something, brother!”- Hulk Hogan
Title image
US-AFRL-CarollHS


Meet-Up

Figure 2.1 Structure of L-Fucose Mutarotase after a MD simulation of 50 ns
Figure 2.1 Structure of L-Fucose Mutarotase after a MD simulation of 50 ns
Figure 2.2 RMSD plot of the l-fucose mutarotase: The RMSD has been calculated on the coordinates of the backbone atoms
Figure 2.2 RMSD plot of the l-fucose mutarotase: The RMSD has been calculated on the coordinates of the backbone atoms

Figure 3.1 Structure of L-fucose mutarotase-ovispirin fusion protein after a MD simulation of 50 ns. The ovispirin AMP is the helical-like terminal domain indicated in red in picuture.
Figure 3.1 Structure of L-fucose mutarotase-ovispirin fusion protein after a MD simulation of 50 ns. The ovispirin AMP is the helical-like terminal domain indicated in red in picuture.
Figure 3.2: RMSD plot of the l-fucose mutarotase-ovisprin fusion protein: The RMSD has been calculated on the coordinates of the backbone atoms
Figure 3.2: RMSD plot of the l-fucose mutarotase-ovisprin fusion protein: The RMSD has been calculated on the coordinates of the backbone atoms

Figure 4: RMSD plot of the isomerase-domain of the L-fucose mutarotase-ovisprin fusion protein:<br>The RMSD has been calculated on the coordinates of the backbone atoms of the isomerase domain
Figure 4: RMSD plot of the isomerase-domain of the L-fucose mutarotase-ovisprin fusion protein:
The RMSD has been calculated on the coordinates of the backbone atoms of the isomerase domain


The simulation of the FucU isomerase protein for 50 ns without AMP shows a RMSD of about 0.25 nm which indicates some minor conformational changes in the in beginning of the simualtion, stabilizing in the last 20 ns of the simulation (Figure 2.1/2.2).
The simulation of the FucU isomerase together with the AMP Ovispirin as subunit shows more drastic changes to the tertiary structure of the fusion protein. The RMSD value reaches a value of 0-7-0.8 nm in the time span of 50 ns. This can be explained by the fact, that we manually concatenated the isomerase protein with the crystal structure of the Ovispirin protein, which in this initial fusion state is sub-optimally folded. The ovispirin domain undergoes some conformational changes, since it is now connected to the larger isomerase domain Figure 3.1/3.2). We also analyzed the RMSD value over the time of the simulation only for the isomerase domain, since the iGEM Team Paris-Bettencourt was particularity interested in the influence on this domain while being fused to the ovispirin. The plot indicates some minor changes, but the conformation remains stable overall, without the ovispirin domain interfering heavily with the isomerase domain (Figure 4).

Epitope Removal
The second step of our workflow was the identification of the T-cell MHC class II immune epitopes for the three most prevalent alleles in central Europe and their removal by specific amino acid substitutions, which do not alter the tertiary structure of the protein. In our deimmunization workflow, we focused on removing the immune epitopes within the isomerase domain, since there are barely any known homologous of the ovispirin protein. This lack of related protein drastically decreases the accuracy of our deimmunization tool and chances are high to get a structurally unstable and nonfunctional protein. That’s why the following epitope related data are for the isomerase domain only. Initially, we identified a total of 126 immune epitopes for the three alleles mentioned above in the isomerase domain. Between residue 100-130, the isomerase domain has a cluster of amino acids which are part of many different epitopes. This makes the isomerase domain a good candidate for a deimmunization, since the substitution of single amino acids in this cluster, can destroy a large number of epitopes.
Our algorithm calculated the following three amino acid substitution, as a compromise between the maximum structural integrity and the minimal immunogenicity of the protein (Table 1).
These three substitution reduce the number of immune epitopes to 85, which is a reduction by ~33%.

Table 1 Computed amino acid point mutations in the L-fucose mutarotase protein to reduce the immunogenicity.
MutationNumber of epitopes after mutationPredicted ddG value [kcal/mol]
L 49 C113-1.518
I 103 D95-2.009
K 116 D850.032


The changed immune epitope count of serveral of the individual amino acids in Figure 5.1 and Figure 5.2 shows, that especially the clustered regions with many epitopes were edited by our algorithm. This can be explained by the fact that a single mutation in this area has probability the biggest impact on the immunogenicity.


Figure 5.1 T-Cell immune epitopes before the deimmunization workflow shown as combined bar-/lineplot. For each amino acid position, the number of MHC class II epitopes  is plotted. Note that there is a prominent cluster of amino acid between residue 100-130 which are part of many immune epitopes.
Figure 5.1 T-Cell immune epitopes before the deimmunization workflow shown as combined bar-/lineplot. For each amino acid position, the number of MHC class II epitopes is plotted. Note that there is a prominent cluster of amino acid between residue 100-130 which are part of many immune epitopes.
Figure 5.2 T-Cell immune epitopes after the deimmunization workflow shown as combined bar-/lineplot. For each amino acid position, the number of MHC class II epitopes  is plotted.
Figure 5.2 T-Cell immune epitopes after the deimmunization workflow shown as combined bar-/lineplot. For each amino acid position, the number of MHC class II epitopes is plotted.





Structural Verification
To validate whether the change of amino acids at these three positions still results in a stable protein, we did another MD simulation of 25 ns of the mutated protein with and without the fusion domain of the structures of previous MD simulations. Both RMSD plot show a RMDS of < 0.15 nm, which is a very stable conformation regarding the introduction of three point mutations (Figure 6.1/6.2). All three amino acids have their side chains orientated outwards relative to the protein core (Figure 7) and do not interfere with any present secondary structures of the protein or any other amino acids. This also suggests that the our algorithm made a good choice regarding the substituted residues.


Figure 6.1: RMSD plot of the mutated L-fucose mutarotase protein: The RMSD has been calculated on the coordinates of the backbone atoms.
Figure 6.1: RMSD plot of the mutated L-fucose mutarotase protein: The RMSD has been calculated on the coordinates of the backbone atoms.
Figure 6.2 Figure 6.1: RMSD plot of the mutated L-fucose mutarotase-ovisprin fusion protein: The RMSD has been calculated on the coordinates of the backbone atoms of the isomerase domain.
Figure 6.2 Figure 6.1: RMSD plot of the mutated L-fucose mutarotase-ovisprin fusion protein: The RMSD has been calculated on the coordinates of the backbone atoms of the isomerase domain.


Figure 7: Structure of the L-fucose mutarotase-ovispirin fusion protein after the substitution of the three amino acids and a 25 ns MD simulation. In the image the three amino acids are labeled.
Figure 7: Structure of the L-fucose mutarotase-ovispirin fusion protein after the substitution of the three amino acids and a 25 ns MD simulation. In the image the three amino acids are labeled.



Discussion
All in all this collaboration allowed us to test our workflow BERT in a meaningful iGEM related context and we were able to provide the iGEM-Team Paris-Brettencourt with an epitope reduced sequence and a corresponding stable protein structure. Moreover, we could help Paris-Brettencourt to verify the structural integrity of their isomerase protein when fused to the ovispirin AMP. Besides the modeling, we were happy to get the opportunity to discuss some problems we had with or MD simulations with another team that is also using MD simulation to model parts of their project.


BioInfo

Introduction

In order to test our deimmunization tool BERT in the context of a meaningful application, we collaborated with the iGEM Team Paris-Brettencourt. Their project focused on the usage of antimicrobial peptides fused together with self-assembling scaffolding proteins as a potential alternative to classical antibiotic treatment.

Since biologicals (biopharmaceuticals) often have the problem of being targeted by the immune system by the prescence of specifc anti-drug anitbodies (ADA), we performed our deimmunizaton workflow BERT on a construct of the iGEM team Paris-Brettencourt. A low immunogenicity would be crucial for the application of AMP/scaffolding protein constructs, since in this case binding of ADAs to the protein would most likely severely impair the self-assembly properties to large complexes. Moreover, this was also a "blind test" for our deimmunization tool, since we applied the steps on a protein which was completely unknown to us. If we solely would have focused on our own botulinum toxin shuttle, with the purpose to optimize the steps of the workflow, there is the risk to lose the general applicability of the workflow arbitrary proteins.

A second important aspect of this collaboration, was the validation of the structural integrity of the fusion protein we used in our deimmunization workflow. In this external validation we investigated the influence of the AMP on the tertiary structure of the scaffolding protein using MD simulations. Since we have access to the required hardware to run prolonged MD simulation, we were able to share our expertise on this subject and our computational capabilities with the iGEM Team Paris-Brettencourt. Furthermore since both our teams were using MD simulations to model the structure of the proteins in our projects, this collaboration allowed us to exchange knowledge about this topic and help us in the almost never ending process of troubleshooting while simulating complex biological problems.

For the application of our deimmunization workflow BERT on an AMP/scaffold protein, Paris-Bettencourt provided us with the sequences of their proteins. We focused our approach on a Ovispirin/L-Fucose Mutarotase fusion protein, for multiple reasons. Firstly, this protein has very prominent clusters of epitopes for the three most prevalent MHC class II alleles in central Europe (DRB1*03:01, DRB1*07:01, DRB1*15:01), which allows for very effective reduction in the number of immune epitopes. Secondly, we were able to find many closely and distantly related proteins, leading to an excellent identification of highly conversed residues by our tool, which are in turn avoided in the mutagenesis process. Lastly this fusion protein is of smaller size, which allowed us to include longer MD simulations in our tight schedule for simulation on our hardware.


Structural Analysis

In the initial step of deimmunization workflow, we required a stable protein structure to be able to evaluate the influence of possible point mutations. For this purpose, we performed two 50 ns MD simulations, the first using the isolated L-Fucose Mutarotase (PDB ID: 2WCV) domain and the second the L-fucose isomerase/Ovispirin (PDB ID: 1HU5) fusion protein. To simulate the proteins of our collaboration partner, we used the MD simulation software GROMACS, because it is a widely used tool with an excellent performance. For the force field we chose AMBER99SB, due to the fact that it is generally applicable and well established.
Figure 2.1 Structure of L-Fucose Mutarotase after a MD simulation of 50 ns
Figure 2.1 Structure of L-Fucose Mutarotase after a MD simulation of 50 ns
Figure 2.2 RMSD plot of the l-fucose mutarotase: The RMSD has been calculated on the coordinates of the backbone atoms
Figure 2.2 RMSD plot of the l-fucose mutarotase: The RMSD has been calculated on the coordinates of the backbone atoms
Figure 3.1 Structure of L-fucose mutarotase-ovispirin fusion protein after a MD simulation of 50 ns. The ovispirin AMP is the helical-like terminal domain indicated in red in picuture.
Figure 3.1 Structure of L-fucose mutarotase-ovispirin fusion protein after a MD simulation of 50 ns. The ovispirin AMP is the helical-like terminal domain indicated in red in picuture.
Figure 3.2: RMSD plot of the l-fucose mutarotase-ovisprin fusion protein: The RMSD has been calculated on the coordinates of the backbone atoms
Figure 3.2: RMSD plot of the l-fucose mutarotase-ovisprin fusion protein: The RMSD has been calculated on the coordinates of the backbone atoms
Figure 4: RMSD plot of the isomerase-domain of the L-fucose mutarotase-ovisprin fusion protein:<br>The RMSD has been calculated on the coordinates of the backbone atoms of the isomerase domain
Figure 4: RMSD plot of the isomerase-domain of the L-fucose mutarotase-ovisprin fusion protein:
The RMSD has been calculated on the coordinates of the backbone atoms of the isomerase domain
The simulation of the FucU isomerase protein for 50 ns without AMP shows a RMSD of about 0.25 nm which indicates some minor conformational changes in the in beginning of the simualtion, stabilizing in the last 20 ns of the simulation (Figure 2.1/2.2).
The simulation of the FucU isomerase together with the AMP Ovispirin as subunit shows more drastic changes to the tertiary structure of the fusion protein. The RMSD value reaches a value of 0-7-0.8 nm in the time span of 50 ns. This can be explained by the fact, that we manually concatenated the isomerase protein with the crystal structure of the Ovispirin protein, which in this initial fusion state is sub-optimally folded. The ovispirin domain undergoes some conformational changes, since it is now connected to the larger isomerase domain Figure 3.1/3.2). We also analyzed the RMSD value over the time of the simulation only for the isomerase domain, since the iGEM Team Paris-Bettencourt was particularity interested in the influence on this domain while being fused to the ovispirin. The plot indicates some minor changes, but the conformation remains stable overall, without the ovispirin domain interfering heavily with the isomerase domain (Figure 4).


Epitope Revomal

The second step of our workflow was the identification of the T-cell MHC class II immune epitopes for the three most prevalent alleles in central Europe and their removal by specific amino acid substitutions, which do not alter the tertiary structure of the protein. In our deimmunization workflow, we focused on removing the immune epitopes within the isomerase domain, since there are barely any known homologous of the ovispirin protein. This lack of related protein drastically decreases the accuracy of our deimmunization tool and chances are high to get a structurally unstable and nonfunctional protein. That’s why the following epitope related data are for the isomerase domain only. Initially, we identified a total of 126 immune epitopes for the three alleles mentioned above in the isomerase domain. Between residue 100-130, the isomerase domain has a cluster of amino acids which are part of many different epitopes. This makes the isomerase domain a good candidate for a deimmunization, since the substitution of single amino acids in this cluster, can destroy a large number of epitopes.
Our algorithm calculated the following three amino acid substitution, as a compromise between the maximum structural integrity and the minimal immunogenicity of the protein (Table 1).
These three substitution reduce the number of immune epitopes to 85, which is a reduction by ~33%.
Table 1 Computed amino acid point mutations in the L-fucose mutarotase protein to reduce the immunogenicity.
MutationNumber of epitopes after mutationPredicted ddG value [kcal/mol]
L 49 C113-1.518
I 103 D95-2.009
K 116 D850.032
The changed immune epitope count of serveral of the individual amino acids in Figure 5.1 and Figure 5.2 shows, that especially the clustered regions with many epitopes were edited by our algorithm. This can be explained by the fact that a single mutation in this area has probability the biggest impact on the immunogenicity.
Figure 5.1 T-Cell immune epitopes before the deimmunization workflow shown as combined bar-/lineplot. For each amino acid position, the number of MHC class II epitopes  is plotted. Note that there is a prominent cluster of amino acid between residue 100-130 which are part of many immune epitopes.
Figure 5.1 T-Cell immune epitopes before the deimmunization workflow shown as combined bar-/lineplot. For each amino acid position, the number of MHC class II epitopes is plotted. Note that there is a prominent cluster of amino acid between residue 100-130 which are part of many immune epitopes.
Figure 5.2 T-Cell immune epitopes after the deimmunization workflow shown as combined bar-/lineplot. For each amino acid position, the number of MHC class II epitopes  is plotted.
Figure 5.2 T-Cell immune epitopes after the deimmunization workflow shown as combined bar-/lineplot. For each amino acid position, the number of MHC class II epitopes is plotted.



Structural Verification

To validate whether the change of amino acids at these three positions still results in a stable protein, we did another MD simulation of 25 ns of the mutated protein with and without the fusion domain of the structures of previous MD simulations. Both RMSD plot show a RMDS of < 0.15 nm, which is a very stable conformation regarding the introduction of three point mutations (Figure 6.1/6.2). All three amino acids have their side chains orientated outwards relative to the protein core (Figure 7) and do not interfere with any present secondary structures of the protein or any other amino acids. This also suggests that the our algorithm made a good choice regarding the substituted residues.
Figure 6.1: RMSD plot of the mutated L-fucose mutarotase protein: The RMSD has been calculated on the coordinates of the backbone atoms.
Figure 6.1: RMSD plot of the mutated L-fucose mutarotase protein: The RMSD has been calculated on the coordinates of the backbone atoms.
Figure 6.2 Figure 6.1: RMSD plot of the mutated L-fucose mutarotase-ovisprin fusion protein: The RMSD has been calculated on the coordinates of the backbone atoms of the isomerase domain.
Figure 6.2 Figure 6.1: RMSD plot of the mutated L-fucose mutarotase-ovisprin fusion protein: The RMSD has been calculated on the coordinates of the backbone atoms of the isomerase domain.
Figure 7: Structure of the L-fucose mutarotase-ovispirin fusion protein after the substitution of the three amino acids and a 25 ns MD simulation. In the image the three amino acids are labeled.
Figure 7: Structure of the L-fucose mutarotase-ovispirin fusion protein after the substitution of the three amino acids and a 25 ns MD simulation. In the image the three amino acids are labeled.


Discussion

All in all this collaboration allowed us to test our workflow BERT in a meaningful iGEM related context and we were able to provide the iGEM-Team Paris-Brettencourt with an epitope reduced sequence and a corresponding stable protein structure. Moreover, we could help Paris-Brettencourt to verify the structural integrity of their isomerase protein when fused to the ovispirin AMP. Besides the modeling, we were happy to get the opportunity to discuss some problems we had with or MD simulations with another team that is also using MD simulation to model parts of their project.