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{{Sandbox_MedChem-StOlaf_Hanson}}<!-- PLEASE ADD YOUR CONTENT BELOW HERE -->
 
==Validation of the Binding Action at the DPP-4 Protein==
==Validation of the Binding Action at the DPP-4 Protein==
<StructureSection load='1nu6' size='340' side='right' caption='The 1nu6 DPP-4 binding' scene=''>
<StructureSection load='1nu6' size='340' side='right' caption='The 1nu6 DPP-4 binding' scene=''>
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== 3Q8W ==
== 3Q8W ==
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Outside view of 3Q8W binding pocket (orange) with clashes shown
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http://proteopedia.org/wiki/images/9/9b/3Q8W_Clash_Outside.png
3Q8W is the structure with the worst resolution (3.64 Å), but the majority of the structure’s validation issues are due to its large clashscore. It has little to no RSRZ issues. The structure itself is valid, although its resolution is poor.
3Q8W is the structure with the worst resolution (3.64 Å), but the majority of the structure’s validation issues are due to its large clashscore. It has little to no RSRZ issues. The structure itself is valid, although its resolution is poor.
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Click to see catalytic triad of 3Q8W: [[http://proteopedia.org/wiki/images/1/12/3Q8W_Clashes_Triad.png]]
== 1NU6 ==
== 1NU6 ==
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== 1PFQ ==
== 1PFQ ==
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Image of the 1PFQ binding pocket and surrounding clashes
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http://proteopedia.org/wiki/images/9/9a/1PFQ_RSRZ_bwr.png
1PFQ has the highest number of RSRZ issues and a resolution of 1.9 Å. However, the largest gaps in electron density are located on the edges of the protein (red), and the majority of the gaps are relatively small (blue).
1PFQ has the highest number of RSRZ issues and a resolution of 1.9 Å. However, the largest gaps in electron density are located on the edges of the protein (red), and the majority of the gaps are relatively small (blue).
1PFQ’s binding pocket is surrounded by gaps in the electron density data. The residues of the catalytic triad do not have any missing data. Therefore, while the overall structure of 1PFQ isn’t particularly accurate, studies focusing on the catalytic triad should have accurate data.
1PFQ’s binding pocket is surrounded by gaps in the electron density data. The residues of the catalytic triad do not have any missing data. Therefore, while the overall structure of 1PFQ isn’t particularly accurate, studies focusing on the catalytic triad should have accurate data.
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Click to see the catalytic triad: [[http://proteopedia.org/wiki/images/7/75/1PFQ_RSRZ_Triad.png]]
== 5T4B ==
== 5T4B ==
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5T4B has a resolution of 1.76 Å and can be seen here with the 75N ligand within the binding pocket. There are more RSRZ outliers near the entrance to the binding cavity, but few clashes near the actual binding site. This indicates that the binding pocket itself has validity, but the mechanism for the ligand entering the cavity may be in question.
5T4B has a resolution of 1.76 Å and can be seen here with the 75N ligand within the binding pocket. There are more RSRZ outliers near the entrance to the binding cavity, but few clashes near the actual binding site. This indicates that the binding pocket itself has validity, but the mechanism for the ligand entering the cavity may be in question.
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<jmol><jmollink><text>View Figure 1c: 5T4B</text><script>exit;figure=1;SCRIPT "http://proteopedia.org/wiki/images/a/a4/5t4b_A.png";spin on</script></jmollink></jmol>
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<jmol><jmollink><text>View Figure 1c: 5T4B overview</text><script>exit;figure=1;SCRIPT "http://proteopedia.org/wiki/images/a/a4/5t4b_A.png";spin on</script></jmollink></jmol>
Shown in Figure 1c is a view of a the 75N ligand inside the binding pocket of DPP-4.
Shown in Figure 1c is a view of a the 75N ligand inside the binding pocket of DPP-4.
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To see the binding pocket of the 75N ligand at the catalytic triad, click on Figure 1d. There is electron density from the catalytic triad that extends into the binding pocket, and surrounding the functional binding groups on the ligand. No RSRZ outliers are found within the binding pocket, and this conformation of the molecule is supported by the electron density surrounding the catalytic triad.
To see the binding pocket of the 75N ligand at the catalytic triad, click on Figure 1d. There is electron density from the catalytic triad that extends into the binding pocket, and surrounding the functional binding groups on the ligand. No RSRZ outliers are found within the binding pocket, and this conformation of the molecule is supported by the electron density surrounding the catalytic triad.
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<jmol><jmollink><text>View Figure 1d: 5T4B</text><script>exit;figure=1;SCRIPT "http://proteopedia.org/wiki/images/a/a4/5t4b_A.png";zoomto *5</script></jmollink></jmol>
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<jmol><jmollink><text>View Figure 1d: 5T4B ligand</text><script>exit;figure=1;SCRIPT "http://proteopedia.org/wiki/images/a/a4/5t4b_A.png";zoomto *5</script></jmollink></jmol>
== 6B1E ==
== 6B1E ==
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In the 6B1E protein with resolution 1.77 Å, the big density sizes are far from the ligand, which doesn’t have a significant impact on the binding pocket interaction. All of the missing electron density is not impacting the actual validity of the binding site.
In the 6B1E protein with resolution 1.77 Å, the big density sizes are far from the ligand, which doesn’t have a significant impact on the binding pocket interaction. All of the missing electron density is not impacting the actual validity of the binding site.
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Figure 1g: [[http://proteopedia.org/wiki/images/7/7a/6b1e.png]]
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Figure 1e: Broad view of the 6B1E binding
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<jmol><jmollink><text>View Figure 1g: 6B1E overview</text><script>exit;figure=1;SCRIPT "http://proteopedia.org/wiki/images/7/7a/6b1e.png";spin on</script></jmollink></jmol>
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http://proteopedia.org/wiki/images/7/7a/6b1e.png
In the 6B1E crystal structure, the catalytic triad seem to have some missing density but still not significant enough to be an invalid structure and interaction with the LF7 ligand.
In the 6B1E crystal structure, the catalytic triad seem to have some missing density but still not significant enough to be an invalid structure and interaction with the LF7 ligand.
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<jmol><jmollink><text>View Figure 1g: 6B1E Triad Density</text><script>exit;figure=1;SCRIPT "http://proteopedia.org/wiki/images/6/6e/6b1e_density.png";spin on</script></jmollink></jmol>
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Figure 1f: View of the 6B1E catalytic triad
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http://proteopedia.org/wiki/images/6/6e/6b1e_density.png
== 4N8D ==
== 4N8D ==
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4N8D with resolution 1.65 Å: an overview of the binding site, missing densities, and clashes. Overall, the missing density sizes are not significant, which gives this crystal a valid structure. And the clashscore is not high, which means it’s not conflicting with the binding site. This crystal seems to be less valid than 6B1E in terms of the RSRZ score, but not enough to be claimed an invalid structure.
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4N8D with resolution 1.65 Å: an overview of the binding site and missing densities. Overall, the missing density sizes are not significant, which gives this crystal a valid structure.
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4N8D: the catalytic triads missing densities are shown. The densities of the amino acids are not significant enough to be viewed as an invalid structure, but does have more missing than the 6B1E crystal.
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<jmol><jmollink><text>View Figure 1g: 4N8D overview</text><script>exit;figure=1;SCRIPT "http://proteopedia.org/wiki/images/0/00/4n8d_D.png";spin on</script></jmollink></jmol>
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The catalytic triad's electron densities are shown. There isn’t enough density missing around the catalytic triad for the structure to be considered invalid.
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<jmol><jmollink><text>View Figure 1h: 4N8D catalytic triad</text><script>exit;figure=1;SCRIPT "http://proteopedia.org/wiki/images/f/f4/4n8d_E.png";zoomto *4</script></jmollink></jmol>
== 4A5S ==
== 4A5S ==
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Broad view of 4A5S molecule with binding pocket and clashes
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<jmol><jmollink><text>View Figure 1i: 4A5S overview</text><script>exit;figure=1;SCRIPT "http://proteopedia.org/wiki/images/b/b7/4A5S_G.png";spin on</script></jmollink></jmol>
4A5S has the highest resolution of all of the DPP4 structures at 1.62 Å. It has a relatively low amount of RSRZ issues, although the gaps are larger. Also, its RSRZ issues are generally only around the edges of the protein chain.
4A5S has the highest resolution of all of the DPP4 structures at 1.62 Å. It has a relatively low amount of RSRZ issues, although the gaps are larger. Also, its RSRZ issues are generally only around the edges of the protein chain.
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4A5S: There are no clashes around the binding pocket, meaning this should be an accurate model. Also the electron density doesn’t show any gaps.
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<jmol><jmollink><text>View Figure 1j: 4A5S ligand (N7F)</text><script>exit;figure=1;SCRIPT "http://proteopedia.org/wiki/images/b/b7/4A5S_G.png";zoomto *5</script></jmollink></jmol>
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There are no clashes around the binding pocket [[http://proteopedia.org/wiki/images/4/4d/4A5S_RSRZ_Triad.png]], meaning this should be an accurate model. Also the electron density doesn’t show any gaps.
== Structural highlights ==
== Structural highlights ==

Current revision

Validation of the Binding Action at the DPP-4 Protein

The 1nu6 DPP-4 binding

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Click a green link on the left to load Figure 1

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References

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