Phytanoyl-CoA dioxygenase Structure: Difference between revisions
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4 Sheets | 4 Sheets | ||
3 beta-hairpins | <br>3 beta-hairpins | ||
4 beta bulges | <br>4 beta bulges | ||
15 strands | <br>15 strands | ||
10 helices | <br>10 helices | ||
6 helix-helix interactions | <br>6 helix-helix interactions | ||
24 beta turns | <br>24 beta turns | ||
1 gamma turn | <br>1 gamma turn | ||
It should be noted that a large proportion of the alpha helices are located on the outside of the protein, while the core is mostly composed of beta sheets. One beta sheet is composed of 7 strands, this makes up most of the protein core. These structural characteristics are further shown in the topology maps below. | It should be noted that a large proportion of the alpha helices are located on the outside of the protein, while the core is mostly composed of beta sheets. One beta sheet is composed of 7 strands, this makes up most of the protein core. These structural characteristics are further shown in the topology maps below. | ||
Revision as of 22:21, 9 June 2008
Originally, the structure of our protein was experimentally defined (by Zhang, Z., Butler, D., McDonough, M.A et.al.) via X-ray diffraction.
Name - Phytanoyl-CoA dioxygenase (PHYHD1)
Classification - Oxidoreductase
Resolution (Amstrongs) - 1.90
R-Value - 0.221 (obs, relatively low)
Space Group - P 3.1 2 1
Unit Cell Paramters (Amstrongs) - a = 91.97, b = 91.97, c = 81.61
Unit Cell Angles - alpha = 90.00, beta = 90.00, gamma = 120.00
Using Pymol the image was visualized to get a general overview of the protein. These are below.
This image was taken from behind the pocket of the molecule (cartoon).
The pocket can be seen here in a cartoon depiction.
The surface was rendered and the image from behind the pocket was taken again.
This is the surface rendering of the pocket.
There are high levels of steric hinderance if the approaching ligand comes from behind the molecule (figure 1, figure 3).
There is a large hole in the structure of our protein (figure 2, figure 4). As steric hinderance is low and the surface area is maximized at this position, it would seem that this area should encompass the binding sites of our protein, or at least be the location of some form of interaction. The fact such a definitive hole in the structure of the protein exists lead us to investigate further properties around this region. Liam will go into more details as to the function of the binding sites and a comparison to a similar protein in his section.
Promotif returned the following list of structural features.
4 Sheets
3 beta-hairpins
4 beta bulges
15 strands
10 helices
6 helix-helix interactions
24 beta turns
1 gamma turn
It should be noted that a large proportion of the alpha helices are located on the outside of the protein, while the core is mostly composed of beta sheets. One beta sheet is composed of 7 strands, this makes up most of the protein core. These structural characteristics are further shown in the topology maps below.
Showing the topology of the protein. Reproduced from the European Bioinformatics Institute,
http://www.ebi.ac.uk/thornton-srv/databases/pdbsum/2opw/domA01.gif
Showing another topology of the protein. Reproduced from the European Bioinformatics Institute,
http://www.ebi.ac.uk/
