User:David Canner/Sandbox good: Difference between revisions
David Canner (talk | contribs) No edit summary |
David Canner (talk | contribs) No edit summary |
||
| Line 3: | Line 3: | ||
This is a list of tips and tricks to develop effective scenes for your pages. The scenes below were taken from the indicated pages. | This is a list of tips and tricks to develop effective scenes for your pages. The scenes below were taken from the indicated pages. | ||
<StructureSection load='1dq8' size='500' side='right' scene='User:David_Canner/Sandbox_P/ | <StructureSection load='1dq8' size='500' side='right' scene='User:David_Canner/Sandbox_P/Full/1' caption=''> | ||
===Smooth Transitions=== | ===Smooth Transitions=== | ||
====Tip #1: When developing a series of scenes illustrating related parts of a protein, use the “transition options” to create smooth transitions void of peculiar zoom-outs, etc.==== | ====Tip #1: When developing a series of scenes illustrating related parts of a protein, use the “transition options” to create smooth transitions void of peculiar zoom-outs, etc.==== | ||
=====Example from the page [[The Structure of PI3K]]: ===== | =====Example from the page [[The Structure of PI3K]]: ===== | ||
<center><scene name='User:David_Canner/Sandbox_P/ | <center><scene name='User:David_Canner/Sandbox_P/Full/1'>Initial Scene (Reset)</scene> </center> | ||
Although no <scene name='User:David_Canner/Sandbox_P/Inhibitor_main/4'>crystal structure of PI3K</scene> with bound substate analog has been solved, a model for PIP2 phosphorylation has been developed and is generally supported. In this model, the headgroup of PIP2 is <scene name='User:David_Canner/Sandbox_P/Catalytic_cavity/2'>positioned in a cavity</scene> between the <scene name='User:David_Canner/Sandbox_P/Catalytic_site/1'>C-terminal helix 12 of the kinase domain, the “activation” loop, and the “catalytic” loop</scene>. This puts the 5-phosphate of PIP2 near Lys 973 and the <scene name='User:David_Canner/Sandbox_P/Catalytic_site_atp_lys/1'>I-phosphate of ATP near Lys 807 and Lys 808</scene>. The <scene name='User:David_Canner/Sandbox_P/Catalytic_site_pip2/1'>basic residues Arg 947</scene> and Lys 973 can bind the 4-Phosphate of PIP2 and help provide the Class I PI3Ks with their specificity for PIP2. Once PIP2 and ATP are bound, it is believed <scene name='User:David_Canner/Sandbox_P/Catalytic_site_his/1'>His 948 rotates to interact with PIP2</scene>, deprotonating it at the C-3 Hydroxyl position creating a nucleophile. This nucleophile subsequently attacks the gamma phosphate of ATP producing PIP3. | Although no <scene name='User:David_Canner/Sandbox_P/Inhibitor_main/4'>crystal structure of PI3K</scene> with bound substate analog has been solved, a model for PIP2 phosphorylation has been developed and is generally supported. In this model, the headgroup of PIP2 is <scene name='User:David_Canner/Sandbox_P/Catalytic_cavity/2'>positioned in a cavity</scene> between the <scene name='User:David_Canner/Sandbox_P/Catalytic_site/1'>C-terminal helix 12 of the kinase domain, the “activation” loop, and the “catalytic” loop</scene>. This puts the 5-phosphate of PIP2 near Lys 973 and the <scene name='User:David_Canner/Sandbox_P/Catalytic_site_atp_lys/1'>I-phosphate of ATP near Lys 807 and Lys 808</scene>. The <scene name='User:David_Canner/Sandbox_P/Catalytic_site_pip2/1'>basic residues Arg 947</scene> and Lys 973 can bind the 4-Phosphate of PIP2 and help provide the Class I PI3Ks with their specificity for PIP2. Once PIP2 and ATP are bound, it is believed <scene name='User:David_Canner/Sandbox_P/Catalytic_site_his/1'>His 948 rotates to interact with PIP2</scene>, deprotonating it at the C-3 Hydroxyl position creating a nucleophile. This nucleophile subsequently attacks the gamma phosphate of ATP producing PIP3. | ||
====Tip #2: It is best to establish a color scheme for all domains of interest and to stick with this color scheme throughout the analysis==== | ====Tip #2: It is best to establish a color scheme for all domains of interest and to stick with this color scheme throughout the analysis==== | ||
Revision as of 13:24, 21 November 2010
How to Make Excellent Scenes
This is a list of tips and tricks to develop effective scenes for your pages. The scenes below were taken from the indicated pages.
Smooth TransitionsExample from the page The Structure of PI3K:Although no with bound substate analog has been solved, a model for PIP2 phosphorylation has been developed and is generally supported. In this model, the headgroup of PIP2 is between the . This puts the 5-phosphate of PIP2 near Lys 973 and the . The and Lys 973 can bind the 4-Phosphate of PIP2 and help provide the Class I PI3Ks with their specificity for PIP2. Once PIP2 and ATP are bound, it is believed , deprotonating it at the C-3 Hydroxyl position creating a nucleophile. This nucleophile subsequently attacks the gamma phosphate of ATP producing PIP3. Tip #2: It is best to establish a color scheme for all domains of interest and to stick with this color scheme throughout the analysisExample from the page The Structure of PI3K(residues 340-345) is anchored into Helix α11K of the (residues 1017-1024) nSH2 interacts with the through a network of charge-charge interactions involving two loops on nSH2 (Residues 374-377 & 350-354) and C2 residues 364-371, a strong Tip #3: Providing a wide view scene of an area of interest before zooming in provides contextExample from the page The Structure of PI3KThis loop in which contains the hotspots (residues 542-546) is located precisely where The salt bridge formed between like PDGFR, eliminating nSH2-mediated inhibition of p110α and activating the enzyme to phosphorylate PIP2 into PIP3. Tip #4: When switching focus to a new domain, it is best to zoom out and orient the reader to the new domain of interestExample from the page The Structure of PI3K:(residues 340-345) is anchored into Helix α11K of the (residues 1017-1024) nSH2 interacts with the through a network of charge-charge interactions involving two loops on nSH2 (Residues 374-377 & 350-354) and C2 residues 364-371, a strong Tip #5: Eliminate the Scene transition when comparing different binding interactions for similar ligandsExample from the page PI3K Activation, Inhibition, & Medical Implications:LY294002, a competitive inhibitor of ATP binding in the PI3K kinase domain, was first discovered by scientists at Eli Lilly. Quercetin, Myricetin & Staurosporine are natural compounds which broadly inhibit protein kinases. Understanding how ATP binds to the ATP binding site of PI3Kγ and how various inhibitors prevent this interaction helps elucidate ways to develop effective, selective inhibitors. See p110γ bound to (1e8x), (1e7u), (1e7v), (1e8w), (1e8z), (1e90). Example from the page PI3K Activation, Inhibition, & Medical Implications:
|
| ||||||||||