CHEM2052 Tutorial Example4
From Proteopedia
(Difference between revisions)
| Line 5: | Line 5: | ||
The spinning structure you initially view on this page is a protease called Renin. Renin is an '''aspartyl protease''', which cleaves a particular peptide called angiotensinogen. | The spinning structure you initially view on this page is a protease called Renin. Renin is an '''aspartyl protease''', which cleaves a particular peptide called angiotensinogen. | ||
| - | == Background == | + | == '''Background''' == |
In later lecture we will look a little more closely at '''Renin''' (also known as '''angiotensinase'''). This enzyme is involved in a biological pathway leading to elevation of blood pressure, which can be beneficial in many ways. However if this process has become overactive, hypertension (high blood pressure) can result. Hypertension leads to cardiovascular disease which is the leading cause of death globally. The World Health Organisation states "An estimated 17.3 million people died from cardiovascular disease in 2008, representing 30% of all global deaths" see the following web page if you want to know more: [http://www.who.int/mediacentre/factsheets/fs317/en/ Cardiovascular disease facts WHO]. | In later lecture we will look a little more closely at '''Renin''' (also known as '''angiotensinase'''). This enzyme is involved in a biological pathway leading to elevation of blood pressure, which can be beneficial in many ways. However if this process has become overactive, hypertension (high blood pressure) can result. Hypertension leads to cardiovascular disease which is the leading cause of death globally. The World Health Organisation states "An estimated 17.3 million people died from cardiovascular disease in 2008, representing 30% of all global deaths" see the following web page if you want to know more: [http://www.who.int/mediacentre/factsheets/fs317/en/ Cardiovascular disease facts WHO]. | ||
| Line 13: | Line 13: | ||
== '''Active Site''' == | == '''Active Site''' == | ||
| - | This representation illustrates the <scene name='59/596437/Renin_catalytic_residues/2'>active site catalytic residues</scene> of Renin. Consider the mechanism of the enzymatic cleavage of the natural peptide substrate angiotensinase. Identify the structure of the transition state. In later lectures we will see how knowledge of | + | This representation illustrates the <scene name='59/596437/Renin_catalytic_residues/2'>active site catalytic residues</scene> of Renin. Consider the mechanism of the enzymatic cleavage of the natural peptide substrate angiotensinase. Identify the structure of the transition state. In later lectures we will see how knowledge of this transition state can be used to design very effective enzyme inhibitors which mimic this structure, as you will find out, these are (not surprisingly) called "transition state" inhibitors. But for now though we will focus on the Pfizer inhibitor. |
== '''Inhibition of Renin''' == | == '''Inhibition of Renin''' == | ||
This scene shows the <scene name='55/559112/Renin_catalytic_residues/1'>active site of renin with the Pfizer inhibitor bound</scene>. Which part of the inhibitor binds to the catalytic residues of the active site? | This scene shows the <scene name='55/559112/Renin_catalytic_residues/1'>active site of renin with the Pfizer inhibitor bound</scene>. Which part of the inhibitor binds to the catalytic residues of the active site? | ||
| + | |||
| + | == '''Active Site Interactions''' == | ||
| + | |||
| + | Once you have thought about the types of interactions you would expect this inhibitor COULD make at the active site of the enzyme (refer to your notes for an example)then look at the 2-dimensional "map" of the active site on your tutorial sheet and compare this to the 3-dimensional representations here. | ||
| + | This view shows the amino acid residues on the left hand side of your "map". | ||
| + | This view shows the amino acid residues on the right hand side of your "map". | ||
== Structural highlights == | == Structural highlights == | ||
Revision as of 07:56, 13 August 2014
CHEM2052_Tutorial_Example4
| |||||||||||
References
- ↑ Powell NA, Ciske FL, Cai C, Holsworth DD, Mennen K, Van Huis CA, Jalaie M, Day J, Mastronardi M, McConnell P, Mochalkin I, Zhang E, Ryan MJ, Bryant J, Collard W, Ferreira S, Gu C, Collins R, Edmunds JJ. Rational design of 6-(2,4-diaminopyrimidinyl)-1,4-benzoxazin-3-ones as small molecule renin inhibitors. Bioorg Med Chem. 2007 Sep 1;15(17):5912-49. Epub 2007 Jun 2. PMID:17574423 doi:10.1016/j.bmc.2007.05.069
