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Trypsin is a serine protease that works enzymatically by using a mixture of base, acid, and covalent catalysis. The protein uses serine in its active site to interact covalently with the substrate. To create a nucleophilic attack, a histidine group activates a serine group via base catalysis and covalent catalysis follows.To complete the formation of a nucleophile, aspartic acid pulls positive charge from histidine, completing the catalytic triad and forming an effective nucleophile. This forms a tetrahedral intermediate, in which the anionic carbonyl oxygen moves into the active site to a location known as the oxyanion hole. The tetrahedral intermediate is followed by acid catalysis from the -NH2 of the of the c-terminus, resulting in a broken peptide bond in the substrate.The transition state from the tetrahedral intermediate is stabilized by Asp 189 interacting with Gly 219 to create a stable specificity pocket. The acyl-enzyme intermediate is present, and hydrolysis occurs which ultimately releases the c-terminal chain of the substrate and forms a new bond between water and the carbonyl carbon of the enzyme-substrate complex. The covalent C-O bond of the substrate-enzyme complex is broken, and the enzyme is reformed as the product is released. | Trypsin is a serine protease that works enzymatically by using a mixture of base, acid, and covalent catalysis. The protein uses serine in its active site to interact covalently with the substrate. To create a nucleophilic attack, a histidine group activates a serine group via base catalysis and covalent catalysis follows.To complete the formation of a nucleophile, aspartic acid pulls positive charge from histidine, completing the catalytic triad and forming an effective nucleophile. This forms a tetrahedral intermediate, in which the anionic carbonyl oxygen moves into the active site to a location known as the oxyanion hole. The tetrahedral intermediate is followed by acid catalysis from the -NH2 of the of the c-terminus, resulting in a broken peptide bond in the substrate.The transition state from the tetrahedral intermediate is stabilized by Asp 189 interacting with Gly 219 to create a stable specificity pocket. The acyl-enzyme intermediate is present, and hydrolysis occurs which ultimately releases the c-terminal chain of the substrate and forms a new bond between water and the carbonyl carbon of the enzyme-substrate complex. The covalent C-O bond of the substrate-enzyme complex is broken, and the enzyme is reformed as the product is released. | ||
| - | + | Each member of the catalytic triad can be seen below. | |
<scene name='72/725331/Ser_195_zoom/2'>Important Serine Residue</scene> | <scene name='72/725331/Ser_195_zoom/2'>Important Serine Residue</scene> | ||
Revision as of 15:21, 19 February 2016
The Mechanism of Trypsin
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References
David Elkins
Cameron Brown
