Sandbox 37
From Proteopedia
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| + | == '''LYSOZYME''' == | ||
| + | Lysozyme, pictured to the right, is an enzyme found commonly in saliva, tears, mucus, and even egg whites. This particular enzyme breaks down bonds of bacterial cell walls. Specifically, lysozyme serves to catalyze the hydrolysis of the Beta (1->4) glycosidic linkage which occurs between N-acetylmuramic acid and N-acetylglucosamine (NAG) of peptidoglycan. Lysozyme is also capable of hydrolyzing polyNAG which constitutes chitin, a major component of fungi cell walls as well as the exoskeletons of insects and crustaceans. | ||
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| + | The Lysozyme in egg white, specifically hen egg whites (HEW), is the most widely studied and hence the most widely understood species of the enzyme. The picture to the right reveals a HEW lysozyme's cartoon structure with the secondary structure in grey and the yellow being salt bridges throughout the molecule. | ||
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<applet load='3IJU' size='300' frame='true' align='right' caption='Insert caption here' /> | <applet load='3IJU' size='300' frame='true' align='right' caption='Insert caption here' /> | ||
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| + | = Secondary Structure = | ||
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| + | The secondary structure of lysozyme consists of 5 beta pleated sheets along with 5 alpha helices. These structures are displayed as <scene name='Sandbox_37/1/1'>cartoon rockets</scene> (click link to view in Jmol) where the alpha helices are labelled pink and the beta pleated sheets are yellow. The two shortest cartoon rockets which should be yellow beta pleated sheets are labelled pink by the program when told to label different secondary structures differently. This is due to the fact that two of the beta pleated sheets are slightly abnormally shaped and thus can be confused for alpha helices. | ||
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| + | = Distribution of Polar and NonPolar residues = | ||
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| + | A distribution of polar vs nonpolar residues can be viewed <scene name='Sandbox_37/Polarblue_nonpolarred/1'>here</scene>. The residues on this backbone stucture of lysozyme are labelled blue if they are polar and red if they are nonpolar. By viewing this structure one is capable of seeing the overall dispersion of polar vs. nonpolar residues. Polar residues, which are hydrophillic, are generally found on the outside of a molecule so that they can interact with surrounding water molecules. This is much more apparent when viewing <scene name='Sandbox_37/Polarblue_nonpolarred2/1'>this</scene> structural format (blue again represents polar while red represents nonpolar residues. Lysozyme is slightly unique in its polar vs nonpolar residues in that, as is apparent in the structure just mentioned, there are still a large number of nonpolar residues towards the outside surface of the molecule. This is due to the fact that lysozyme is a relatively "open" molecule meaning that it is not tightly bound and thus does not hide all of its nonpolar residues with an outward polar residue shell. | ||
Revision as of 00:04, 29 October 2010
| Please do NOT make changes to this Sandbox. Sandboxes 30-60 are reserved for use by Biochemistry 410 & 412 at Messiah College taught by Dr. Hannah Tims during Fall 2012 and Spring 2013. |
LYSOZYME
Lysozyme, pictured to the right, is an enzyme found commonly in saliva, tears, mucus, and even egg whites. This particular enzyme breaks down bonds of bacterial cell walls. Specifically, lysozyme serves to catalyze the hydrolysis of the Beta (1->4) glycosidic linkage which occurs between N-acetylmuramic acid and N-acetylglucosamine (NAG) of peptidoglycan. Lysozyme is also capable of hydrolyzing polyNAG which constitutes chitin, a major component of fungi cell walls as well as the exoskeletons of insects and crustaceans.
The Lysozyme in egg white, specifically hen egg whites (HEW), is the most widely studied and hence the most widely understood species of the enzyme. The picture to the right reveals a HEW lysozyme's cartoon structure with the secondary structure in grey and the yellow being salt bridges throughout the molecule.
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Secondary Structure
The secondary structure of lysozyme consists of 5 beta pleated sheets along with 5 alpha helices. These structures are displayed as (click link to view in Jmol) where the alpha helices are labelled pink and the beta pleated sheets are yellow. The two shortest cartoon rockets which should be yellow beta pleated sheets are labelled pink by the program when told to label different secondary structures differently. This is due to the fact that two of the beta pleated sheets are slightly abnormally shaped and thus can be confused for alpha helices.
Distribution of Polar and NonPolar residues
A distribution of polar vs nonpolar residues can be viewed . The residues on this backbone stucture of lysozyme are labelled blue if they are polar and red if they are nonpolar. By viewing this structure one is capable of seeing the overall dispersion of polar vs. nonpolar residues. Polar residues, which are hydrophillic, are generally found on the outside of a molecule so that they can interact with surrounding water molecules. This is much more apparent when viewing structural format (blue again represents polar while red represents nonpolar residues. Lysozyme is slightly unique in its polar vs nonpolar residues in that, as is apparent in the structure just mentioned, there are still a large number of nonpolar residues towards the outside surface of the molecule. This is due to the fact that lysozyme is a relatively "open" molecule meaning that it is not tightly bound and thus does not hide all of its nonpolar residues with an outward polar residue shell.
