Proteins: primary and secondary structure: Difference between revisions
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Eric Martz (talk | contribs) Undo revision 3016439 by Dinesh Kulhary (Talk) |
Eric Martz (talk | contribs) Undo revision 3016438 by Dinesh Kulhary (Talk) |
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<StructureSection load='' size='500' side='right' caption='' scene='60/603296/Primaria/2'> | <StructureSection load='' size='500' side='right' caption='' scene='60/603296/Primaria/2'> | ||
<big> | <big> | ||
*''' | *'''Primary structure''' | ||
:* | :*In this <scene name='60/603296/Primaria/2'>initial view</scene> we can see a short fragment of a polypeptide chain in order to analyze some features of its ''primary structure''. Atoms forming the chain ''backbone'' are disposed in zig-zag, as required by geometry of its bonding orbitals. Side chains of amino acid residues (or R groups) protrude outwards either side of backbone. | ||
:* | :*Let's go now to a <scene name='60/603296/Primaria3/1'>peptide bond</scene> between two amino acid residues. Because phenomenon of resonance, peptide bond shows some features of a double bond, which prevents free rotation of atoms on either bond side. So, six atoms marked in <scene name='60/603296/Primaria3/7'>rectangle</scene> on model window are always confined to the same rigid flat. We can test it by <scene name='60/603296/Primaria3/6'>activate rotation</scene>. | ||
:* | :*Polypeptide chain backbone consist in a monotonous succession in wich the following sequenze repeats: <scene name='60/603296/Primaria3/8'>alfa carbon</scene>, <scene name='60/603296/Primaria3/9'>carboxyl group carbon</scene>, <scene name='60/603296/Primaria3/11'>amino group nitrogen</scene>. Minding the restrictions to free rotation in ''peptide bond'', we can visualize the polypeptide chain as a succession of <scene name='60/603296/Primaria3/12'>rigid flats</scene>. Each of these rigid flats can freely rotate respect each other. | ||
*'' ' | *'''Secondary structure'''.- In most proteins there are two main types of secondary structure. | ||
:*<scene name='60/603296/Secundaria/4'> | :*<scene name='60/603296/Secundaria/4'>Alfa helix</scene>.- It is a helical structure with a thread pitch of 0.56 nm. Let's go to a <scene name='60/603296/Secundaria/5'>polar view</scene>. Now let's <scene name='60/603296/Secundaria/7'>hide hydrogen atoms</scene>. The polypeptide chain backbone is coiled and placed at the center of structure, while amino acid side chains protrude outward from this backbone. Let's <scene name='60/603296/Secundaria/8'>hide side chains</scene> for a better understanding. Now, let's back to a <scene name='60/603296/Secundaria/10'>side view</scene>. A <scene name='60/603296/Secundaria/11'>ribbon model</scene> highlights the helical folding of the backbone. Using again a <scene name='60/603296/Secundaria/12'>ball and stick model</scene> we recover <scene name='60/603296/Secundaria/13'>side chains</scene>, now highlighted with a spectral color series. ''Alfa helix'' structure becomes stabilized by many <scene name='60/603296/Secundaria/14'>hydrogen bonds</scene>. All peptide groups in the chain are involved in these hydrogen bonds. <scene name='60/603296/Secundaria/15'>Zoom in</scene> to a better understanding. | ||
:* | :*Primary structure specifies secondary structure, i.e., is the amino acid sequence which determines that a polypeptide chain folds resulting a alfa helix or other secondary structure. Let's consider the effects of <scene name='60/603296/Secundaria/20'>electrical charged residues</scene> of either sign and the <scene name='60/603296/Secundaria/21'>side chains size</scene>. | ||
:*'''<scene name='60/603296/Secundaria2/1'> | :*'''<scene name='60/603296/Secundaria2/1'>Beta sheet</scene>'''.- Polypeptide chain is folded in zigzag arrangement. Let's <scene name='60/603296/Secundaria2/2'>hide hydrogen atoms</scene> and <scene name='60/603296/Secundaria2/3'>side chains</scene> for a better understanding. Notice that a polypeptide chain can have several linear fragments separated by curvatures called ''beta turns''. Now let's recover <scene name='60/603296/Secundaria2/4'>side chains</scene> and highlight the <scene name='60/603296/Secundaria2/5'>hydrogen bonds</scene> between different linear sections of the chain. This hydrogen bonds give stability to the structure. Let's look now the polypeptide chain represented by a <scene name='60/603296/Secundaria2/6'>ribbon model</scene>. | ||
</StructureSection> | </StructureSection> | ||
== References == | == References == | ||
<references/> | <references/> | ||
Revision as of 20:00, 5 October 2019
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