Proteins: primary and secondary structure: Difference between revisions

From Proteopedia
Jump to navigation Jump to search
← Older edit
Joel L. Sussman (talk | contribs)
ConfirmAccount, Editor, Journal, Mutation, Print3D, Tester, Bureaucrats, Administrators
7,920 edits
No edit summary
m grammar and spelling
 
(11 intermediate revisions by 4 users not shown)
Line 1: Line 1:
[[es:Proteins: primary and secondary structure (Spanish)]]
[[es:Proteins: primary and secondary structure (Spanish)]]
[[hi:Proteins: primary and secondary structure (Hindi)]]
<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>
Line 5: Line 7:
:*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.
:*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>.
:*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.
:*Polypeptide chain backbone consist in a monotonous succession in wich the following sequenze repeats: <scene name='60/603296/Primaria3/8'>alpha 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.
*'''Secondary structure'''.- In most proteins there are two main types of secondary structure.
:*<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.
:*<scene name='60/603296/Secundaria/4'>Alpha 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. ''Alpha 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>.
:*Primary structure specifies secondary structure, i.e., is the amino acid sequence which determines that a polypeptide chain folds resulting in an alpha 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'>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>.
:*'''<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>.


== Files for 3D printer ==
<i class="fas fa-cubes"></i> An protein alpha helix in different representations by [[User:Marius Mihasan|Marius Mihasan]] [https://3dprint.nih.gov/discover/3dpx-014891  <i class="fas fa-download"></i>]
</StructureSection>
</StructureSection>
== References ==
== References ==
<references/>
<references/>
[[Category:3D printer files]]

Latest revision as of 21:35, 8 December 2021


  • Primary structure
  • In this 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 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 on model window are always confined to the same rigid flat. We can test it by .
  • Polypeptide chain backbone consist in a monotonous succession in wich the following sequenze repeats: , , . Minding the restrictions to free rotation in peptide bond, we can visualize the polypeptide chain as a succession of . Each of these rigid flats can freely rotate respect each other.
  • Secondary structure.- In most proteins there are two main types of secondary structure.
  • .- It is a helical structure with a thread pitch of 0.56 nm. Let's go to a . Now let's . 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 for a better understanding. Now, let's back to a . A highlights the helical folding of the backbone. Using again a we recover , now highlighted with a spectral color series. Alpha helix structure becomes stabilized by many . All peptide groups in the chain are involved in these hydrogen bonds. to a better understanding.
  • Primary structure specifies secondary structure, i.e., is the amino acid sequence which determines that a polypeptide chain folds resulting in an alpha helix or other secondary structure. Let's consider the effects of of either sign and the .
  • .- Polypeptide chain is folded in zigzag arrangement. Let's and for a better understanding. Notice that a polypeptide chain can have several linear fragments separated by curvatures called beta turns. Now let's recover and highlight the 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 .


Files for 3D printer

An protein alpha helix in different representations by Marius Mihasan

Drag the structure with the mouse to rotate

ReferencesReferences

Proteopedia Page Contributors and Editors (what is this?)Proteopedia Page Contributors and Editors (what is this?)

Alejandro Porto, Joel L. Sussman, Dinesh Kulhary, Eric Martz, Jaime Prilusky, Meghan Wright
Retrieved from "https://proteopedia.openfox.io/wiki/index.php?title=Proteins:_primary_and_secondary_structure&oldid=3488222"