User:Karsten Theis/turns
From Proteopedia
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A '''beta turn''' is a secondary structure element consisting of four consecutive amino acids (or three consecutive peptide planes). The geometry of turns correspond to a change in the direction of the polypeptide backbone, with a short distance between the first and fourth alpha carbon. | A '''beta turn''' is a secondary structure element consisting of four consecutive amino acids (or three consecutive peptide planes). The geometry of turns correspond to a change in the direction of the polypeptide backbone, with a short distance between the first and fourth alpha carbon. | ||
| - | <ref>PMID:36293166</ref> | ||
==Turns in 3D== | ==Turns in 3D== | ||
| - | <StructureSection load='' size='500' side='right' caption='' scene='10/1072233/Turn/ | + | <StructureSection load='' size='500' side='right' caption='' scene='10/1072233/Turn/9'> |
The repetitive secondary structure elements (alpha helices and beta strands) go in a single direction. Turns change the direction of the main chain, allowing them to connect alpha helices and beta strands at the surface of a globular protein. Of the six main chain hydrogen bonding partners of a turn, a maximum of two are engaged in hydrogen bonding, and turns are rarely found in the hydrophobic core. Below are three different protein folds highlighting the position of turns. | The repetitive secondary structure elements (alpha helices and beta strands) go in a single direction. Turns change the direction of the main chain, allowing them to connect alpha helices and beta strands at the surface of a globular protein. Of the six main chain hydrogen bonding partners of a turn, a maximum of two are engaged in hydrogen bonding, and turns are rarely found in the hydrophobic core. Below are three different protein folds highlighting the position of turns. | ||
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==Exploring turns== | ==Exploring turns== | ||
| - | The interactive Jmol window shows a <scene name='10/1072233/Turn/ | + | The interactive Jmol window shows a <scene name='10/1072233/Turn/10'>turn</scene> (residues 67-70 of the [[2hmr]] structure shown previously) that you can explore. Four consecutive amino acids are said to form a beta turn if the alpha carbon atoms of the first and the fourth residue are in close proximity (less than 7.0 or 7.5 Angstrom<ref>PMID:36293166</ref>). However, this also happens in alpha helices and 3(10) helices, and these are not classified as beta turn. |
In the structure fragment shown, the alpha carbon atoms are numbered 1 through 4 (relative numbering, sometimes also given as n, n+1, n+2, n+3), and the distance between the carbonyl oxygen and the amide hydrogen is indicated (dashed line and magnitude). Side chains are truncated to just show the beta carbon, and residues 1 and 4 have some main chain omitted for clarity. | In the structure fragment shown, the alpha carbon atoms are numbered 1 through 4 (relative numbering, sometimes also given as n, n+1, n+2, n+3), and the distance between the carbonyl oxygen and the amide hydrogen is indicated (dashed line and magnitude). Side chains are truncated to just show the beta carbon, and residues 1 and 4 have some main chain omitted for clarity. | ||
Revision as of 17:13, 11 February 2025
A beta turn is a secondary structure element consisting of four consecutive amino acids (or three consecutive peptide planes). The geometry of turns correspond to a change in the direction of the polypeptide backbone, with a short distance between the first and fourth alpha carbon.
Turns in 3D
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References
- ↑ de Brevern AG. A Perspective on the (Rise and Fall of) Protein β-Turns. Int J Mol Sci. 2022 Oct 14;23(20):12314. PMID:36293166 doi:10.3390/ijms232012314
