User:Michael Roberts/BIOL115 CaM
From Proteopedia
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<StructureSection load='1cll' size='600' side='right' caption='Structure of Human calmodulin (PDB entry [[1cll]])' scene=''> | <StructureSection load='1cll' size='600' side='right' caption='Structure of Human calmodulin (PDB entry [[1cll]])' scene=''> | ||
Let's start with a simple <scene name='User:Michael_Roberts/BIOL115_CaM/Wireframe/2'>wireframe representation </scene>of the protein. This shows all the bonds between the atoms that make up the protein. | Let's start with a simple <scene name='User:Michael_Roberts/BIOL115_CaM/Wireframe/2'>wireframe representation </scene>of the protein. This shows all the bonds between the atoms that make up the protein. | ||
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'''BACKBONE''': | '''BACKBONE''': | ||
The wireframe view shows us all the atoms, but this can be too much detail if we're mainly interested ion the overall structure of the protein. | The wireframe view shows us all the atoms, but this can be too much detail if we're mainly interested ion the overall structure of the protein. | ||
This next veiw takes us right doewn to a minimal representation that simply traces the <scene name='User:Michael_Roberts/BIOL115_CaM/Backbone/1'>"backbone" </scene>of the protein. The backbone includes the peptide linkages between each amino acid, along with the alpha-carbon atoms to which the side chains are attached. Notice that helical regions can now be seen. | This next veiw takes us right doewn to a minimal representation that simply traces the <scene name='User:Michael_Roberts/BIOL115_CaM/Backbone/1'>"backbone" </scene>of the protein. The backbone includes the peptide linkages between each amino acid, along with the alpha-carbon atoms to which the side chains are attached. Notice that helical regions can now be seen. | ||
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'''SECONDARY STRUCTURE''': This is shown more clearly by a <scene name='User:Michael_Roberts/BIOL115_CaM/Structure_plus_c/2'>ribbon diagram</scene>. The computer calculates where regions of secondary structure occur and draws them as ribbons. | '''SECONDARY STRUCTURE''': This is shown more clearly by a <scene name='User:Michael_Roberts/BIOL115_CaM/Structure_plus_c/2'>ribbon diagram</scene>. The computer calculates where regions of secondary structure occur and draws them as ribbons. | ||
The alpha-helical region is now clearly defined, and there are also regions of beta-structure. | The alpha-helical region is now clearly defined, and there are also regions of beta-structure. | ||
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Colour key: | Colour key: | ||
{{Template:ColorKey_Helix}}, | {{Template:ColorKey_Helix}}, | ||
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The short anti-parallel beta-sheet between the adjacent EF hand loops are observed in calmodulins from various species. | The short anti-parallel beta-sheet between the adjacent EF hand loops are observed in calmodulins from various species. | ||
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'''CALCIUM IONS''': | '''CALCIUM IONS''': | ||
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The structure shown has four <scene name='User:Michael_Roberts/BIOL115_CaM/Structure_plus_c/3'>Ca2+ ions</scene> bound. In this condition, the protein adopts the extended structure shown. The EF hand-forming helices are bent away from the long linking helix, revealing hydrophobic residues and exposing the linking chain. | The structure shown has four <scene name='User:Michael_Roberts/BIOL115_CaM/Structure_plus_c/3'>Ca2+ ions</scene> bound. In this condition, the protein adopts the extended structure shown. The EF hand-forming helices are bent away from the long linking helix, revealing hydrophobic residues and exposing the linking chain. | ||
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'''CO-ORDINATING RESIDUES''': | '''CO-ORDINATING RESIDUES''': | ||
To illustrate how Ca2+ is bound, this display shows the <scene name='User:Michael_Roberts/BIOL115_CaM/Co-ordination/1'>residues </scene>that take part in binding one of the Ca2+ ions. | To illustrate how Ca2+ is bound, this display shows the <scene name='User:Michael_Roberts/BIOL115_CaM/Co-ordination/1'>residues </scene>that take part in binding one of the Ca2+ ions. | ||
| - | <scene name='User:Michael_Roberts/BIOL115_CaM/Co-ordination/2'> | + | <scene name='User:Michael_Roberts/BIOL115_CaM/Co-ordination/2'>Zoom in</scene> to see this more clearly. |
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'''CO-ORDINATING ATOMS''': | '''CO-ORDINATING ATOMS''': | ||
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| + | '''INACTIVE CALMODULIN:''' | ||
| + | At resting levels of cytosolic Ca2+ (~100 nM), calmodulin exists predominantly in the calcium-free form. This is called apo-calmodulin and <scene name='User:Michael_Roberts/BIOL115_CaM/Inactive_calmodulin/1'>its structure </scene>is more compact. | ||
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| + | The terminal helices are folded down concealing their hydrophobic surfaces and the central chain, which is not a helical along its whole length, is not exposed. | ||
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| + | '''CALMODULIN INTERACTS WITH ITS TARGET:''' | ||
| + | The Ca2+-bound form of calmodulin with its exposed hydrophobic surfaces that you have already observed can <scene name='User:Michael_Roberts/BIOL115_CaM/Active_calmodulin/1'>interact with a target protein</scene>. It does this by wrapping around a specific sequence on the target molecule, forcing it to adopt an a-helical structure. | ||
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| + | The target molecule here is the calmodulin-regulated enzyme, myosin light chain kinase. Only a short sequence from this protein, the calmodulin binding domain, is shown. | ||
End of section | End of section | ||
</StructureSection> | </StructureSection> | ||
Revision as of 11:39, 12 April 2013
Sequence and structure of EF hands
The EF hand motif is present in a many proteins and it commonly bestows the ability to bind Ca2+ ions. It was first identified in parvalbumin, a muscle protein. Here we will have a look at the Ca2+-binding protein calmodulin, which possesses four EF hands. Calmodulin and its isoform, troponinC, are important intracellular Ca2+-binding proteins.
The structure below, obtained by X-ray crystallography, represents the Ca2+-binding protein calmodulin. It has a dumbell-shaped structure with two identical lobes connected by a central alpha-helix. Each lobe comprises three a helices joined by loops. A helix-loop-helix motif forms the basis of each EF hand.
Click on the 'green links' in the text in the scrollable section below to examine this molecule in more detail.
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