User:Amy Kerzmann/Sandbox 3

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('''Channel Function''')
('''Channel Function''')
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<applet load='1bl8' size='300' frame='true' align='left' caption='The structure of this channel revealed how potassium selectivity is attained.' />
<applet load='1bl8' size='300' frame='true' align='left' caption='The structure of this channel revealed how potassium selectivity is attained.' />
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The selectivity filter of the channel is formed from the strand that connects the second and third helices of each monomer, as briefly described above. In this case, the <scene name='User:Amy_Kerzmann/Sandbox_3/Carbonyls/1'>carbonyl groups</scene> of the backbone that span residues 74-79 make direct contact with potassium ions. These contacts are clearer when <scene name='User:Amy_Kerzmann/Sandbox_3/Carbonyls_-_two_chains/2'>only two protein chains</scene> are visualized. A conserved <scene name='User:Amy_Kerzmann/Sandbox_2/Tyrosine_symmetry/1'>tyrosine</scene> (Y78) forms the narrowest portion of the selectivity filter, with the <scene name='User:Amy_Kerzmann/Sandbox_3/Selectivity_filter/1'>carbonyl backbone</scene> pointed toward the core.
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The selectivity filter of the channel is formed from the strand that connects the second and third helices of each monomer, as briefly described above. In this case, the <scene name='User:Amy_Kerzmann/Sandbox_3/Carbonyls/1'>carbonyl groups</scene> of the backbone that span residues 74-79 make direct contact with potassium ions. These contacts are clearer when <scene name='User:Amy_Kerzmann/Sandbox_3/Carbonyls_-_two_chains/2'>only two protein chains</scene> are visualized. A conserved <scene name='User:Amy_Kerzmann/Sandbox_2/Tyrosine_symmetry/1'>tyrosine</scene> (Y78) forms the narrowest portion of the selectivity filter, with the <scene name='User:Amy_Kerzmann/Sandbox_3/Selectivity_filter/1'>carbonyl oxygen atoms</scene> pointed toward the core.
=='''Gating Mechanism'''==
=='''Gating Mechanism'''==

Revision as of 09:28, 28 September 2009

PDB ID 1bl8

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1bl8, resolution 3.20Å ()
Ligands:
Resources: FirstGlance, OCA, RCSB, PDBsum
Coordinates: save as pdb, mmCIF, xml



Contents

Background

Initial observations of the extraordinary selectivity of some ion-conducting channels for potassium baffled many scientists. How could such proteins permit the passage of potassium ions while restricting smaller sodium ions from being transferred across the membrane?

The crystal structure of the Streptomyces lividans potassium channel illuminated the principles of ion selectivity when it was solved in 1998 (PDB:1bl8).[1] To further demonstrate the importance of this structure, the 2003 Nobel Prize in Chemistry was awarded to Roderick MacKinnon for the work performed in his HHMI laboratory at Rockefeller University.


Channel Structure

This Streptomyces lividans protein was the first potassium channel to be crystallized.

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As described by Doyle, et al in their original paper, the potassium channel forms an "inverted teepee, or cone" with the widest portion facing the extracellular space.[1] Almost the entire structure is buried within the lipid bilayer, which is evident when the structure is colored according to the of each sidechain (hydrophobic residues are shown in grey and hydrophilic in purple.) The protein spans approximately 34 angstroms of the lipid bilayer [1], based on the distance between the highlighted in black.

The potassium channel is also a homotetramer, which means that it is comprised of identical protein chains or monomers, each shown in a different color. These monomeric units assemble to form a functional protein with around the longitudinal axis, which is best viewed from either membrane surface. As a result, each of the channel-lining residues appears as a ring of four identical sidechains. This principle is represented by the conserved amino acids that function as selectivity filters within the cavity. Additional , and sidechains line the channel. We will examine each of these conserved sites in greater detail under the "Channel Function" heading. It is also important to note that analysis of a of these residues reveals some hydrophobic patches within the cavity.

Each is predominantly and lacks beta strands. When viewed in (where the N-terminus is blue and the C-terminus is red), one can see that both termini are located on the cytosolic side of the membrane. Note that the two C-terminal helices form the central core of the channel and that the region between them lines the cavity, making contacts with the migrating potassium ions.

Channel Function

The structure of this channel revealed how potassium selectivity is attained.

Drag the structure with the mouse to rotate

The selectivity filter of the channel is formed from the strand that connects the second and third helices of each monomer, as briefly described above. In this case, the of the backbone that span residues 74-79 make direct contact with potassium ions. These contacts are clearer when are visualized. A conserved (Y78) forms the narrowest portion of the selectivity filter, with the pointed toward the core.

Gating Mechanism

Details of the voltage-gated mechanism go here.


Selectivity Filter

Comparison of the hydrated states of potassium and sodium.




References

  1. 1.0 1.1 1.2 Doyle DA, Morais Cabral J, Pfuetzner RA, Kuo A, Gulbis JM, Cohen SL, Chait BT, MacKinnon R. The structure of the potassium channel: molecular basis of K+ conduction and selectivity. Science. 1998 Apr 3;280(5360):69-77. PMID:9525859

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Amy Kerzmann

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