User:Lori Wetmore/Sandbox 4

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{{STRUCTURE_2hyd | PDB=2hyd | SCENE=User:Lori_Wetmore/Sandbox_4/Sav1866/3}}
{{STRUCTURE_2hyd | PDB=2hyd | SCENE=User:Lori_Wetmore/Sandbox_4/Sav1866/3}}
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<scene name='User:Lori_Wetmore/Sandbox_4/Sav1866/3'>TextToBeDisplayed</scene>
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=='''Background Information'''==
=='''Background Information'''==
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The ATP binding cassette is the most conserved part of an ABC transporter. All ABCs consist of two domains: a RecA-like domain, containing both the Walker A and Walker B motifs, and a helical domain, that contains a unique LSGGQ motif. The two domains are joined by flexible loops, one of which, the Q loop, mediates the interaction between the ABC and the TMD.<ref name="Locher">PMID:18957379</ref>
The ATP binding cassette is the most conserved part of an ABC transporter. All ABCs consist of two domains: a RecA-like domain, containing both the Walker A and Walker B motifs, and a helical domain, that contains a unique LSGGQ motif. The two domains are joined by flexible loops, one of which, the Q loop, mediates the interaction between the ABC and the TMD.<ref name="Locher">PMID:18957379</ref>
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ABC transporters function only when assembled into homodimers. The <scene name='User:Lori_Wetmore/Sandbox_4/Sav1866/8'>two ATP binding sites</scene> of an assembled transporter are at the interfaces of two ABC subunits, where the ATP interacts with the Walker A motif (yellow) on one subunit and the LSGGQ motif (pink) on the other.
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ABC transporters function as homodimers. The <scene name='User:Lori_Wetmore/Sandbox_4/Sav1866/8'>two ATP binding sites</scene> of an assembled transporter are at the interfaces of two ABC subunits, where the ATP interacts with the Walker A motif (yellow) on one subunit and the LSGGQ motif (pink) on the other.
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Binding of ATP closes the interface between the NBDs, which in turn draws the cytosolic portion of the TMDs together, exposing the substrate-binding site to the extracellular space. Hydrolysis and release of ATP causes the separation of the NBDs, pushing the cytosolic ends of the transmembrane domains apart. As the cytosolic ends of the NBDs are drawn apart, their extracellular ends come together, making the substrate-binding site inaccessible on the extracellular face of the membrane and accessible to the intracellular face of the membrane. This cycle of ATP binding and hydrolysis fuels both ABC importers and ABC exporters.
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<scene name='User:Lori_Wetmore/Sandbox_4/Sav1866/3'>Reset Figure</scene>

Revision as of 18:21, 27 September 2010

PDB ID 2hyd

Drag the structure with the mouse to rotate
2hyd, resolution 3.00Å ()
Ligands: ,
Gene: SAV1866 (Staphylococcus aureus)
Resources: FirstGlance, OCA, PDBsum, RCSB
Coordinates: save as pdb, mmCIF, xml




Contents

Background Information

ATP-binding cassette (ABC) transporters are a superfamily of integral membrane proteins that harness the energy of ATP binding and hydrolysis to drive the trans-membrane movement of a variety of small molecules. ABC transporters function as homodimers, in which ATP binding and hydrolysis occurs in two sites that the interface of the nucleotide binding domains (NBD), while the paired transmembrane domains (TMD) facilitate substrate transport. Substrates may be imported or exported, depending upon the structure of the transporter. In ABC importers, which have only been found in prokaryotes, the NBD and TMD are separate polypeptides; however, in the ubiquitous exporters, the NBD and TMD are fused.

ABC transporters are of particular medical interest, as they may contribute to the pathogenicity and drug resistance of pathogenic bacteria and some cancers.[1]




General ABC Structure

Sav1866 from Staphylococcus aureus was the first ABC exporter to have its structure determined to high resolution.

Drag the structure with the mouse to rotate

The ATP binding cassette is the most conserved part of an ABC transporter. All ABCs consist of two domains: a RecA-like domain, containing both the Walker A and Walker B motifs, and a helical domain, that contains a unique LSGGQ motif. The two domains are joined by flexible loops, one of which, the Q loop, mediates the interaction between the ABC and the TMD.[2]

ABC transporters function as homodimers. The of an assembled transporter are at the interfaces of two ABC subunits, where the ATP interacts with the Walker A motif (yellow) on one subunit and the LSGGQ motif (pink) on the other.

Binding of ATP closes the interface between the NBDs, which in turn draws the cytosolic portion of the TMDs together, exposing the substrate-binding site to the extracellular space. Hydrolysis and release of ATP causes the separation of the NBDs, pushing the cytosolic ends of the transmembrane domains apart. As the cytosolic ends of the NBDs are drawn apart, their extracellular ends come together, making the substrate-binding site inaccessible on the extracellular face of the membrane and accessible to the intracellular face of the membrane. This cycle of ATP binding and hydrolysis fuels both ABC importers and ABC exporters.


ABC Exporters






Type I ABC Importers

Template:STRUCTURE 3d31










Type II ABC Importers

Template:STRUCTURE 1l7v



References

  1. Davidson AL, Dassa E, Orelle C, Chen J. Structure, function, and evolution of bacterial ATP-binding cassette systems. Microbiol Mol Biol Rev. 2008 Jun;72(2):317-64, table of contents. PMID:18535149 doi:10.1128/MMBR.00031-07
  2. Locher KP. Review. Structure and mechanism of ATP-binding cassette transporters. Philos Trans R Soc Lond B Biol Sci. 2009 Jan 27;364(1514):239-45. PMID:18957379 doi:10.1098/rstb.2008.0125

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Lori Wetmore

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