Molecular Mechanism of E. coli ATP synthase: Structural Analysis of the Proton Channel

Adenosine triphosphate (ATP) is the energy currency of all living cells and its production is a key reaction in the energy metabolism of living organisms. Cells produce most of the ATP they require through ATP synthase, a unique molecular rotary motor driven by the movement of protons across the lip...

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Other Authors: Dmitriev, Oleg Y.
Language:English
Published: 2013
Subjects:
NMR
Online Access:http://hdl.handle.net/10388/ETD-2013-04-996
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spelling ndltd-USASK-oai-ecommons.usask.ca-10388-ETD-2013-04-9962013-04-27T04:10:49ZMolecular Mechanism of E. coli ATP synthase: Structural Analysis of the Proton ChannelATP synthasesubunit amembrane proteinstructure studiesNMRX-ray crystallographyproton channelAdenosine triphosphate (ATP) is the energy currency of all living cells and its production is a key reaction in the energy metabolism of living organisms. Cells produce most of the ATP they require through ATP synthase, a unique molecular rotary motor driven by the movement of protons across the lipid membrane. In E.coli, ATP synthase is composed of a soluble domain called F1, which houses the catalytic sites, and a transmembrane domain called F0 that shuttles protons across the membrane to drive ATP production in the F1 sector. The F0 domain is built of three subunit types: subunit a and a dimer of subunit b form the stator of the motor, while a decameric c ring forms the rotor. The dynamic interface between a and c10 forms the proton channel. The ultimate goal of this work is to determine the structure of the proton transport machinery and understand the molecular mechanism of proton translocation in ATP synthase. We have characterized some of the key events in the stepwise assembly of the F0--complex. We have designed and validated a model protein, consisting of genetically fused subunits a and c, for structural studies. We have made progress towards determining the structure of the proton channel, including the development of a novel procedure for purification of subunit a and the a/c fusion protein, and crystallization of subunit a. Medical applications of this work include the potential development of novel antibiotic compounds, as well as the characterization and potential treatment of three human diseases caused by disruptions in proton transport through F0.Dmitriev, Oleg Y.2013-04-26T12:00:40Z2013-04-26T12:00:40Z2013-042013-04-25April 2013textthesishttp://hdl.handle.net/10388/ETD-2013-04-996eng
collection NDLTD
language English
sources NDLTD
topic ATP synthase
subunit a
membrane protein
structure studies
NMR
X-ray crystallography
proton channel
spellingShingle ATP synthase
subunit a
membrane protein
structure studies
NMR
X-ray crystallography
proton channel
Molecular Mechanism of E. coli ATP synthase: Structural Analysis of the Proton Channel
description Adenosine triphosphate (ATP) is the energy currency of all living cells and its production is a key reaction in the energy metabolism of living organisms. Cells produce most of the ATP they require through ATP synthase, a unique molecular rotary motor driven by the movement of protons across the lipid membrane. In E.coli, ATP synthase is composed of a soluble domain called F1, which houses the catalytic sites, and a transmembrane domain called F0 that shuttles protons across the membrane to drive ATP production in the F1 sector. The F0 domain is built of three subunit types: subunit a and a dimer of subunit b form the stator of the motor, while a decameric c ring forms the rotor. The dynamic interface between a and c10 forms the proton channel. The ultimate goal of this work is to determine the structure of the proton transport machinery and understand the molecular mechanism of proton translocation in ATP synthase. We have characterized some of the key events in the stepwise assembly of the F0--complex. We have designed and validated a model protein, consisting of genetically fused subunits a and c, for structural studies. We have made progress towards determining the structure of the proton channel, including the development of a novel procedure for purification of subunit a and the a/c fusion protein, and crystallization of subunit a. Medical applications of this work include the potential development of novel antibiotic compounds, as well as the characterization and potential treatment of three human diseases caused by disruptions in proton transport through F0.
author2 Dmitriev, Oleg Y.
author_facet Dmitriev, Oleg Y.
title Molecular Mechanism of E. coli ATP synthase: Structural Analysis of the Proton Channel
title_short Molecular Mechanism of E. coli ATP synthase: Structural Analysis of the Proton Channel
title_full Molecular Mechanism of E. coli ATP synthase: Structural Analysis of the Proton Channel
title_fullStr Molecular Mechanism of E. coli ATP synthase: Structural Analysis of the Proton Channel
title_full_unstemmed Molecular Mechanism of E. coli ATP synthase: Structural Analysis of the Proton Channel
title_sort molecular mechanism of e. coli atp synthase: structural analysis of the proton channel
publishDate 2013
url http://hdl.handle.net/10388/ETD-2013-04-996
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