Structural basis for regulation of bifunctional roles in replication initiator protein

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Zeitschriftentitel:	Proceedings of the National Academy of Sciences
Personen und Körperschaften:	Nakamura, Akira, Wada, Chieko, Miki, Kunio
In:	Proceedings of the National Academy of Sciences, 104, 2007, 47, S. 18484-18489
Format:	E-Article
Sprache:	Englisch
veröffentlicht:	Proceedings of the National Academy of Sciences
Schlagwörter:	Multidisciplinary

author_facet	Nakamura, Akira Wada, Chieko Miki, Kunio Nakamura, Akira Wada, Chieko Miki, Kunio
author	Nakamura, Akira Wada, Chieko Miki, Kunio
spellingShingle	Nakamura, Akira Wada, Chieko Miki, Kunio Proceedings of the National Academy of Sciences Structural basis for regulation of bifunctional roles in replication initiator protein Multidisciplinary
author_sort	nakamura, akira
spelling	Nakamura, Akira Wada, Chieko Miki, Kunio 0027-8424 1091-6490 Proceedings of the National Academy of Sciences Multidisciplinary http://dx.doi.org/10.1073/pnas.0705623104 <jats:p> DNA replication initiator protein RepE stringently regulates F plasmid replication by its two distinct molecular association states. A predominant dimer functions as an autogenous repressor, whereas monomers act as replication initiators, and the dimer requires actions of the DnaK molecular chaperone system for monomerization. The structure of the monomeric form is known, whereas the dimeric structure and structural details of the dimer-to-monomer conversion have been unclear. Here we present the crystal structure of the RepE dimer in complex with the <jats:italic>repE</jats:italic> operator DNA. The dimerization interface is mainly formed by intermolecular β-sheets with several key interactions of charged residues. The conformations of the internal N- and C-terminal domains are conserved between the dimer and monomer, whereas the relative domain orientations are strikingly different, allowing for an efficient oligomeric transition of dual-functional RepE. This domain relocation accompanies secondary structural changes in the linker connecting the two domains, and the linker is included in plausible DnaK/DnaJ-binding regions. These findings suggest an activation mechanism for F plasmid replication by RepE monomerization, which is induced and mediated by the DnaK system. </jats:p> Structural basis for regulation of bifunctional roles in replication initiator protein Proceedings of the National Academy of Sciences
doi_str_mv	10.1073/pnas.0705623104
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imprint	Proceedings of the National Academy of Sciences, 2007
imprint_str_mv	Proceedings of the National Academy of Sciences, 2007
issn	0027-8424 1091-6490
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language	English
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title	Structural basis for regulation of bifunctional roles in replication initiator protein
title_unstemmed	Structural basis for regulation of bifunctional roles in replication initiator protein
title_full	Structural basis for regulation of bifunctional roles in replication initiator protein
title_fullStr	Structural basis for regulation of bifunctional roles in replication initiator protein
title_full_unstemmed	Structural basis for regulation of bifunctional roles in replication initiator protein
title_short	Structural basis for regulation of bifunctional roles in replication initiator protein
title_sort	structural basis for regulation of bifunctional roles in replication initiator protein
topic	Multidisciplinary
url	http://dx.doi.org/10.1073/pnas.0705623104
publishDate	2007
physical	18484-18489
description	<jats:p> DNA replication initiator protein RepE stringently regulates F plasmid replication by its two distinct molecular association states. A predominant dimer functions as an autogenous repressor, whereas monomers act as replication initiators, and the dimer requires actions of the DnaK molecular chaperone system for monomerization. The structure of the monomeric form is known, whereas the dimeric structure and structural details of the dimer-to-monomer conversion have been unclear. Here we present the crystal structure of the RepE dimer in complex with the <jats:italic>repE</jats:italic> operator DNA. The dimerization interface is mainly formed by intermolecular β-sheets with several key interactions of charged residues. The conformations of the internal N- and C-terminal domains are conserved between the dimer and monomer, whereas the relative domain orientations are strikingly different, allowing for an efficient oligomeric transition of dual-functional RepE. This domain relocation accompanies secondary structural changes in the linker connecting the two domains, and the linker is included in plausible DnaK/DnaJ-binding regions. These findings suggest an activation mechanism for F plasmid replication by RepE monomerization, which is induced and mediated by the DnaK system. </jats:p>
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author	Nakamura, Akira, Wada, Chieko, Miki, Kunio
author_facet	Nakamura, Akira, Wada, Chieko, Miki, Kunio, Nakamura, Akira, Wada, Chieko, Miki, Kunio
author_sort	nakamura, akira
container_issue	47
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container_title	Proceedings of the National Academy of Sciences
container_volume	104
description	<jats:p> DNA replication initiator protein RepE stringently regulates F plasmid replication by its two distinct molecular association states. A predominant dimer functions as an autogenous repressor, whereas monomers act as replication initiators, and the dimer requires actions of the DnaK molecular chaperone system for monomerization. The structure of the monomeric form is known, whereas the dimeric structure and structural details of the dimer-to-monomer conversion have been unclear. Here we present the crystal structure of the RepE dimer in complex with the <jats:italic>repE</jats:italic> operator DNA. The dimerization interface is mainly formed by intermolecular β-sheets with several key interactions of charged residues. The conformations of the internal N- and C-terminal domains are conserved between the dimer and monomer, whereas the relative domain orientations are strikingly different, allowing for an efficient oligomeric transition of dual-functional RepE. This domain relocation accompanies secondary structural changes in the linker connecting the two domains, and the linker is included in plausible DnaK/DnaJ-binding regions. These findings suggest an activation mechanism for F plasmid replication by RepE monomerization, which is induced and mediated by the DnaK system. </jats:p>
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imprint	Proceedings of the National Academy of Sciences, 2007
imprint_str_mv	Proceedings of the National Academy of Sciences, 2007
institution	DE-Gla1, DE-Zi4, DE-15, DE-Pl11, DE-Rs1, DE-105, DE-14, DE-Ch1, DE-L229, DE-D275, DE-Bn3, DE-Brt1, DE-Zwi2, DE-D161
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physical	18484-18489
publishDate	2007
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spelling	Nakamura, Akira Wada, Chieko Miki, Kunio 0027-8424 1091-6490 Proceedings of the National Academy of Sciences Multidisciplinary http://dx.doi.org/10.1073/pnas.0705623104 <jats:p> DNA replication initiator protein RepE stringently regulates F plasmid replication by its two distinct molecular association states. A predominant dimer functions as an autogenous repressor, whereas monomers act as replication initiators, and the dimer requires actions of the DnaK molecular chaperone system for monomerization. The structure of the monomeric form is known, whereas the dimeric structure and structural details of the dimer-to-monomer conversion have been unclear. Here we present the crystal structure of the RepE dimer in complex with the <jats:italic>repE</jats:italic> operator DNA. The dimerization interface is mainly formed by intermolecular β-sheets with several key interactions of charged residues. The conformations of the internal N- and C-terminal domains are conserved between the dimer and monomer, whereas the relative domain orientations are strikingly different, allowing for an efficient oligomeric transition of dual-functional RepE. This domain relocation accompanies secondary structural changes in the linker connecting the two domains, and the linker is included in plausible DnaK/DnaJ-binding regions. These findings suggest an activation mechanism for F plasmid replication by RepE monomerization, which is induced and mediated by the DnaK system. </jats:p> Structural basis for regulation of bifunctional roles in replication initiator protein Proceedings of the National Academy of Sciences
spellingShingle	Nakamura, Akira, Wada, Chieko, Miki, Kunio, Proceedings of the National Academy of Sciences, Structural basis for regulation of bifunctional roles in replication initiator protein, Multidisciplinary
title	Structural basis for regulation of bifunctional roles in replication initiator protein
title_full	Structural basis for regulation of bifunctional roles in replication initiator protein
title_fullStr	Structural basis for regulation of bifunctional roles in replication initiator protein
title_full_unstemmed	Structural basis for regulation of bifunctional roles in replication initiator protein
title_short	Structural basis for regulation of bifunctional roles in replication initiator protein
title_sort	structural basis for regulation of bifunctional roles in replication initiator protein
title_unstemmed	Structural basis for regulation of bifunctional roles in replication initiator protein
topic	Multidisciplinary
url	http://dx.doi.org/10.1073/pnas.0705623104