From DNA sequence recognition to directional chromosome segregation: Information transfer in the translocase protein SpoIIIE

From DNA sequence recognition to directional chromosome segregation: Information transfer in the translocase protein SpoIIIE

Faithful chromosome segregation is essential for all living organisms. Bacterial chromosome segregation utilizes highly conserved directional SpoIIIE/FtsK translocases to move large DNA molecules between spatially separated compartments. These translocases employ an accessory DNA-interacting domain...

Full description

Bibliographic Details
Main Author: Besprozvannaya, Marina
Other Authors: Burton, Briana
Language:en_US
Published: Harvard University 2014
Subjects:
Biochemistry
Molecular biology
Microbiology
ATPase molecular motors
Bacillus subtilis
chromosome segregation
directional DNA translocation
SpoIIIE/FtsK
sporulation
Online Access:http://dissertations.umi.com/gsas.harvard:11373
http://nrs.harvard.edu/urn-3:HUL.InstRepos:12274593
id ndltd-harvard.edu-oai-dash.harvard.edu-1-12274593
record_format oai_dc
spelling ndltd-harvard.edu-oai-dash.harvard.edu-1-122745932015-08-14T15:43:13ZFrom DNA sequence recognition to directional chromosome segregation: Information transfer in the translocase protein SpoIIIEBesprozvannaya, MarinaBiochemistryMolecular biologyMicrobiologyATPase molecular motorsBacillus subtilischromosome segregationdirectional DNA translocationSpoIIIE/FtsKsporulationFaithful chromosome segregation is essential for all living organisms. Bacterial chromosome segregation utilizes highly conserved directional SpoIIIE/FtsK translocases to move large DNA molecules between spatially separated compartments. These translocases employ an accessory DNA-interacting domain (gamma) that dictates the direction of DNA transport by recognizing specific DNA sequences. To date it remains unclear how these translocases use DNA sequence information as a trigger to expend chemical energy (ATP turnover) and thereby power mechanical work (DNA movement). In this thesis, I undertook a mechanistic study of directional DNA movement by SpoIIIE from the Gram-positive model bacterium Bacillus subtilis. Specifically, I was interested in understanding the information transfer within the protein from sequence recognition, to ATP turnover, and ultimately to chromosome translocation. How do DNA sequences trigger directional chromosome movement?Burton, Briana2014-06-06T21:29:55Z2014-06-062014Thesis or DissertationBesprozvannaya, Marina. 2014. From DNA sequence recognition to directional chromosome segregation: Information transfer in the translocase protein SpoIIIE. Doctoral dissertation, Harvard University.http://dissertations.umi.com/gsas.harvard:11373http://nrs.harvard.edu/urn-3:HUL.InstRepos:12274593en_USclosed accessHarvard University
collection NDLTD
language en_US
sources NDLTD
topic Biochemistry
Molecular biology
Microbiology
ATPase molecular motors
Bacillus subtilis
chromosome segregation
directional DNA translocation
SpoIIIE/FtsK
sporulation
spellingShingle Biochemistry
Molecular biology
Microbiology
ATPase molecular motors
Bacillus subtilis
chromosome segregation
directional DNA translocation
SpoIIIE/FtsK
sporulation
Besprozvannaya, Marina
From DNA sequence recognition to directional chromosome segregation: Information transfer in the translocase protein SpoIIIE
description Faithful chromosome segregation is essential for all living organisms. Bacterial chromosome segregation utilizes highly conserved directional SpoIIIE/FtsK translocases to move large DNA molecules between spatially separated compartments. These translocases employ an accessory DNA-interacting domain (gamma) that dictates the direction of DNA transport by recognizing specific DNA sequences. To date it remains unclear how these translocases use DNA sequence information as a trigger to expend chemical energy (ATP turnover) and thereby power mechanical work (DNA movement). In this thesis, I undertook a mechanistic study of directional DNA movement by SpoIIIE from the Gram-positive model bacterium Bacillus subtilis. Specifically, I was interested in understanding the information transfer within the protein from sequence recognition, to ATP turnover, and ultimately to chromosome translocation. How do DNA sequences trigger directional chromosome movement?
author2 Burton, Briana
author_facet Burton, Briana
Besprozvannaya, Marina
author Besprozvannaya, Marina
author_sort Besprozvannaya, Marina
title From DNA sequence recognition to directional chromosome segregation: Information transfer in the translocase protein SpoIIIE
title_short From DNA sequence recognition to directional chromosome segregation: Information transfer in the translocase protein SpoIIIE
title_full From DNA sequence recognition to directional chromosome segregation: Information transfer in the translocase protein SpoIIIE
title_fullStr From DNA sequence recognition to directional chromosome segregation: Information transfer in the translocase protein SpoIIIE
title_full_unstemmed From DNA sequence recognition to directional chromosome segregation: Information transfer in the translocase protein SpoIIIE
title_sort from dna sequence recognition to directional chromosome segregation: information transfer in the translocase protein spoiiie
publisher Harvard University
publishDate 2014
url http://dissertations.umi.com/gsas.harvard:11373
http://nrs.harvard.edu/urn-3:HUL.InstRepos:12274593
work_keys_str_mv AT besprozvannayamarina fromdnasequencerecognitiontodirectionalchromosomesegregationinformationtransferinthetranslocaseproteinspoiiie
_version_ 1716817038636220416

Similar Items