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dc.contributor.advisorEttrich, Rüdiger Horst
dc.contributor.authorBialevich, Vitali
dc.date.accessioned2021-12-08T12:54:58Z
dc.date.available2021-12-08T12:54:58Z
dc.date.issued2017
dc.date.submitted2016-12-09
dc.identifier.urihttps://dspace.jcu.cz/handle/123456789/33839
dc.description.abstractBacterial type I restriction-modification systems are composed of three different subunits: one HsdS subunit is required for identification of target sequence and anchoring the enzyme complex on DNA; two HsdM subunits in the methyl-transferase complex serve for host genome modification accomplishing a protective function against self-degradation; two HsdR (or motor) subunits house ATP-dependent translocation and consequent cleavage of double stranded DNA activities. The crystal structure of the 120 kDa HsdR subunit of the Type I restriction-modification system EcoR124I in complex with ATP was recently reported. HsdR is organized into four approximately globular structural domains in a nearly square-planar arrangement: the N-terminal endonuclease domain, the RecA-like helicase domains 1 and 2 and the C-terminal helical domain. The near-planar arrangement of globular domains creates prominent grooves between each domain pair. The two helicase-like domains form a canonical helicase cleft in which double-stranded B-form DNA can be accommodated without steric clash. The helical domain, probably involved in complex assembly, exhibits only a few specific interactions with helicase 2 domain. Molecular mechanism of dsDNA translocation, cleavage and ATP hydrolysis has not been yet structurally investigated. Here we propose a translocation cycle of the restriction-modification system EcoR124I based on analysis of available crystal structures of superfamily 2 helicases, strutural modeling and complementary biochemical characterization of mutations introduced in sites potentially inportant for translocation in the HsdR motor subunit. Also a role of the extended region of the helicase motif III in ATPase activity of EcoR124I was probed.cze
dc.format111
dc.format111
dc.language.isoeng
dc.publisherJihočeská univerzitacze
dc.rightsBez omezení
dc.subjectDNA restriction enzymescze
dc.subjectE. colicze
dc.subjectMultisubunit enzyme complexcze
dc.subjectEcoR124Icze
dc.subjectHsdRcze
dc.subjectType I R-M systemscze
dc.subjectDNA restriction enzymeseng
dc.subjectE. colieng
dc.subjectMultisubunit enzyme complexeng
dc.subjectEcoR124Ieng
dc.subjectHsdReng
dc.subjectType I R-M systemseng
dc.titleDomain conformations of the motor subunit of EcoR124I involved in ATPase activity and dsDNA translocationcze
dc.title.alternativeDomain conformations of the motor subunit of EcoR124I involved in ATPase activity and dsDNA translocationeng
dc.typedisertační prácecze
dc.identifier.stag27954
dc.description.abstract-translatedBacterial type I restriction-modification systems are composed of three different subunits: one HsdS subunit is required for identification of target sequence and anchoring the enzyme complex on DNA; two HsdM subunits in the methyl-transferase complex serve for host genome modification accomplishing a protective function against self-degradation; two HsdR (or motor) subunits house ATP-dependent translocation and consequent cleavage of double stranded DNA activities. The crystal structure of the 120 kDa HsdR subunit of the Type I restriction-modification system EcoR124I in complex with ATP was recently reported. HsdR is organized into four approximately globular structural domains in a nearly square-planar arrangement: the N-terminal endonuclease domain, the RecA-like helicase domains 1 and 2 and the C-terminal helical domain. The near-planar arrangement of globular domains creates prominent grooves between each domain pair. The two helicase-like domains form a canonical helicase cleft in which double-stranded B-form DNA can be accommodated without steric clash. The helical domain, probably involved in complex assembly, exhibits only a few specific interactions with helicase 2 domain. Molecular mechanism of dsDNA translocation, cleavage and ATP hydrolysis has not been yet structurally investigated. Here we propose a translocation cycle of the restriction-modification system EcoR124I based on analysis of available crystal structures of superfamily 2 helicases, strutural modeling and complementary biochemical characterization of mutations introduced in sites potentially inportant for translocation in the HsdR motor subunit. Also a role of the extended region of the helicase motif III in ATPase activity of EcoR124I was probed.eng
dc.date.accepted2017-02-20
dc.description.departmentPřírodovědecká fakultacze
dc.thesis.degree-disciplineBiofyzikacze
dc.thesis.degree-grantorJihočeská univerzita. Přírodovědecká fakultacze
dc.thesis.degree-namePh.D.
dc.thesis.degree-programBiofyzikacze
dc.description.gradeDokončená práce s úspěšnou obhajoboucze
dc.contributor.refereeMartínek, Václav
dc.contributor.refereeNěmčovicová, Ivana
dc.contributor.refereeSchindl, Rainer


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