dc.contributor.advisor | Ettrich, Rüdiger Horst | |
dc.contributor.author | Bialevich, Vitali | |
dc.date.accessioned | 2021-12-08T12:54:58Z | |
dc.date.available | 2021-12-08T12:54:58Z | |
dc.date.issued | 2017 | |
dc.date.submitted | 2016-12-09 | |
dc.identifier.uri | https://dspace.jcu.cz/handle/123456789/33839 | |
dc.description.abstract | Bacterial 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.format | 111 | |
dc.format | 111 | |
dc.language.iso | eng | |
dc.publisher | Jihočeská univerzita | cze |
dc.rights | Bez omezení | |
dc.subject | DNA restriction enzymes | cze |
dc.subject | E. coli | cze |
dc.subject | Multisubunit enzyme complex | cze |
dc.subject | EcoR124I | cze |
dc.subject | HsdR | cze |
dc.subject | Type I R-M systems | cze |
dc.subject | DNA restriction enzymes | eng |
dc.subject | E. coli | eng |
dc.subject | Multisubunit enzyme complex | eng |
dc.subject | EcoR124I | eng |
dc.subject | HsdR | eng |
dc.subject | Type I R-M systems | eng |
dc.title | Domain conformations of the motor subunit of EcoR124I involved in ATPase activity and dsDNA translocation | cze |
dc.title.alternative | Domain conformations of the motor subunit of EcoR124I involved in ATPase activity and dsDNA translocation | eng |
dc.type | disertační práce | cze |
dc.identifier.stag | 27954 | |
dc.description.abstract-translated | Bacterial 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.accepted | 2017-02-20 | |
dc.description.department | Přírodovědecká fakulta | cze |
dc.thesis.degree-discipline | Biofyzika | cze |
dc.thesis.degree-grantor | Jihočeská univerzita. Přírodovědecká fakulta | cze |
dc.thesis.degree-name | Ph.D. | |
dc.thesis.degree-program | Biofyzika | cze |
dc.description.grade | Dokončená práce s úspěšnou obhajobou | cze |
dc.contributor.referee | Martínek, Václav | |
dc.contributor.referee | Němčovicová, Ivana | |
dc.contributor.referee | Schindl, Rainer | |