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1 ing the ATP hydrolysis to work (in this case DNA strand exchange).
2 context of a kinetic model for RecA-mediated DNA strand exchange.
3 e complementation is not sufficient to allow DNA strand exchange.
4 in eukaryotes performing homology search and DNA strand exchange.
5 r homologous double-stranded DNA (dsDNA) and DNA strand exchange.
6 ion results in stimulation of RAD51-promoted DNA strand exchange.
7 stigated the hRad54-dependent stimulation of DNA strand exchange.
8 llow the movement of protein subunits during DNA strand exchange.
9 tein C terminus that activates RecA-mediated DNA strand exchange.
10 forming presynaptic filaments that initiate DNA strand exchange.
11 including ssDNA-dependent ATP hydrolysis and DNA strand exchange.
12 binding (SSB) protein, thereby accelerating DNA strand exchange.
13 the hydrolysis of dATP is poorly coupled to DNA strand exchange.
14 52 protein stimulates Rad51 protein-promoted DNA strand exchange.
15 stuck on the heteroduplex DNA product after DNA strand exchange.
16 tions, Rad52 protein is needed for extensive DNA strand exchange.
17 lished joint molecules in Rad51/Rpa-mediated DNA strand exchange.
18 nds on ATP to promote homologous pairing and DNA strand exchange.
19 hanistic coupling between NTP hydrolysis and DNA strand exchange.
20 ssDNA, and stimulates Rad51 protein-mediated DNA strand exchange.
21 romotes ATP-dependent homologous pairing and DNA strand exchange.
22 lf to explain how ATP hydrolysis facilitates DNA strand exchange.
23 and the gene 4 helicase, mediate homologous DNA strand exchange.
24 The protein nevertheless promotes DNA strand exchange.
25 he secondary binding site has a dual role in DNA strand exchange.
26 A S119A repressor blocks a site required for DNA strand exchange.
27 sDNA to the secondary site strongly inhibits DNA strand exchange.
28 DNA, and contribute to the directionality of DNA strand exchange.
29 y, the ssDNA strand that is displaced during DNA strand exchange.
30 ding specificity in a manner that stimulates DNA strand exchange.
31 synapsis occurs during RecA protein-mediated DNA strand exchange.
32 ilament stability and impairs RAD51-mediated DNA strand exchange.
33 HOP2-MND1 as a 'molecular trigger' of RAD51 DNA strand exchange.
34 Dmc1-Tid1 tilt the bias toward interhomolog DNA strand exchange.
35 the search for homologous DNA sequences and DNA strand exchange.
36 centration dependence parallels that seen in DNA strand exchange.
37 ricus Rad51 homologue, SsoRadA, to stimulate DNA strand exchange.
38 ded DNA (ssDNA), but not dsDNA, to stimulate DNA strand exchange.
39 the current models linking ATP hydrolysis to DNA strand exchange.
40 olysis is completely uncoupled from extended DNA strand exchange.
41 ional separation of DNA pairing and extended DNA strand exchange.
42 ys a major role in, and may be required for, DNA strand exchange.
43 s DNAs are paired and available for extended DNA strand exchange.
44 a tight coupling between ATP hydrolysis and DNA strand exchange.
45 that binds RAD51, the enzyme responsible for DNA strand exchange.
46 on of UvsX-ssDNA filaments that is active in DNA strand exchange.
47 sDNA overhang that serves as a substrate for DNA strand exchange.
48 ed RecA from DNA and inhibited RecA-mediated DNA strand exchange.
49 element in promoting homologous pairing and DNA strand exchange.
50 ate Rad51 from dsDNA, the product complex of DNA strand exchange.
51 oviding new insights into how RecA catalyses DNA strand-exchange.
52 naptic complex and orchestrates the order of DNA strand exchanges.
53 with each recombinase mediating one pair of DNA strand exchanges.
54 helical nucleoprotein filament that promotes DNA strand exchange, a basic step of homologous recombin
57 The Rad51 nucleoprotein filament mediates DNA strand exchange, a key step of homologous recombinat
61 A (RPA) on presynaptic complex formation and DNA strand exchange activities of Rad51 protein were exa
63 ons of Srs2, providing a means for tailoring DNA strand exchange activities to enhance the fidelity o
68 acidic conditions restore both the in vitro DNA strand exchange activity and the in vivo function of
69 ve for genetic recombination in vivo and for DNA strand exchange activity in vitro under conventional
76 emonstrated that Ca2+ greatly stimulates the DNA strand exchange activity of human (h) Rad51 protein.
82 Rad51C displays an ATP-independent apparent DNA strand exchange activity, whereas Rad51B shows no su
83 ant protein has a corresponding reduction in DNA strand exchange activity, which probably results in
84 her Lys6 or Arg28 show partial inhibition of DNA strand exchange activity, yet the mechanistic reason
85 ngly with reduced ssDNA-binding affinity and DNA strand-exchange activity in both H195Q and H195A mut
86 filament has long been known to occur during DNA strand exchange, although its importance to this pro
87 NA/hRAD51 and including salts that stimulate DNA strand exchange (ammonium sulfate and spermidine) we
88 nucleoprotein filament is more competent in DNA strand exchange and acts over a broader range of sol
90 e Rad51-G103E mutant protein is deficient in DNA strand exchange and ATPase activity due to a primary
91 nteractions between hRad54 and hRad51 during DNA strand exchange and branch migration, which are two
93 In vitro, RAD54 stimulates RAD51-mediated DNA strand exchange and promotes branch migration of Hol
96 genome maintenance pathways, including RecA DNA strand exchange and RecA-independent suppression of
97 verexpression of Rad51, a protein central to DNA strand exchange and recombination, did not further i
99 d in vivo, stimulating RecA protein-mediated DNA strand-exchange and rescuing the ssb-1 lethal mutati
100 om the work are 13.3 +/- 1.1 kcal mole-1 for DNA strand exchange, and 14.4 +/- 1.4 kcal mole-1 for AT
101 eoprotein filament makes dsDNA receptive for DNA strand exchange, and it defines an early step of the
102 -ssDNA nucleoprotein filaments that catalyze DNA strand exchange, and it mediates single-strand DNA a
104 1 protein (hDmc1) for the ability to promote DNA strand exchange, and show that hDmc1 mediates strand
105 TP, in concert with SsbA and DprA, catalyzes DNA strand exchange, and SsbB is an accessory factor in
107 can be recognized by PcG complexes, and RNA-DNA strand exchange as a PRC2 activity that could contri
110 s affect the pK(a) of key groups involved in DNA strand exchange as well as the direct binding of Rec
111 51 protein requires ATP for the catalysis of DNA strand exchange, as do all Rad51 and RecA-like recom
112 ies preference in the Rad51 dissociation and DNA strand exchange assays underlines the importance of
114 acid residues result in strong inhibition of DNA strand exchange below pH 7, where the wild-type prot
116 protein of HR, possesses a unique activity: DNA strand exchange between homologous DNA sequences.
117 Although providing an efficient rate of DNA strand exchange between polymorphic alleles, Dmc1 mu
118 ength BRCA2 protein stimulates DMC1-mediated DNA strand exchange between RPA-ssDNA complexes and dupl
120 ain DNA mismatches, and it also acts against DNA strand exchange between substrates solely harboring
122 red for DNA repair, including RAD51 mediated DNA strand exchange, but is dispensable for DNA replicat
123 ATP and ssDNA active in homology search and DNA strand exchange, but the precise role of its ATPase
126 studies established that Brh2 can stimulate DNA strand exchange by enabling Rad51 nucleoprotein fila
127 ing of the ssDNA strand that is displaced by DNA strand exchange by Rad51 and RPA, to a second ssDNA
128 ion of Rad54 protein overcomes inhibition of DNA strand exchange by Rad51 protein bound to substrate
131 excess of ssDNA and prevents the reversal of DNA strand exchange by removing the displaced strand fro
132 additional role in the postsynaptic phase of DNA strand exchange by stimulating heteroduplex DNA exte
134 breaks by homologous recombination, promotes DNA strand-exchange by an unprecedented inverse pathway,
137 ede activities of RecA that are important to DNA strand exchange, consistent with its role in targeti
140 yotic recombinase responsible for initiating DNA strand exchange during homologous recombination.
143 tead, RadD greatly accelerates RecA-mediated DNA strand exchange, functioning only when RecA protein
144 requirement for RecA filament disassembly in DNA strand exchange has a variety of ramifications for t
145 teins align homologous sequences and promote DNA strand exchange has long been known, as are the crys
148 The Escherichia coli RecA protein promotes DNA strand exchange in homologous recombination and reco
151 2+ effects, the limitations of RecA-mediated DNA strand exchange in the absence of ATP hydrolysis, an
154 substrates for the RecA protein, permitting DNA strand exchange in vitro at a rate and efficiency co
155 us recombination in vivo, is able to perform DNA strand exchange in vitro with ATP, but is unable to
159 Optimal conditions for RecA protein-mediated DNA strand exchange include 6-8 mm Mg(2+) in excess of t
163 Here, we demonstrate that the polarity of DNA strand exchange is embedded within RecA filaments ev
164 d significant ATP is hydrolyzed, even though DNA strand exchange is entirely blocked by the mutant pr
167 nd, as a consequence, Rad51 protein-mediated DNA strand exchange is inhibited when the ssDNA is in a
168 the four-stranded intermediate arising from DNA strand exchange is migrated and resolved and how anc
171 sing every 20 min, the pace of RecA-mediated DNA strand exchange is potentially much too slow for bac
172 he secondary site for ssDNA is essential for DNA strand exchange, it renders DNA strand exchange sens
173 aptically to inhibit RecA during an on-going DNA strand exchange, likely through the disassembly of R
174 ate common and idiosyncratic features in the DNA strand exchange mechanisms of three RecA-family reco
175 filaments possess an intrinsic capacity for DNA strand exchange, mediated by binding energy rather t
176 s DNA molecules and promote highly efficient DNA strand exchange of the paired molecules over at leas
179 nzyme, an accessory protein that accelerates DNA strand exchange, possibly with a helicase-like actio
180 accharomyces cerevisiae (ScRad51) propagated DNA strand exchange preferentially in the 5' to 3' direc
182 context of a model in which a fast phase of DNA strand exchange produces a discontinuous three-stran
183 g identifies Ca2+ as a universal cofactor of DNA strand exchange promoted by mammalian homologous rec
184 he main reason for the low efficiency of the DNA strand exchange promoted by Rad51 protein in vitro i
185 xplain some of the unique characteristics of DNA strand exchange promoted by Rad51 protein, when comp
190 ation, and stimulates homologous pairing and DNA strand exchange promoted in vitro by human recombina
192 hese features depend on the meiosis-specific DNA strand exchange protein Dmc1 (disrupted meiotic cDNA
193 In selecting ssDNA over dsDNA, the RAD51 DNA strand exchange protein has to overcome the entropy
200 he RecBCD enzyme and leads to loading of the DNA strand exchange protein, RecA, onto the chi-containi
201 cBCD enzyme to coordinate the loading of the DNA strand exchange protein, RecA, onto the single-stran
202 in, RadA, possesses the characteristics of a DNA strand exchange protein: The RadA protein is a DNA-d
205 itiation of recombination and for loading of DNA strand-exchange protein RAD-51, despite the fact tha
206 richia coli the RecBCD enzyme also loads the DNA strand-exchange protein RecA onto the newly formed e
207 sal role of Ca2+ in stimulation of mammalian DNA strand exchange proteins and reveal diversity in the
210 rocessed ends are substrates for assembly of DNA strand exchange proteins that mediate DNA strand inv
215 the defining member of a ubiquitous class of DNA strand-exchange proteins that are essential for homo
218 genomic integrity via interactions with the DNA-strand exchange RAD51 protein in homology-directed r
219 mutant protein is capable of catalyzing the DNA strand exchange reaction and is insensitive to inhib
220 h the presynaptic and synaptic phases of the DNA strand exchange reaction as follows: during presynap
221 ocess, how exactly hydrolysis influences the DNA strand exchange reaction at the structural level rem
224 Deinococcus radiodurans (Dr) both promote a DNA strand exchange reaction involving two duplex DNAs.
225 erse" reaction is a unique, highly efficient DNA strand exchange reaction that is not due to redistri
231 RecA protein catalyses an ATP-dependent DNA strand-exchange reaction that is the central step in
232 e Escherichia coli RecA protein performs the DNA strand-exchange reaction utilized in both genetic re
234 protein filament can participate in multiple DNA strand exchange reactions concurrently (involving du
236 at improve DNA pairing can inhibit extensive DNA strand exchange reactions in the absence of ATP hydr
237 ights into the role of ATP hydrolysis in the DNA strand exchange reactions promoted by the bacterial
238 , optimal conditions for the DNA pairing and DNA strand exchange reactions promoted by the RecA and R
239 o coordinate closely with and accelerate the DNA strand exchange reactions promoted by the RecA recom
240 e of ATP hydrolysis in RecA protein-mediated DNA strand exchange reactions remains controversial.
242 combined biochemical reconstitutions of the DNA strand exchange reactions with total internal reflec
243 ort shape changing films that are powered by DNA strand exchange reactions with two different domains
250 and two molecules each of XerC and XerD, the DNA strand-exchange reactions are separated in time and
256 erminal residues eliminates the reduction in DNA strand exchange seen with the wild-type protein at p
257 ssential for DNA strand exchange, it renders DNA strand exchange sensitive to an excess of ssDNA whic
258 to explain how ATP hydrolysis is coupled to DNA strand exchange so as to bring about these effects.
259 that RPA has a critical postsynaptic role in DNA strand exchange, stabilizing the DNA pairing initiat
260 displaced from homologous duplex DNA during DNA strand exchange, stabilizing the initial heteroduple
261 chia coli RecA protein catalyzes the central DNA strand-exchange step of homologous recombination, wh
262 RecA protein promotes homologous pairing and DNA strand exchange, steps important to homologous recom
263 acement to generate PiDSD, an intermolecular DNA strand-exchange strategy to measure a set of key kin
264 bility of RecA to utilize UTP as cofactor in DNA strand exchange suggest a separation of the function
265 recombination (HR) is a crucial mechanism of DNA strand exchange that promotes genetic repair and div
268 omote a search for homology and that perform DNA strand exchange, the two essential steps of genetic
269 though Cre and Int use the same mechanism of DNA strand exchange, their respective reaction pathways
270 the nucleoprotein filament that is active in DNA strand exchange, these findings raise the possibilit
274 ant for the search of homologous DNA and for DNA strand exchange, two critical steps of homologous re
276 The optimal conditions for Rad51-mediated DNA strand exchange used here minimize the secondary str
277 fects both presynaptic complex formation and DNA strand exchange via changes in DNA structure, employ
279 gly, the ability of RAD54 to stimulate RAD51 DNA strand exchange was not significantly affected by SN
280 stranded oligonucleotides were activated for DNA strand exchange when attached as tails protruding fr
282 specific recombinase Tn3 resolvase initiates DNA strand exchange when two res recombination sites and
283 d54 function together to promote intersister DNA strand exchange, whereas Dmc1-Tid1 tilt the bias tow
284 o a gapped duplex DNA molecule and promote a DNA strand exchange with a second homologous linear dupl
286 double-stranded (ds) DNA, an intermediate in DNA strand exchange with unclear functional significance