ライフサイエンスコーパス: sister chromatid exchange

1 recombination with a concomitant increase in sister chromatid exchange.

2 rmal replication intermediates and increased sister chromatid exchange.

3 within the repeats, facilitating slippage or sister chromatid exchange.

4 r maximal induction of replication-dependent sister chromatid exchange.

5 chromosomal aberrations and 3-fold elevated sister chromatid exchange.

6 patterns suggest mechanisms such as unequal sister chromatid exchange.

7 acilitate FA pathway activation and suppress sister chromatid exchange.

8 to an increase in the incidence of telomere sister chromatid exchange.

9 unctional BLM show 10-fold elevated rates of sister chromatid exchange.

10 synthesis and caused a 3-4-fold increase in sister chromatid exchange.

11 relatively normal XRCC1 levels but elevated sister chromatid exchange.

12 erence in HeLa cells leads to an increase in sister chromatid exchange.

13 gene conversion but maintain proficiency in sister chromatid exchange.

14 toxicant as well as an effective inducer of sister-chromatid exchange.

15 t functions in a protein complex to suppress sister-chromatid exchange.

16 Bloom's syndrome is an elevated frequency of sister chromatid exchanges.

17 DNA damage signaling, telomere fragility and sister chromatid exchanges.

18 ative capacity and an increased frequency of sister chromatid exchanges.

19 itro induced enhanced chromosomal breaks and sister chromatid exchanges.

20 elayed and reduced RAD51 response, and fewer sister chromatid exchanges.

21 This leads to an increase in sister chromatid exchanges.

22 A damage, and displayed elevated spontaneous sister chromatid exchanges.

23 the potential for loss of heterozygosity and sister-chromatid exchanges.

24 on in response to DNA damage, and suppresses sister-chromatid exchanges.

25 e of genome stability and the suppression of sister-chromatid exchanges.

26 Furthermore, formation of sister chromatid exchanges, a hallmark of HR, increased

27 Sister chromatid exchanges, a surrogate measure of iHR,

28 recombination repair, we observed extensive sister chromatid exchanges after treatment with tirapaza

29 e fibroblasts displayed an increased rate of sister chromatid exchange and a high frequency of sponta

30 n cells results in an increased frequency of sister chromatid exchange and DNA damage sensitivity aft

31 n, Tet TKO ESCs exhibited increased telomere-sister chromatid exchange and elongated telomeres.

32 At bulky adducts, PrimPol promotes sister chromatid exchange and genetic recombination.

33 Rates of sister chromatid exchange and homologous recombination w

34 ing membrane signaling, and the induction of sister chromatid exchange and HPRT mutations by very low

35 ely to be intact as basal and damage induced sister chromatid exchange and immunoglobulin gene conver

36 hyper-recombination manifested as excessive sister chromatid exchange and loss of heterozygosity.

37 ies but accumulate markedly higher levels of sister chromatid exchange and mitotic bridges.

38 re partially defective in the suppression of sister chromatid exchange and resistance to camptothecin

39 FANCJ-deficient cells display increased sister chromatid exchange and sensitivity to replication

40 We conclude that ORD activity suppresses sister chromatid exchange and stimulates inter-homologue

41 n relieved the cells with the suppression of sister chromatid exchange and therefore led to a hyper-r

42 ase activity to suppress spontaneous unequal sister chromatid exchanges and DNA double-strand break-i

43 c mitotic recombination, a high frequency of sister chromatid exchanges and double strand DNA breaks,

44 telomeres, manifested as increased telomere sister chromatid exchanges and formation of telomere cir

45 ous recombination (HR), exhibiting decreased sister chromatid exchanges and HR-dependent repair as de

46 notype manifests as an elevated frequency of sister chromatid exchanges and interhomologue recombinat

47 ected into BS cells reduces the frequency of sister chromatid exchanges and restores BLM in the nucle

48 ary Pml(C62A/C65A) cells exhibited increased sister-chromatid exchange and chromosome abnormalities.

49 types of Bloom syndrome cells as assessed by sister-chromatid exchange and micronuclei formation assa

50 d telomere shortening, elevation of telomere sister-chromatid exchanges and increased aphidicolin-ind

51 integrated recombination substrate, unequal sister-chromatid exchanges and repair of collapsed repli

52 omycin C (MMC), as measured by cell killing, sister chromatid exchange, and chromosome aberrations.

53 these cells results in chromosome breakage, sister chromatid exchange, and cytotoxicity by a mechani

54 51-mediated D-loop formation, suppression of sister chromatid exchange, and resistance to camptotheci

55 ases karyotype abnormalities and spontaneous sister chromatid exchange, and slows down cell prolifera

56 tability, as quantified by chromatid breaks, sister chromatid exchanges, and H2AX phosphorylation.

57 quency of recombination, gene amplification, sister chromatid exchanges, and micronuclei formation in

58 come hypermutable, exhibit high frequency of sister chromatid exchanges, and show increased micronucl

59 lts may explain why cytologically observable sister chromatid exchanges are induced only weakly by DN

60 fects, including specific gene mutations and sister chromatid exchanges, are induced in neighboring,

61 we examined these cell types for evidence of sister chromatid exchange at telomeres, and observed an

62 centromeric CO-FISH patterns consistent with sister chromatid exchange at the frequency of 5% in prim

63 displaying the characteristics of an unequal sister chromatid exchange between FLP target sites.

64 FLP-mediated unequal sister-chromatid exchange between inverted FRTs produced

65 BLM, telomeric circle formation and telomere sister chromatid exchange, both arising out of nucleolyt

66 n resistance and increased cisplatin-induced sister chromatid exchange, both of which were reversed b

67 s expressing BLM-S144A show normal levels of sister chromatid exchange but fail to maintain the mitot

68 We previously found that the induction of sister chromatid exchanges by UV irradiation was greatly

69 s to telomere shortening, elevated telomeric sister chromatid exchanges, C-circle formation as well a

70 nomic instability and increased frequency of sister chromatid exchange characteristic of Bloom's synd

71 ly 7-methylguanine), can specifically induce sister chromatid exchange, chromatid and chromosome gaps

72 BS cells exhibit elevated rates of sister chromatid exchange, chromosome breaks, and CIN.

73 relation between chromosomal instability and sister chromatid exchange, delayed mutation, and mismatc

74 Thus, we analyzed clones for sister chromatid exchange, delayed reproductive cell dea

75 RECQ5 is significant in suppressing sister chromatid exchanges during homologous recombinati

76 eletion of mRtel1 increased the frequency of sister chromatid exchange events and suppressed gene rep

77 ally, evidence of gene conversion or unequal sister chromatid exchange events in T. quasimodo and T.

78 The sister chromatid exchange events stimulated by Tim reduc

79 ogous recombination, inducing an increase in sister chromatid exchange events.

80 heir integrity, it also permits rare unequal sister chromatid-exchange events within palindromes that

81 n of oncogenic selection and fine mapping of sister-chromatid-exchange events.

82 tion, but not ATM protein disruption, blocks sister chromatid exchange following DNA damage.

83 SQAP treatment reduced the spontaneous sister chromatid exchange formation in CHO wild type and

84 e not affected by the absence of Rad51d, but sister chromatid exchange frequencies did fail to be ind

85 PALB2-MRG15 interaction resulted in elevated sister chromatid exchange frequencies.

86 Sister chromatid exchange frequency and sensitivity to U

87 d levels of cisplatin-induced Rad51 foci and sister chromatid exchange frequency.

88 d points such as chromosome destabilization, sister chromatid exchanges, gene mutation and amplificat

89 of principle, we show our ability to detect sister chromatid exchanges, genome compartmentalization,

90 d Strand-seq data, to enable fine-mapping of sister chromatid exchanges, germline inversion and to su

91 on can be induced display elevated levels of sister chromatid exchange, gross chromosomal aberrations

92 s can occur by replication slippage, unequal sister chromatid exchange, homologous recombination, and

93 the elevated level of gene targeting and of sister chromatid exchanges, implying that Blm primarily

94 These results suggest that an unequal sister chromatid exchange in male meiosis is likely to b

95 mutagenic but causes DNA breaks and elevates sister chromatid exchange in mammalian cells.

96 easured interhomolog recombination and intra/sister chromatid exchange in the CUP1 locus.

97 fic biomarkers (DNA and albumin adducts) and sister chromatid exchanges in the blood of 48 reinforced

98 Missense alleles fail to reduce the sister chromatid exchanges in transfected BS cells or re

99 ting a damaged template, namely mutation and sister chromatid exchange induction.

100 ents are the probable consequence of unequal sister chromatid exchanges involving chromosome 2, as we

101 de the evidence that NRSS, following unequal sister chromatid exchange, is a mechanism by which GSCs

102 e show that gene conversion, and not unequal sister chromatid exchange, is the predominant recombinat

103 hey suggest that gene conversion rather than sister chromatid exchange may be the primary recombinati

104 Neither sister-chromatid exchange nor gene-targeting frequencies

105 BS cells, chromosomal abnormalities such as sister chromatid exchanges occur at highly elevated rate

106 orce in the evolution of the rRNA genes with sister chromatid exchange occurring more often than exch

107 We propose that sister chromatid exchange occurs at the more proximal si

108 with RAD18 deficiency, reverses the elevated sister chromatid exchange of the rad18 mutant, and reduc

109 fications, TERRA expression levels, telomere sister chromatid exchange or telomere length.

110 to be due to events such as multiple unequal sister-chromatid exchanges or gene conversions.

111 ut R1 and R2 retrotransposition the frequent sister chromatid exchanges postulated from various empir

112 , SWS1-SWSAP1-SPIDR drives the high level of sister-chromatid exchange, promotes long-range loss of h

113 nce of chromosomal gaps and breaks, elevated sister chromatid exchange, quadriradial formations, and

114 re unstable genetically and exhibit frequent sister chromatid exchanges, reflective of homologous rec

115 cause in its absence cells display increased sister chromatid exchanges, replication origin firing an

116 ir at endogenous genomic loci by combining a sister chromatid exchange (SCE) assay with fluorescent i

117 Sister chromatid exchange (SCE) can occur by several rec

118 , called Strand-seq, that can be used to map sister chromatid exchange (SCE) events genome-wide in si

119 This activity suppresses potentially harmful sister chromatid exchange (SCE) events in wild-type cell

120 ay be responsible for the elevated levels of sister chromatid exchange (SCE) found in BLM(-/-) cells.

121 Utilizing sister chromatid exchange (SCE) frequencies as a marker

122 d human aging, we analyzed the dependence of sister chromatid exchange (SCE) frequencies on location

123 Here, we report that a sister chromatid exchange (SCE) generated by crossover-a

124 p53 further enhanced the rate of spontaneous sister chromatid exchange (SCE) in Bloom syndrome (BS) c

125 Sister chromatid exchange (SCE) in Escherichia coli resu

126 In the knockout cells, spontaneous sister chromatid exchange (SCE) occurred with twice the

127 likely to be accommodated by adjustments in sister chromatid exchange (SCE) rate, rather than by dir

128 mportance of G2 arrest in DNA damage-induced sister chromatid exchange (SCE) was evident by a 10-fold

129 recombination visualized cytogenetically as sister chromatid exchange (SCE), and that this rate is d

130 Spontaneous sister chromatid exchange (SCE), as monitored between tr

131 the simultaneous high-resolution mapping of sister chromatid exchange (SCE), facilitating the study

132 , 10- and 30-fold higher rate of spontaneous sister chromatid exchange (SCE), heteroallelic recombina

133 Unless the pattern is disrupted by sister chromatid exchange (SCE), the dark chromatid is a

134 n a significant increase in the frequency of sister chromatid exchange (SCE), whereas deleting both B

135 DT40 cells results in an increased level of sister chromatid exchange (SCE)--the hallmark feature of

136 s on UV-induced G1/S checkpoint response and sister chromatid exchange (SCE).

137 s in displaying reduced endogenous levels of sister chromatid exchange (SCE).

138 to decreased BLM protein level and increased sister chromatid exchange (SCE).

139 wever, this mutation does result in elevated sister chromatid exchanges (SCE).

140 mic instability epitomized by high levels of sister-chromatid exchange (SCE) and cancer predispositio

141 ctures in vivo, increase spontaneous unequal sister-chromatid exchange (SCE) in vegetatively growing

142 h IRs and TNRs stimulate spontaneous unequal sister-chromatid exchange (SCE) in yeast.

143 der characterized cellularly by increases in sister chromatid exchanges (SCEs) and numbers of micronu

144 defective for BLM exhibit elevated levels of sister chromatid exchanges (SCEs) and patients with Bloo

145 Sister chromatid exchanges (SCEs) are products of joint

146 Using the occurrence of excessive sister chromatid exchanges (SCEs) as an index of DNA dam

147 al results found an increased association of sister chromatid exchanges (SCEs) at PATRR regions in ex

148 x2(null) cells exhibited reduced spontaneous sister chromatid exchanges (SCEs) but this was not due t

149 itization with caffeine and the induction of sister chromatid exchanges (SCEs) by UV irradiation are

150 suggestion that inter-sister crossovers, or sister chromatid exchanges (SCEs), are quite common.(2-1

151 somal instability, characterized by elevated sister chromatid exchanges (SCEs), as well as chromosoma

152 isiae RAD51 in DNA damage-associated unequal sister chromatid exchanges (SCEs), translocations, and i

153 repair of mitomycin C (MMC)-induced DSBs and sister chromatid exchanges (SCEs), two RAD51-dependent p

154 uent formation of COs, assessed by measuring sister chromatid exchanges (SCEs).

155 features particularly an increased number of sister-chromatid exchanges (SCEs).

156 eted of BLAP75 display an increased level of sister-chromatid exchange, similar to cells depleted of

157 telomeres may be maintained through telomere sister chromatid exchange (T-SCE) in murine telomere rev

158 elicase-deficient mutant, abolished telomere sister chromatid exchange (T-SCE), indicating that WRN n

159 cytic leukemia (PML) bodies (APBs), telomere sister chromatid exchanges (T-SCEs), and extrachromosoma

160 reduces dimer chromosomes, which result from sister chromatid exchange, to monomers.

161 ophila melanogaster, which relies on unequal sister chromatid exchange (USCE) initiated by DNA breaks

162 of BS and FA cells-an elevated frequency of sister chromatid exchanges-was due to a loss of interact

163 Spontaneous frequencies of sister chromatid exchange were not affected by the absen

164 eats; however, no alterations in the rate of sister chromatid exchange were observed.

165 subjects, albumin and DNA adducts as well as sister chromatid exchanges were significantly correlated

166 formants were almost fully corrected whereas sister chromatid exchanges were unchanged.

167 Positional coincidence of >81% of sister chromatid exchanges with target loci is unprecede

168 inery, and increases C-circles and telomeric sister chromatid exchanges, without increasing telomeric

169 Bloom cell lines show increased sister chromatid exchange, yet are proficient in the rep