ライフサイエンスコーパス: renaturation

1 ope that is amenable to mAb recognition upon renaturation.

2 otein to DNA has revealed a new mechanism of renaturation.

3 ty undeterred by repetitive denaturation and renaturation.

4 hydrolyzable analog of GTP, GMP-PCP, inhibit renaturation.

5 d aminoacylation compared to wild type after renaturation.

6 edure was developed for its purification and renaturation.

7 shown that hsp70 is required for luciferase renaturation.

8 rotein sequence or in vitro denaturation and renaturation.

9 e tested for additional factors that enhance renaturation.

10 avoiding the need for dsDNA denaturation and renaturation.

11 main bearing the proper conformation without renaturation.

12 ability to fibrillize by simple denaturation/renaturation.

13 s by denaturation followed by subunit mixing renaturation.

14 olet-visible (UV-vis) monitored denaturation/renaturation.

15 pressure for simultaneous solubilization and renaturation.

16 preventing their aggregation and spontaneous renaturation.

17 lectrochemically controlled denaturation and renaturation.

18 bind HA after SDS-PAGE, electrotransfer, and renaturation.

19 ons for NBD1-R expression, purification, and renaturation.

20 DNA strand-transfer and single-stranded DNA renaturation activities are associated with the unique N

21 s or less than that of hsp 70, and it has no renaturation activity in the absence of hsp 70.

22 This renaturation activity is greatly increased under conditi

23 tivated ATPase activity is essential for the renaturation activity of Hsp70; therefore, the effects o

24 N or the C terminus does not abolish the DNA renaturation activity of the protein.

25 e supplemented with a DnaJ protein to obtain renaturation activity.

26 -PAGE, and their identities were verified by renaturation and activity assays.

27 overed in biologically active form following renaturation and anion exchange chromatography.

28 ich blocked exchange mediated by spontaneous renaturation and branch migration; beta imposed a polari

29 of divalent cation concentration during mRNA renaturation and by the presence of an antisense sequenc

30 can be detected by their ability to undergo renaturation and catalyze the phosphorylation of a pepti

31 can be detected by their ability to undergo renaturation and catalyze the phosphorylation of a pepti

32 ablation, distamycin inhibition of binding, renaturation and competition experiments, and tissue dis

33 A c-Fos/c-Jun complex was generated by co-renaturation and purified via a His-tag on the full-leng

34 Renaturation and reconstitution experiments with Zn(2+)

35 t 95, 55, and 60 degrees C for denaturation, renaturation, and DNA extension, respectively.

36 t increase in the rate of in vitro substrate renaturation, and partial independence from the Hsp70 ch

37 the DNA template by thermal denaturation and renaturation, and this hairpin structure was predicted t

38 d stable presynaptic complexes that promoted renaturation as rapidly as RecA, but the recombinant hum

39 40 cooperate with further factors in protein renaturation, as demonstrated by the finding that lucife

40 omplementary single-stranded DNA and promote renaturation, as measured by Tris-phosphate agarose gel

41 n renatured by dialysis of the resin against renaturation buffer.

42 ed following electroelution from the gel and renaturation by dialysis.

43 protein family, which also enhances protein renaturation by hsp 70, we purified a 38-kDa protein fro

44 Although significant renaturation can occur with only hsp70 and DnaJ proteins

45 ve sequences follow a nonspecific pathway to renaturation consistent with a molecular "slithering" me

46 ntrol samples, subjected to one denaturation/renaturation cycle and products are electrophoresed agai

47 d be slightly induced by a urea denaturation-renaturation cycle in an extracellular protein fraction,

48 vity could be induced by a urea denaturation-renaturation cycle in this fraction.

49 Externally imposed denaturation-renaturation cycles did not reverse this tendency.

50 y by exploiting ion-induced DNA denaturation/renaturation cycles.

51 y, thus restoring stability, as evidenced by renaturation described previously and by 70-ns molecular

52 appropriate conditions for hybridization and renaturation, determinations of sequence complexity, and

53 The renaturation effect of ALA-D is additive with that of RF

54 The renaturation-enhancing effect of ALA-D may be caused by

55 Following electrophoresis and renaturation, enzymatic digestions of the substrate in 5

56 nzyme, following sequential denaturation and renaturation, estimate the molecular size of the catalyt

57 It is found that a typical renaturation event occurs through a nucleation step, whe

58 became protease-accessible, indicating rapid renaturation except along the nuclease fold with restora

59 ty through a five-step procedure including a renaturation experiment and found that its apparent mole

60 Denaturation/renaturation experiments in the presence of various meta

61 orption spectrum of E.NAD+ from denaturation-renaturation experiments reveals the presence of a broad

62 Renaturation experiments showed that the approximately 8

63 performed "double-jump" GdnHCl denaturation/renaturation experiments, with a third jump, where the r

64 ell defined folding intermediate in the acid renaturation folding pathway of this protein reflected i

65 nto a functional protein splicing element by renaturation from 6 M urea.

66 the synthetic peptide were reconstituted by renaturation from guanidinium chloride.

67 Temperature-induced unfolding and renaturation from the urea-denatured state revealed that

68 lving the formation of key base pairs before renaturation fully ensues.

69 g sequences could be restored, partially, by renaturation; however, self-cleavage of transcripts with

70 egation and to facilitate subsequent protein renaturation in cooperation with ATP-dependent chaperone

71 eaminases was observed on their denaturation-renaturation in EDTA, which revealed the mutants to be r

72 mycin (GA) on the kinetics of the luciferase renaturation in RRL were examined to gain insight into t

73 reversed GA-induced inhibition of luciferase renaturation in RRL.

74 rporated phosphate after denaturation and/or renaturation in SDS gels.

75 rporate a single nucleotide in situ upon its renaturation in the gel.

76 bind to DNA, but following denaturation and renaturation in the presence of DNA, binding can be demo

77 enuator could not be restored efficiently by renaturation in vitro.

78 The contribution of hsp90 to renaturation is only partially blocked by geldanamycin,

79 ion methods, controlled DNA denaturation and renaturation is particularly essential and achieved by c

80 g of rhodanese but, as with wild-type GroEL, renaturation is quenched by addition of mutant GroEL 'tr

81 However, renaturation is reduced under conditions that stabilize

82 es active proteins (without denaturation and renaturation), it is more sensitive compared with most e

83 o strains, G186AS and Downs, and analyzed by renaturation kinetics and genomic reconstruction with th

84 ents of single DNA molecule denaturation and renaturation kinetics in the presence of gp32 and its pr

85 enhancer glycerol (<5 m) does not alter the renaturation kinetics of EcMDH, it dramatically accelera

86 Here we use renaturation kinetics to compare the repetitive nature o

87 lasma capsulatum was determined by using DNA renaturation kinetics, genomic reconstruction, and flow

88 Conditions that promote renaturation of an unfolded protein also promote protein

89 A common obstacle to proper renaturation of an unfolded protein is aggregation, an i

90 The presence of free BACE Pro peptide during renaturation of BACE460 but not ProBACE460 increases rec

91 of 1 BchI:1 BchD was sufficient for maximum renaturation of BchD.

92 rmation without interfering with the correct renaturation of carbonic anhydrase.

93 , is a DNA binding protein that promotes the renaturation of complementary single strands.

94 inds to single-stranded DNA and promotes the renaturation of complementary single strands.

95 ichiometry of binding to DNA and the rate of renaturation of complementary strands were similar for t

96 cent, growing polypeptide chains to in vitro renaturation of complete chains and determining the role

97 ing anti-aggregation activity, promoting the renaturation of denatured proteins, and preferential bin

98 gation, also strongly inhibit EF-Tu-mediated renaturation of denatured rhodanese to levels near those

99 F) Tu has chaperone-like capacity to promote renaturation of denatured rhodanese.

100 The proposed model is used to examine the renaturation of DNA.

101 -induced attraction, which helps mediate the renaturation of DNA.

102 Renaturation of E1 with a similarly slow kinetics was al

103 mimicking double-strand breaks, and prevents renaturation of long stretches (>1 kb) of denatured dsDN

104 were tested for their ability to inhibit the renaturation of luciferase and bind to Hsp70 in reticulo

105 n of hsp 70, RF-hsp 70 increases the rate of renaturation of luciferase by hsp 70 about 3-4-fold.

106 Rabbit reticulocyte ALA-D stimulates the renaturation of luciferase by hsp 70 up to 10-fold at co

107 recycling protein and markedly enhances the renaturation of luciferase by hsp 70.

108 e lysate based upon its ability to stimulate renaturation of luciferase by hsp 70.

109 f Hsp70; therefore, the effects of HspBP1 on renaturation of luciferase in a reticulocyte lysate and

110 and peptide-K inhibited chaperone-dependent renaturation of luciferase in RRL.

111 Chaperone-mediated renaturation of luciferase obeyed Michaelis-Menten kinet

112 increased several folds during denaturation/renaturation of mitochondrial proteins in vitro, suggest

113 it dramatically accelerates the spontaneous renaturation of PmMDH at all temperatures tested.

114 Renaturation of polypeptides excised from sodium dodecyl

115 eterotrimers were formed by denaturation and renaturation of protein mixtures; when such mixtures con

116 We surveyed conditions for renaturation of purified rMMP-1 in 6 M guandine hydrochl

117 conformation and can be replicated by proper renaturation of recombinant Tromp1.

118 ependent denaturation followed by misaligned renaturation of repeated sequences and intermolecular pa

119 Renaturation of rhodanese and GTP hydrolysis by EF-Tu ar

120 related biological chaperones facilitate the renaturation of substrate proteins by minimizing the agg

121 with a short thermal denaturation, prevents renaturation of the duplex nucleic acids (dsDNA/RNA).

122 Further, denaturation/renaturation of the EICARMP-inactivated enzyme did not r

123 e recovery of activity upon denaturation and renaturation of the enzyme.I complex.

124 omplexes can be obtained by denaturation and renaturation of the fragment ("induced" association) wit

125 tent and fidelity of AMP-dependent, in vitro renaturation of the mutant AMP-free apoETF is reduced by

126 Isolation and renaturation of the protein from SDS/polyacrylamide gel

127 Renaturation of the small proteinase inhibitor cystatin

128 dC-tailed template assay, it was found that renaturation of the template was required for factor 2 f

129 Because the renaturation of the Venus fluorescent protein results in

130 Renaturation of thermally denatured firefly luciferase i

131 The renaturation of thermally denatured firefly luciferase r

132 However, the rates of denaturation and renaturation of V60N were faster.

133 Denaturation and renaturation of vitronectin isolated from human plasma w

134 Denaturation and renaturation of vitronectin under near physiological sol

135 MP-free apoETF is reduced by 57% compared to renaturation of wild type apoETF, likely due to the abse

136 ation of CAD by SDS gel electrophoresis, and renaturation on a nitrocellulose membrane, strongly sugg

137 espectively, following chemical denaturation/renaturation or transient heat shock.

138 at and/or boiling in SDS, precipitation, and renaturation or when fragments were recovered from an SD

139 slow refolding kinetics, indicating distinct renaturation pathways that implicate slow prolyl peptide

140 ciation of cross-linked complexes by SDS and renaturation prior to immunoprecipitation did not preven

141 echnique and a SDS-polyacrylamide separation/renaturation procedure led to the hypothesis that this p

142 ctahedron structure by a simple denaturation-renaturation procedure.

143 determining step that limits the rate of the renaturation process and constitutes a kinetic trap.

144 A study of the denaturation-renaturation process of D(3) suggested that without this

145 DnaJ proteins, hsp90 also contributes to the renaturation process, both in the complex environment of

146 rated in vitro using a stepwise denaturation-renaturation process.

147 As renaturation progresses, the noncompact dimer undergoes

148 inactivate its capacity to chaperone protein renaturation, protected HRI from irreversible denaturati

149 f recombinant inclusion body protein using a renaturation protocol that was originally developed for

150 Prp21 was purified using a solubilization/renaturation protocol.

151 MfpA refolded using a novel "time-dependent renaturation" protocol yields protein with native second

152 eliminated by denaturation and recovered by renaturation, provided that the concentration of denatur

153 e strongly to a presumed intermediate in the renaturation reaction that beta itself catalyzed, and be

154 the polypeptide backbone; the inhibition of renaturation/reassociation described here is probably du

155 partitioning that slows the overall rate of renaturation relative to the chaperonin chamber, where s

156 sure of ProBACE460 to guanidine denaturation/renaturation results in a 7-fold higher recovery of BACE

157 y only if iron and sulfur are present in the renaturation steps.

158 For renaturation studies of recombinant Tromp1 (rTromp1), a

159 t hsp90 is not an essential component of the renaturation system.

160 By a fractionation/renaturation technique the Adx factor in mouse Y1 adreno

161 Kinase renaturation tests designed to detect reactivated protei

162 DNA but remains bound to the DNA product of renaturation that beta itself catalyzes.

163 Following renaturation, the 40-kD recombinant XCP1 was not proteol

164 xploit the fact that, following denaturation/renaturation, the PCR amplified JH flanking region DNA f

165 of alpha-crystallin was observed during the renaturation, the role of ATP is not clear.

166 Upon renaturation, this fragment bound to operator with an af

167 also undergoes autoproteolysis rapidly upon renaturation to produce two products.

168 The generality of "time-dependent renaturation" to other proteins and denaturation methods

169 The GA inhibited luciferase renaturation uncompetitively with respect to ATP concent

170 ntrol of five cycles of DNA denaturation and renaturation, under otherwise constant conditions, could

171 less effective than cyclodextrin at inducing renaturation upon detergent removal.

172 When renaturation was carried out in the absence of thiols, t

173 lded on the resin, and the efficiency of the renaturation was determined by the efficiency of the pro

174 ow rescue of protein from aggregation during renaturation, we developed a novel application of mass s

175 Conditions for its renaturation were determined by studying the refolding b

176 ycling, 30 cycles of pH-induced denaturation/renaturation were used to amplify protein DNA fragments

177 We have developed a technique based on DNA renaturation which normalizes repetitive DNA, and thereb

178 90-mediated p56lck biogenesis and luciferase renaturation while enforcing salt-stable interactions wi

179 HspBP1 inhibited renaturation with half-maximal inhibition at 2 microM.

180 Kinetic analysis of PmMDH renaturation with increasing glycerol concentrations sug

181 Improving renaturation yields by minimizing aggregation and reduci

182 of inclusion bodies whose solubilization and renaturation yields poly(A) polymerase activity that cor