ライフサイエンスコーパス: differential display

1 expressed in a breast cancer cell line using differential display.

2 d for analysis of gene expression is through differential display.

3 ng during the reverse transcription stage of differential display.

4 nd hibernating brain and compared them using differential display.

5 t repetitive sampling occurs exten-sively in differential display.

6 after epidermal injury was cloned utilizing differential display.

7 s acidophilus was investigated by the use of differential display.

8 ng may considerably reduce the efficiency of differential display.

9 SAR) protein, in adult erythroid cells using differential display.

10 ic mRNA abundances in a manner detectable by differential display.

11 ed for gene expression differences by RT-PCR differential display.

12 f a sex-linked gene from S. latifolia, DD44 (Differential Display 44).

13 Here we have identified by differential display a novel oncogenic Ras target, mob-5

14 Using differential display, a cDNA fragment was identified as

15 Using differential display, a novel gene, Rig-1, was isolated

16 Using differential display, a target gene of AP3/PI was identi

17 e expression profiling methods such as SAGE, Differential Display, AFLP, etc. which rely on PCR.

18 Differential display analysis and mRNA half-life measure

19 olling these cellular events, we performed a differential display analysis between regenerating and n

20 IRIP cDNA was isolated in a differential display analysis of an ischemia/reperfusion

21 tin-like (UBL) gene, 40.1, was identified by differential display analysis of control and gentamicin-

22 clone mc3s5/mtCLIC, has been identified from differential display analysis of differentiating mouse k

23 Differential display analysis of gene expression reveale

24 Differential display analysis of gene expression reveale

25 o have high reproducibility for quantitative differential display analysis of interlysate comparisons

26 Recently we reported differential display analysis of matched macrophage-deri

27 Differential display analysis of mRNA derived from hypox

28 ate-specific gene, PCGEM1, was identified by differential display analysis of paired normal and prost

29 Differential display analysis of rat primary Sertoli cel

30 Differential display analysis of retinal pigment epithel

31 Differential display analysis of the exorbital lacrimal

32 ling prostate cancer metastasis we performed differential display analysis of the human prostate carc

33 Differential display analysis showed that new RNA specie

34 We used differential display analysis to identify 33 putative HA

35 RNA from the enriched cells was subjected to differential display analysis to identify lineage-specif

36 Differential display analysis was initiated to detect po

37 A differential display analysis was performed on poly(A)+

38 Differential display analysis was used to look for gende

39 le rabbit lacrimal glands were compared in a differential display analysis, and a new rabbit lacrimal

40 By using differential display analysis, we examined expression le

41 geted approach based on bulked segregant and differential display analysis.

42 ithdrawn chick oviducts and was subjected to differential display analysis.

43 scription-polymerase chain reaction (RT-PCR) differential display analysis.

44 ed with lineage positive cells by 3' end PCR differential display analysis.

45 us mouse lenses were analyzed by both RT-PCR differential display and a candidate-gene approach.

46 bronectin (FN) and osteopontin (OPN) mRNA in differential display and bioinformatics screen.

47 cally investigate such changes, we used mRNA differential display and cDNA microarrays to screen appr

48 administration of CoPP in rats was found, by differential display and confirmed by Real-Time PCR, to

49 we have used a multidisciplinary approach of differential display and family-specific slot blots in c

50 The method is a two-step combination of differential display and high-sensitivity cDNA arrays.

51 Results of differential display and quantitative PCR analysis showe

52 comparative or subtractive methods, such as differential display and representational difference ana

53 Differential display and RNA analysis of ganglia dissect

54 f breast adenocarcinoma cells in paclitaxel, differential display and single gene analysis demonstrat

55 Petunia inflata, we had previously used mRNA differential display and subtractive hybridization to id

56 d the ubiquitin ligase EDD (E3 identified by differential display) and the nucleoporin Tpr (transloca

57 roaches such as differential cDNA screening, differential display, and cDNA subtraction have been emp

58 ed for gene expression differences by RT-PCR differential display, and transcripts exhibiting altered

59 rial analysis of gene expression and digital differential display; and the published literature, incl

60 We have used a differential display approach to clone some of the genes

61 We have used a differential display approach to identify fibroblast gro

62 Applying the differential display approach, an effective method for a

63 nd pollen maturation, we used microarray and differential display approaches to compare gene expressi

64 Using differential display, arbitrary-primed polymerase chain

65 l cDNA complex probes to sequentially screen differential display arrays.

66 ed to cell differentiation was identified by differential display as a candidate suppressor of metast

67 Through the use of a differential display assay, a transcription factor has b

68 By using the differential display assay, we have cloned a putative re

69 find 25S rRNA represented frequently in our differential display assays, suggesting that our reverse

70 otal cDNA probes allows direct evaluation of differential display bands from the initial reamplificat

71 A PCR-based differential display-cloning approach, using Taxus (yew)

72 To identify the gene(s) responsible, differential display comparing chromosome 11-containing

73 r matrix gene overexpression, we performed a differential display comparison of fibroblasts from clin

74 An mRNA differential display comparison of mouse JB6 promotion-s

75 A differential display comparison of P+ and P- cell mRNAs

76 Since its invention in the early 1990s, differential display (DD) has become one of the most com

77 ation of cellular RNA expression profiles by differential display (DD) involves the visualization of

78 ciated epithelial membrane protein 1), using differential display (DD) of mRNA.

79 We used mRNA differential display (DD) to detect global differences a

80 Differential display (DD) was used to search for new gen

81 (CGH), expression profiling on microarrays, differential display (DD), subtractive hybridization, an

82 Differential display (DD)-PCR analysis comparing normal

83 ation of differentially expressed genes with differential display (DD)-PCR.

84 Using a data-mining tool called Digital Differential Display (DDD) from the Cancer Gene Anatomy

85 proline-rich protein (KPRP) isolated by RNA differential display during skin development.

86 interactions that implicate E3 identified by differential display (EDD) in promoting spindle assembly

87 adipocyte differentiation, we identified by differential display ENC-1, a Drosophila kelch-related p

88 Northern blot analyses confirmed the differential display expression patterns.

89 n of genes in the A-B regulon, a fluorescent differential display (FDD) screen was used to randomly s

90 We used gene chip, differential display, fluorescence-activated cell sorter

91 We have used restriction fragment differential display for isolating genes of the unicellu

92 This work validates the application of mRNA differential display for the discovery of new microbial

93 We describe a method (sub-proteome differential display) for comparing the proteins from tw

94 show a pattern of differential expression on differential display gels must be eluted from the gel ma

95 The EDD (E3 identified by differential display) gene, first identified as a proges

96 Differential display, Gene Discovery Arrays, and Affymet

97 ight, increasing the chances of detection of differential display genes with less background bands.

98 Experiments based on differential display identified 13 additional genes up-r

99 In a primary screen, differential display identified 170 candidate marker gen

100 Immunoprecipitation followed by differential display identified Prx1 mRNA as one of the

101 mRNA differential display identified TFF1 as a gastrin-regula

102 Analysis by differential display identified thioredoxin-1 (TRX) as a

103 Comparison of SKOV-3 to SKOV-3TR by differential display identifies a new gene, TRAG-3 (Taxo

104 a putative ethanol-regulated gene using mRNA differential display in mice genetically selected for se

105 ted a simplified high throughput approach to differential display in order to identify transcriptiona

106 w describe a novel gene, Fxna, identified by differential display in the neonatal rat ovary.

107 omitant induction of 11 genes as revealed by differential display, including the small GTP-binding ve

108 Differential display is a robust technique for detecting

109 This work shows that mRNA differential display is an important tool for the identi

110 In conclusion, differential display is useful to establish melanocyte c

111 etected by UV absorption was generated and a differential display map indicating the presence of up-

112 We used the RT-PCR differential display method to first identify mRNA trans

113 We utilized a messenger RNA differential display method to identify the genes whose

114 The differential display method was used to identify a novel

115 this study, a protein tyrosine kinase (PTK) differential display method was utilized to characterize

116 ism of AHPN action, we identified, using the differential display method, several genes that are diff

117 e early stage of hard-surface treatment by a differential-display method.

118 contribute to sexual behaviors, we used the differential display mRNA screening technique.

119 We here report the cloning by differential display of a novel gene, DLM-1, that is hig

120 We compared the differential display of arbitrarily PCR-amplified gene t

121 ) related gene], was identified through mRNA differential display of interleukin (IL) 9-stimulated an

122 To this end, differential display of melanocyte mRNA isolated from th

123 Differential display of mRNA expression in prostate carc

124 ve antiretroviral factor, OTK18, isolated by differential display of mRNA from HIV type 1-infected pr

125 ge of tumors (>75%) than those identified by differential display of mRNA from individual patient sam

126 We performed differential display of mRNA from patient-matched nontum

127 Differential display of mRNA showed that one gene fragme

128 The differential display of mRNA technique was used to scree

129 Using a differential display of mRNA technique we discovered tha

130 We have found using differential display of mRNA that the growth factor here

131 A modified protocol for differential display of mRNA was used to identify and cl

132 Using differential display of mRNA we identified a P. nil orth

133 and the development of an approach based on differential display of mRNA-reverse transcription-PCR,

134 Using differential display of mRNAs from nontumorigenic infini

135 a hallmark of malignant transformation, the differential display of phosphopeptides on cancer cells

136 ressed in most tumor specimens, we turned to differential display of pooled tissue samples, a techniq

137 ase separation method has been developed for differential display of proteins from cell lysates and a

138 Using differential display of rat fetal and postnatal cardiomy

139 Differential display of reverse transcribed RNA was used

140 nella enterica serovar Typhimurium using the differential display of RNA fingerprinting gels of arbit

141 Differential display of RNA was used to identify genes w

142 enes were identified by messenger RNA (mRNA) differential display of the gastric fundus from gastrin-

143 Differential display of the integrins CD103 and CD11b ar

144 To do this, 3'-end differential display, oligonucleotide chip array hybridi

145 ins of Cstb-deficient mice by using modified differential display, oligonucleotide microarray hybridi

146 ntial expression screens employing PCR-based differential display or hybridization to a cDNA microarr

147 entity of the respective genes (for example, differential display or serial analysis of gene expressi

148 sight into these protective effects, we used differential display PCR (DD-PCR) to amplify RNA from va

149 NF2/ERM/ 4.1 superfamily was isolated using Differential Display PCR (DDPCR) on primary lung tumors.

150 Using differential display PCR (DDPCR), a cDNA fragment from S

151 Differential display PCR analysis of cerebellar interpos

152 enes and cell-type-specific markers, we used differential display PCR analysis of RNA prepared from e

153 Results of differential display PCR analysis showed that SCG10--a n

154 we developed a strategy involving the use of differential display PCR and a panel of genetically matc

155 rential mRNA profiles, such as long distance differential display PCR and cDNA microarrays, promise t

156 Differential display PCR and expression studies show tha

157 se gene, mRTVP-1, as a p53 target gene using differential display PCR and extensive promoter analysis

158 We now use differential display PCR between wild type CHO-K1 cells

159 the neurons was also investigated using mRNA differential display PCR in an attempt to elucidate the

160 present study reports the identification by differential display PCR of Munc13-3, a mammalian homolo

161 tal SVZ is poorly understood, we performed a differential display PCR screen to identify genes prefer

162 In addition, differential display PCR showed that the inactivation of

163 Analysis of approximately 3000 differential display PCR signals resulted in identificat

164 vent these problems, we developed a modified differential display PCR technique that is highly sensit

165 ently identified a novel rat cDNA (best5) by differential display PCR that is regulated during osteob

166 renal failure gene (CRFG), was discovered by differential display PCR to be regulated differentially

167 This study used differential display PCR to identify expression changes

168 targeted by E and P in the VMH, we used the differential display PCR to identify messenger RNAs that

169 Indexing-based differential display PCR was done on neuronal precursor

170 Indexing-based differential display PCR was done to screen for differen

171 Differential display PCR was used to identify alternate

172 In this study, differential display PCR was used to identify P. gingiva

173 mologue in Pneumocystis carinii, isolated by differential display PCR, that is expressed optimally at

174 Herein, using differential display PCR, we have cloned an 85-kDa forkh

175 Using differential display PCR, we have identified a gene [NOE

176 Analysis of the above differential display PCR-derived genes in these cells sh

177 The RNA bulks were compared by differential display PCR.

178 ated tomato (Solanum lycopersicum) leaves by differential display PCR.

179 A differential-display PCR procedure identified the capsul

180 Differential-display PCR showed that MMP3 is downregulat

181 ancer by using a phosphatase domain-specific differential-display PCR strategy.

182 sponse to rickettsial infection, we utilized differential-display PCR.

183 Differential display-PCR (DDPCR) was used to identify a

184 itumor activity, we did restriction fragment differential display-PCR and cloned a novel retinoid rec

185 Differential display-PCR between ovarian tumor cell line

186 In the present study, the differential display-PCR technique was used to obtain a

187 fy pathways relevant to the disease process, differential display-PCR was used.

188 Using the technique of differential display polymerase chain reaction (ddPCR),

189 Using a differential display polymerase chain reaction (PCR) app

190 y expressed in the right ventricle utilizing differential display polymerase chain reaction (PCR) on

191 cipitation (ChIP) coupled with random primed differential display polymerase chain reaction (PCR).

192 Using the Differential Display Polymerase Chain Reaction and 5' Ra

193 e expression changes in cardiac tissue using differential display polymerase chain reaction and cDNA

194 Differential display polymerase chain reaction cloning t

195 ed in breast and prostate cancer cells using differential display polymerase chain reaction screening

196 was obtained by using reverse transcription differential display polymerase chain reaction to identi

197 A differential display polymerase chain reaction was emplo

198 Using differential display polymerase chain reaction, we have

199 ed temporal artery specimens was compared by differential display polymerase chain reaction.

200 ulated with M. graminicola, were compared by differential-display polymerase chain reaction (DD-PCR).

201 We used differential display-polymerase chain reaction to isolat

202 Differential display-polymerase chain reaction was used

203 Using differential display-polymerase chain-reaction in the ma

204 strain PCC 6803 has enabled us to develop a differential display procedure that takes advantage of a

205 Using a domain-specific differential display procedure, we have isolated two tob

206 nduced cell death, we used a comparative RNA differential display procedure.

207 With the 0.7 kb differential display product as a probe, hybridizations

208 d gel slice is limited or when contaminating differential display products co-migrate with the differ

209 expression pattern is that expected from the differential display profile.

210 their post-translational modifications; (2) 'differential display' proteomics for comparison of prote

211 By using a modified differential display protocol, we compared a subset of t

212 Differential display relies on a series of anchored prim

213 d in M. bovis-infected bovine macrophages by differential display reverse transcriptase PCR.

214 during the differentiation process and used differential display reverse transcriptase polymerase ch

215 anding of its cold tolerance mechanism, mRNA differential display reverse transcriptase polymerase ch

216 Differential display reverse transcriptase-PCR (RT-PCR),

217 owth factor-beta1 (TGF-beta 1), we performed differential display reverse transcriptase-PCR analysis

218 Differential display reverse transcriptase-PCR identifie

219 We used a differential display reverse transcriptase-PCR screen fo

220 ystallinum), using a protein-kinase-targeted differential display reverse transcriptase-polymerase ch

221 region and internal mispriming are common in differential display reverse transcription and implies t

222 Using differential display reverse transcription polymerase ch

223 ation of stem/progenitor cells, we have used differential display reverse transcription polymerase ch

224 otein kinase phospatase 1), were detected by differential display reverse transcription-PCR (DD RT-PC

225 cal vein endothelial cells (HUVECs) by using differential display reverse transcription-PCR (DD-RTPCR

226 ng initial interactions, as revealed by mRNA differential display reverse transcription-PCR and cDNA

227 This study used a functional genomic tool, differential display reverse transcription-PCR, to ident

228 Using differential display reverse transcription-polymerase ch

229 ressed genes in the fetal liver, we employed differential display reverse transcription-polymerase ch

230 Differential display reverse transcription-polymerase ch

231 up-regulated in the Ant1(-/-) mouse, we used differential display reverse transcription-polymerase ch

232 By means of differential display reverse-transcriptase polymerase ch

233 Differential-display reverse transcriptase-polymerase ch

234 The RNA samples were analyzed using differential-display reverse transcription-polymerase ch

235 of anergy in cloned human CD4+ T cells using differential display RT-PCR and subsequently examined th

236 mRNA differential display RT-PCR has been extensively used fo

237 ction of DeltaF508 trafficking, we performed differential display RT-PCR on mRNA from IB3-1 CF bronch

238 e DeltaF508-CFTR trafficking, we performed a differential display RT-PCR screen on IB3-1 CF bronchiol

239 Using a differential display RT-PCR strategy to identify novel g

240 Finally, the use of differential display RT-PCR was an effective approach to

241 Whole genome scan analysis, differential display RT-PCR, Northern blot, and RT-PCR a

242 for such genes we have performed a PCR-based differential display screen using RNAs from rostral neoc

243 receptor blocking antibodies, we performed a differential display screen with cells grown in the pres

244 relative to pure species was identified in a differential display screen.

245 receptor blocking antibodies, we performed a differential display screening and isolated differential

246 Through a comprehensive differential display screening of oncogenic ras target g

247 Removal of common mRNAs prior to differential display should diminish redundant identific

248 patients with non-small cell lung carcinoma, differential display shows that aldo-keto reductase (AKR

249 Here we used a differential display strategy to detect cDNAs present in

250 A modified differential display strategy was used to identify a gen

251 For this purpose, the differential display technique and subsequent Northern b

252 By using a mRNA differential display technique to search for salicylate

253 cumulate excess lipids, we employed the mRNA differential display technique using RNA isolated from h

254 OC28, was identified by an agarose gel-based differential display technique, and it was found to be u

255 Using the mRNA differential display technique, seven cDNAs have been is

256 By using mRNA differential display technique, we show, herein, that es

257 heir immediate progenitors in mice using the differential display technique.

258 ppressive subtractive hybridization (SSH) or differential display techniques such as cDNA-AFLP (Ampli

259 reaction-based subtractive hybridization and differential display techniques to identify aldosterone-

260 We used differential display techniques to identify cDNA fragmen

261 Using differential display techniques, we have isolated 27 ret

262 ated brain mRNAs identified using subtracted differential display techniques.

263 rse transcriptase-initiated PCR (RT-PCR) and differential display technology.

264 in human cancer for a gene, HLM, isolated by differential display, that bears homology to an oxystero

265 nducible proapoptotic genes, we compared, by differential display, the expression of genes in spleen

266 tages of breast carcinogenesis, we performed differential display to compare the gene expression patt

267 We have used differential display to detect altering mRNA levels in r

268 We used differential display to detect enhanced expression of an

269 We used differential display to identify genes affected by acute

270 d parental DC-3F cells were compared by mRNA differential display to identify genetic changes occurri

271 We performed differential display to identify hematopoietic cell-spec

272 rostate cancer differentiation, we used mRNA differential display to identify the gene(s) induced by

273 ntrast with the few previous applications of differential display to prokaryotes, we use a large numb

274 located at the S locus, we used fluorescent differential display to screen for differential gene exp

275 To further understand the role of SrhSR, differential display two-dimensional gel electrophoresis

276 Differential display was employed to identify target gen

277 erica serotype Typhimurium infection, an RNA differential display was made with total RNA extracted f

278 ormation requires expression of other genes, differential display was performed.

279 In parallel experiments, differential display was used in an attempt to identify

280 mRNA differential display was used in conjunction with a modi

281 y genes associated with akinete development, differential display was used to amplify and compare cDN

282 scriptase-polymerase chain reaction (RT-PCR) differential display was used to evaluate differential g

283 se observed clinical differences in outcome, differential display was used to identify a novel gene,

284 Differential display was used to identify H. influenzae

285 To isolate candidate RNase-L substrates, differential display was used to identify mRNAs that exh

286 in cell growth and/or apoptosis in leukemia, differential display was used to identify mRNAs that sho

287 The technique of mRNA differential display was used to identify simultaneously

288 Differential display was used to isolate cDNA clones fro

289 mRNA differential display was used to screen for novel gene p

290 Employing differential display we identified several genes whose t

291 Using degenerative primed PCR followed by differential display, we analyzed the tyrosine kinase ex

292 Using differential display, we cloned a gene with reduced expr

293 Using RNA differential display, we find that genes encoding three

294 Using differential display, we identified a cDNA fragment that

295 Using differential display, we identified the cDNA of a novel

296 Using a differential display, we isolated cDNAs preferentially a

297 Utilizing differential display, we searched for molecular componen

298 of the CLOCK (CLK) transcription factor and differential display, we uncovered several striking feat

299 Sertoli cell-germ cell co-cultures and mRNA differential display were used.

300 homogenized rat lungs and then subjected to differential display with combinations of oligo(dT) and