ライフサイエンスコーパス: transcriptional regulatory network

1 on factor to DNA is the central event in any transcriptional regulatory network.

2 molecular rheostat for the control of a key transcriptional regulatory network.

3 and from this we reconstructed a functional transcriptional regulatory network.

4 providing a quantitative description of the transcriptional regulatory network.

5 odels propose that v-rel disrupts the normal transcriptional regulatory network.

6 is crucial for understanding the dynamics of transcriptional regulatory network.

7 ed regulation and the context-dependent post-transcriptional regulatory network.

8 ion time series to delineate the Th17 global transcriptional regulatory network.

9 a is a powerful method for understanding the transcriptional regulatory network.

10 same global protein-protein interaction and transcriptional regulatory networks.

11 gnaling pathways and their intersection with transcriptional regulatory networks.

12 icroarray and TF binding data for unraveling transcriptional regulatory networks.

13 UTR formation and its consequences for post-transcriptional regulatory networks.

14 ns, microbial organisms have evolved complex transcriptional regulatory networks.

15 expression rely on transcriptional and post-transcriptional regulatory networks.

16 ion factors is fundamental for understanding transcriptional regulatory networks.

17 clear hormone receptors and their associated transcriptional regulatory networks.

18 operties, and a novel interactive display of transcriptional regulatory networks.

19 hypotheses that further our understanding of transcriptional regulatory networks.

20 cription factors is important in deciphering transcriptional regulatory networks.

21 informatics tools in assisting in unraveling transcriptional regulatory networks.

22 e expression is under the control of several transcriptional regulatory networks.

23 data and gene expression data to reconstruct transcriptional regulatory networks.

24 lled by environmental signals acting through transcriptional regulatory networks.

25 ation is an essential step in elucidation of transcriptional regulatory networks.

26 d the way for genome-scale reconstruction of transcriptional regulatory networks.

27 We extend our network analysis to encompass transcriptional regulatory networks.

28 ral approach for building detailed models of transcriptional regulatory networks.

29 pment of methods that use this data to infer transcriptional regulatory networks.

30 connectivity information for the underlying transcriptional regulatory networks.

31 uable tools for systems-level exploration of transcriptional regulatory networks.

32 x-sensitive signal transduction pathways and transcriptional regulatory networks.

33 have implications for studying genome-scale transcriptional regulatory networks.

34 molecular level and its role in genome-wide transcriptional regulatory networks.

35 taneously infer the transcriptional and post-transcriptional regulatory networks.

36 additional substrates for known enzymes, and transcriptional regulatory networks.

37 remain largely untapped for the analysis of transcriptional regulatory networks.

38 y play an important role in the evolution of transcriptional regulatory networks.

39 d regulatory programs that can be modeled as transcriptional regulatory networks.

40 m of discovering the underlying hierarchy in transcriptional regulatory networks.

41 n is hampered by our incomplete knowledge of transcriptional regulatory networks.

42 The regulatory relations are modeled using transcriptional regulatory networks.

43 ous study were superposed with the resulting transcriptional regulatory networks.

44 ultiple transcription factors in large-scale transcriptional regulatory networks.

45 Transcriptional regulatory networks allow bacteria to ex

46 We also demonstrate, using transcriptional regulatory-network analyses, genetic int

47 tory network is similar in complexity to the transcriptional regulatory network and is thought to be

48 hensively reconstruct the genome-wide GadEWX transcriptional regulatory network and RpoS involvement

49 te central nervous system requires a complex transcriptional regulatory network and signaling process

50 Moreover, transcriptional regulatory networks and electronic circu

51 sults suggest an unappreciated complexity of transcriptional regulatory networks and highlight the fu

52 fferentiation, and our results have revealed transcriptional regulatory networks and new factors (eg,

53 Here we review the properties of transcriptional regulatory networks and the rapidly evol

54 one of the preliminary steps to reconstruct transcriptional regulatory networks and to identify sign

55 The key components of a transcriptional regulatory network are the connections b

56 Transcriptional regulatory networks are fine-tuned syste

57 Transcriptional regulatory networks are one of the mecha

58 metabolic, protein-protein interaction, and transcriptional regulatory networks are used differentia

59 a scaffold for describing the Synechocystis transcriptional regulatory network as well as efficient

60 ion factor in E. histolytica that controls a transcriptional regulatory network associated with oxida

61 ic miRNA expression patterns are achieved by transcriptional regulatory networks at different develop

62 ormation that can help the identification of transcriptional regulatory networks at the full genome s

63 s not been unequivocally traced, nor has its transcriptional regulatory network been fully clarified.

64 I also compare and contrast the transcriptional regulatory networks between the two yeas

65 udies are uncovering not only the underlying transcriptional regulatory networks, but also how these

66 intracellular events, such as metabolic and transcriptional regulatory networks, but not in dynamic

67 derstanding the organization and function of transcriptional regulatory networks by analyzing high-th

68 t microRNAs provide phenotypic robustness to transcriptional regulatory networks by buffering fluctua

69 ossible information-processing tasks which a transcriptional regulatory network can realize.

70 Our analysis suggests that transcriptional regulatory networks can be identified us

71 nduces persistent alterations in genome-wide transcriptional regulatory networks, chromatin remodelin

72 For example, transcriptional regulatory networks consist of interacti

73 e have reconstructed the nutrient-controlled transcriptional regulatory network controlling metabolis

74 Transcriptional regulatory networks controlling cell fat

75 ized that the rlrA locus has integrated into transcriptional regulatory networks controlling expressi

76 Drosophila has demonstrated that reasonable transcriptional regulatory network diagrams representing

77 Transcriptional regulatory networks direct the developme

78 h to define the functional correlates of the transcriptional regulatory network driving the early res

79 ministration, we reverse engineered a global transcriptional regulatory network during protracted abs

80 events and to improve understanding of post-transcriptional regulatory networks during mouse lens de

81 The evolution of transcriptional regulatory networks entails the expansio

82 Identifying the complete transcriptional regulatory network for an organism is a

83 Unraveling the transcriptional regulatory network for inducing cardiomy

84 The data were assembled into a transcriptional regulatory network for podocyte developm

85 address these questions, we characterized a transcriptional regulatory network for the metastasis su

86 this problem by using the largest assembled transcriptional regulatory network for yeast.

87 construction of the integrated metabolic and transcriptional regulatory networks for Escherichia coli

88 n models, which can inform the prediction of transcriptional regulatory networks for extant HDs or th

89 t consequences for accurately reconstructing transcriptional regulatory networks, for motif discovery

90 oarray and promoter sequence data to infer a transcriptional regulatory network from the response to

91 ory modules will be a key step in assembling transcriptional regulatory networks from gene expression

92 critical step in our ability to reconstruct transcriptional regulatory networks from gene expression

93 zed in 3-dimensional space, showing that the transcriptional regulatory network governing metabolism

94 re that allows obtaining alternative genomic transcriptional regulatory network (GTRN) that still mai

95 genes encoding several key components of the transcriptional regulatory network has an important role

96 The structure of complex transcriptional regulatory networks has been studied ext

97 The evolution of transcriptional regulatory networks has thus far mostly

98 Few transcriptional regulatory networks have been described

99 We show that prokaryotic transcriptional regulatory networks have evolved princip

100 Discovering transcriptional regulatory networks helps us to understa

101 well-characterized abiotic stress-associated transcriptional regulatory networks (i.e. ORYZA SATIVA D

102 Elucidating the transcriptional regulatory network immediately downstrea

103 that RKIP is a novel component of the Snail transcriptional regulatory network important for the pro

104 ed the call graph, which is analogous to the transcriptional regulatory network in a cell.

105 way to full bottom-up reconstruction of the transcriptional regulatory network in bacterial cells.

106 Here we comprehensively reconstruct the Fur transcriptional regulatory network in Escherichia coli K

107 econstruct networks with the topology of the transcriptional regulatory network in Escherichia coli w

108 nt advancements have revealed a complex post-transcriptional regulatory network in humans involving m

109 f their selective functional activity in the transcriptional regulatory network in mouse but not huma

110 1 as a key functional target of NRL-centered transcriptional regulatory network in rod photoreceptors

111 sources, we created an extensive map of the transcriptional regulatory network in Saccharomyces cere

112 ignalling pathway, which cooperates with the transcriptional regulatory network in sustaining ESC sel

113 perone Hfq drafts an unexpectedly large post-transcriptional regulatory network in this organism, com

114 rigenesis through a SOX9 and FOXG1-dependent transcriptional regulatory network in vitro and in vivo.

115 ecause the best and most extensively studied transcriptional regulatory network in Xenopus is that un

116 fy many widely expressed factors that impact transcriptional regulatory networks in a cell-selective

117 genomic sequences to reconstruct and analyze transcriptional regulatory networks in Bacteria, but the

118 g regulatory networks can be interlaced with transcriptional regulatory networks in eukaryotic gene e

119 f TF interactions may help to understand the transcriptional regulatory networks in eukaryotic system

120 annotations greatly expand the scope of post-transcriptional regulatory networks in mammals, and have

121 arget sequences is pivotal to fully annotate transcriptional regulatory networks in metazoan genomes.

122 This approach may be useful for modeling transcriptional regulatory networks in more complex euka

123 setting the foundations for dissecting post-transcriptional regulatory networks in stem cells.

124 dent relationship between the UME6 and NDT80 transcriptional regulatory networks in the meiotic gene

125 emonstrated through its application to infer transcriptional regulatory networks in the yeast cell cy

126 identifying new cis regulatory elements and transcriptional regulatory networks in various genomes.

127 is article, we develop and apply methods for transcriptional regulatory network inference from divers

128 We have developed a computational method for transcriptional regulatory network inference, CARRIE (Co

129 These findings uncover a novel transcriptional regulatory network influencing Drosophil

130 is known about how they are integrated with transcriptional regulatory networks into coherent gene e

131 Decomposing transcriptional regulatory networks into functional modu

132 ant challenge, lagging behind predictions of transcriptional regulatory networks into which they ofte

133 osttranslationally control components of the transcriptional regulatory network involved in the iron

134 Our observations delineate a novel post-transcriptional regulatory network involving carbohydrat

135 Elucidating the human transcriptional regulatory network is a challenge of the

136 TX (KDM6a) We propose that an NKX3.1-G9a-UTY transcriptional regulatory network is essential for pros

137 ce, the components and dynamics of the HoxB4 transcriptional regulatory network is poorly understood,

138 The post-transcriptional regulatory network is similar in complex

139 revisiae, the results suggest that the yeast transcriptional regulatory network is very sparse, conta

140 ip between gene duplication and evolution of transcriptional regulatory networks is largely unexplore

141 The objective of identifying transcriptional regulatory networks is to provide insigh

142 kit to generate a computationally executable transcriptional regulatory network model of blood develo

143 This approach allowed us to infer transcriptional regulatory network models that recapitul

144 nciples, we present a comparison between the transcriptional regulatory network of a well-studied bac

145 An important step in unravelling the transcriptional regulatory network of an organism is to

146 ify Foxp1 as an essential participant in the transcriptional regulatory network of B lymphopoiesis.

147 We use the known transcriptional regulatory network of Escherichia coli t

148 Here we use the transcriptional regulatory network of Escherichia coli t

149 Switching is controlled by a transcriptional regulatory network of interlocking feedb

150 Our findings provide new insight into the transcriptional regulatory network of NKX2-1 and suggest

151 on factor 4 (Oct3/4) is a master gene in the transcriptional regulatory network of pluripotent cells.

152 The main idea is to use the known transcriptional regulatory network of reference organism

153 The generated transcriptional regulatory network of the gingival inter

154 Characterization of the transcriptional regulatory network of the normal cell cy

155 Remarkably, the transcriptional regulatory network of the SMAD2 promoter

156 stributed architecture behind the scale-free transcriptional regulatory network of yeast by applying

157 transcriptome, we obtained insights into the transcriptional regulatory networks of AP-1 in TNBC cell

158 We found that the transcriptional regulatory networks of both Saccharomyce

159 We use our method to analyze the transcriptional regulatory networks of E. coli, H. sapie

160 We apply this approach to the transcriptional regulatory networks of Escherichia coli

161 First, from the experimentally verified transcriptional regulatory networks of Escherichia coli,

162 We are beginning to elucidate transcriptional regulatory networks on a large scale and

163 In this study, we describe a core PPARGC1A transcriptional regulatory network operating in HepG2 ce

164 tic gene expression by targeting three major transcriptional regulatory networks: peroxisome prolifer

165 l layout, but there is a key difference: The transcriptional regulatory network possesses a few globa

166 e full yeast protein-protein interaction and transcriptional regulatory networks, protein hubs with m

167 factor binding provide one view of potential transcriptional regulatory networks, regulation also occ

168 r VegT that are components of an established transcriptional regulatory network required for mesendod

169 This analysis defined a transcriptional regulatory network required for the expr

170 Establishing transcriptional regulatory networks requires knowledge o

171 Both the MRTF-SRF and the YAP-TEAD transcriptional regulatory networks respond to extracell

172 Interaction of the Csr system with transcriptional regulatory networks results in a variety

173 Genome-wide mapping of the XBP1 transcriptional regulatory network revealed that XBP1 dr

174 cific genes and support its proposed role in transcriptional regulatory network(s) during rod differe

175 Analysis of transcriptional regulatory networks showed that this cla

176 We show here that a Hox transcriptional regulatory network specifies motor neuro

177 Transcriptional regulatory networks specify regulatory p

178 Transcriptional regulatory networks specify the interact

179 These findings provide key insights into the transcriptional regulatory network specifying this still

180 tomated process can use motifs to assemble a transcriptional regulatory network structure.

181 egulation, implying a much more complex post-transcriptional regulatory network than is currently kno

182 This process involves the action of a transcriptional regulatory network that builds and maint

183 , and an interactive visualization of a full transcriptional regulatory network that can be painted w

184 rms the foundation for a complete map of the transcriptional regulatory network that controls the cel

185 sed to measure the dynamics of any bacterial transcriptional regulatory network that is affected by i

186 ome assembly and function is controlled by a transcriptional regulatory network that is induced by FA

187 We define an IEC transcriptional regulatory network that is shared betwee

188 Our studies place FoxO4 in the center of a transcriptional regulatory network that links gene trans

189 activity, and provides an initial map of the transcriptional regulatory network that underlies the ho

190 This information is necessary for defining transcriptional regulatory networks that contribute to c

191 tionary context, to provide new insight into transcriptional regulatory networks that control photosy

192 Transcriptional regulatory networks that control the mor

193 gy have made possible the study of intricate transcriptional regulatory networks that describe gene e

194 y controlled, however, little is known about transcriptional regulatory networks that effect gene exp

195 em and, thus, integrate Elf-4 into the wider transcriptional regulatory networks that govern hematopo

196 Here we review emerging data on transcriptional regulatory networks that govern the diff

197 ge characteristic genes to better define the transcriptional regulatory networks that regulate chondr

198 function studies to build a new model of the transcriptional regulatory networks that specify 5-HT ne

199 The transcriptional regulatory networks that specify and mai

200 ific neuronal populations can illuminate the transcriptional regulatory networks that underlie neuron

201 eurogenomic states, we reconstructed a brain transcriptional regulatory network (TRN) model.

202 derlying nonlinear dynamical system (NDS) of transcriptional regulatory network (TRN) processes.

203 y datasets helps infer a mutually consistent transcriptional regulatory network (TRN) with strong sim

204 we initiated a search of large databases of transcriptional regulatory network (TRN), protein-protei

205 Current efforts to reconstruct transcriptional regulatory networks (TRNs) focus primari

206 Modeling of transcriptional regulatory networks (TRNs) has been incr

207 Identification of transcriptional regulatory networks (TRNs) is of signifi

208 Although the structure of transcriptional regulatory networks (TRNs) is well under

209 Transcriptional regulatory networks (TRNs) program cells

210 o their environment is controlled by complex transcriptional regulatory networks (TRNs), which are st

211 Here, we systematically studied three-node transcriptional regulatory networks (TRNs), with three d

212 pond to changes in their environment through transcriptional regulatory networks (TRNs).

213 However, our understanding of the transcriptional regulatory networks underlying early sta

214 factors is important for reconstructing the transcriptional regulatory networks underlying global ge

215 Our results reveal that a core transcriptional regulatory network used for directing ce

216 e have hypothesized that the construction of transcriptional regulatory networks using a method that

217 a causal inference approach for constructing transcriptional regulatory networks using gene expressio

218 UTR annotations permit reassessment of post-transcriptional regulatory networks, via conserved miRNA

219 To examine the principles of the human transcriptional regulatory network, we determined the ge

220 The identification of transcriptional regulatory networks, which control tissu

221 g accurate predictions is the integration of transcriptional regulatory networks with the correspondi

222 he cross-talk between signaling pathways and transcriptional regulatory networks within cells are ess

223 y would facilitate predictive models of many transcriptional regulatory networks within these genomes

224 ), introduce a range of complex behaviors to transcriptional regulatory networks, yet such properties