ライフサイエンスコーパス: environmental signal

1 developmental sensitivity to nitrogen, a key environmental signal.

2 esponse to presence of a host plant or other environmental signals.

3 sensing systems to appropriately respond to environmental signals.

4 d global regulators in response to different environmental signals.

5 in enhancers in response to cell lineage and environmental signals.

6 as sensors for a wide range of cellular and environmental signals.

7 n is appropriate to myriad developmental and environmental signals.

8 RNAs (sRNAs) in response to stress and other environmental signals.

9 cks which in turn are entrained to different environmental signals.

10 Sensory systems can adapt to different environmental signals.

11 longation is controlled by many hormonal and environmental signals.

12 are dictated by different physiological and environmental signals.

13 es growth regulation by several hormonal and environmental signals.

14 tomatal aperture according to endogenous and environmental signals.

15 th morphologically and in their responses to environmental signals.

16 ontrolling cellular behaviors in response to environmental signals.

17 hose timing is affected by developmental and environmental signals.

18 of growth in bacteria in response to diverse environmental signals.

19 through gene manipulation or encounters with environmental signals.

20 ate chloroplast transcription in response to environmental signals.

21 ynaptic strength and duration in response to environmental signals.

22 differential responses to developmental and environmental signals.

23 ion, and it responds to largely unidentified environmental signals.

24 ssing units to detect and integrate multiple environmental signals.

25 cally distributed ILCPs in response to local environmental signals.

26 n transcriptionally regulated by a number of environmental signals.

27 ally synthesized and degraded in response to environmental signals.

28 ategy used by the cell to respond rapidly to environmental signals.

29 ved in cells responding to developmental and environmental signals.

30 f plant growth in response to endogenous and environmental signals.

31 e happened within the cell or in response to environmental signals.

32 ains, with several chemoreceptors matched to environmental signals.

33 entraining the circadian clocks to external environmental signals.

34 pendent on developmental stage, genotype and environmental signals.

35 nse to complex profiles of interoceptive and environmental signals.

36 -negative bacteria to monitor and respond to environmental signals.

37 GMP synthesizing and degrading enzymes sense environmental signals.

38 ts ability to receive and respond to various environmental signals.

39 r ability to respond specifically to diverse environmental signals.

40 ly used by bacteria to detect and respond to environmental signals.

41 ble plasticity in response to endogenous and environmental signals.

42 hosphatase activity may also be modulated by environmental signals.

43 n modulating animal body size in response to environmental signals.

44 opsis thaliana) is influenced by a number of environmental signals.

45 g respiratory gene expression in response to environmental signals.

46 developmental process regulated by multiple environmental signals.

47 binary conformational change in response to environmental signals.

48 e a potential for sensing a great variety of environmental signals.

49 e responses to a broad range of chemical and environmental signals.

50 nitrifying bacteria in response to different environmental signals.

51 d neurogenesis in response to physiology and environmental signals.

52 activity is controlled by developmental and environmental signals.

53 gnal transduction for enhanced perception of environmental signals.

54 and regulation mediate plastic responses to environmental signals.

55 g and rate of gene expression in response to environmental signals.

56 s structure can be remodelled in response to environmental signals.

57 dormancy of her progeny seed in response to environmental signals.

58 d disease, and response to pharmacologic and environmental signals.

59 cells can metabolically adapt in response to environmental signals.

60 n ability to sense, evaluate, and respond to environmental signals.

61 ment, is regulated tightly by endogenous and environmental signals.

62 estrate their homeostasis and interplay with environmental signals.

63 matic cells in response to developmental and environmental signals.

64 , albeit with altered responses to different environmental signals.

65 pment is highly plastic and is influenced by environmental signals [2].

66 or growth promotion by multiple hormonal and environmental signals [8-11].

67 crossdating must be applied to fully resolve environmental signals, a point we underscore as the fron

68 Effective decision-making can involve using environmental signals about the possible good and bad ou

69 opsis (Arabidopsis thaliana), endogenous and environmental signals acting on the shoot apical meriste

70 These experiments demonstrate how environmental signals acting via FOS/JUN and BAF coordin

71 ulated dynamically by extra-follicular macro-environmental signals, allowing stem cells to adapt to a

72 portant in the evolution of linkages between environmental signals and behavior.

73 gement could allow for information from both environmental signals and cell-to-cell communication to

74 t, oligodendrocyte precursor cells integrate environmental signals and coordinate the activation of t

75 All cells discriminate environmental signals and generate appropriate intracell

76 per illustrates the intricate interaction of environmental signals and genetic factors to regulate fl

77 involved in relaying plant responses to many environmental signals and in regulating ion fluxes.

78 ores their differential capacities to detect environmental signals and influence the inflammatory mil

79 Plant seeds can sense diverse environmental signals and integrate the information to r

80 ion of chemoreceptor (CR) gene expression by environmental signals and internal cues may contribute t

81 s problem, because they lie between external environmental signals and internal physiological respons

82 ator of cell growth that responds to diverse environmental signals and is deregulated in many human d

83 Therefore, autophagy couples environmental signals and metabolic homeostasis to prote

84 transcriptional response regulator to detect environmental signals and modulate gene expression for a

85 hat the functions of CsrABb are dependent on environmental signals and on select residues.

86 n in multidomain proteins by sensing diverse environmental signals and regulating the activity of out

87 Mature leaves detect these environmental signals and relay messages to immature lea

88 the ADS of bacteria in response to specific environmental signals and reveals some notable differenc

89 gulated in response to developmental status, environmental signals and stress is still unknown.

90 meter was determined by a typical pattern of environmental signals and their interactions.

91 ence gene expression and responds to various environmental signals and transcription factors.

92 histidine kinases are believed to recognize environmental signals and transduce this information ove

93 uginosa can sense and respond to a myriad of environmental signals and utilizes a system of small mol

94 lationships between brain anatomy, behavior, environmental signals, and gene expression.

95 ability can compromise cellular responses to environmental signals, and it can also enlarge the reper

96 not abolish the branching response to these environmental signals, and neither signal is dominant ov

97 ed by complex interactions of endogenous and environmental signals, and the knowledge required to ach

98 of heterogeneous soil environments, diverse environmental signals are integrated into root developme

99 challenge because systems-level estimates of environmental signals are only accessible indirectly as

100 Environmental signals are superimposed onto this stable

101 R metabolomics to demonstrate that divergent environmental signals are transduced into common metabol

102 The molecular mechanisms through which environmental signals are translated into changes in gen

103 2/3 complex, which might help to explain how environmental signals are translated into changes in mor

104 structed that can detect and integrate three environmental signals (arsenic, mercury and copper ion l

105 Our data suggest that KaiA directly senses environmental signals as changes in redox state and modu

106 cess that is influenced by genetic variants, environmental signals, as well as the nature of the spec

107 Environmental signals at the site of inflammation mediat

108 puts from intrinsic follicular and extrinsic environmental signals based on universal patterning prin

109 fferentiated subpopulations by interpreting (environmental) signals based on the spatiotemporal commu

110 ceive cytoplasmic signals in addition to the environmental signal blue light.

111 are sensors for a wide range of cellular and environmental signals, but elucidating how these channel

112 in that the pea aphid mother experiences the environmental signals, but it is her offspring that are

113 ptor-like kinases to perceive endogenous and environmental signals, but little is known about their i

114 n Vibrio cholerae is able to respond to host environmental signals by activating transcriptional regu

115 Cells respond to environmental signals by altering gene expression throug

116 late gene expression in response to specific environmental signals by altering the promoter specifici

117 be highly plastic cells that can respond to environmental signals by changing their phenotype and fu

118 suggest that the phosphorelay may normalize environmental signals by the size of the (sub)population

119 In S. epidermidis, disparate environmental signals can affect synthesis of the biofil

120 mporal coding theory where information about environmental signals can be encoded, at least partially

121 Environmental signals can be translated into chromatin c

122 Our findings demonstrate that environmental signals can initiate C. albicans parasexua

123 tches (RNAs that change shape in response to environmental signals), catalysis, and more roles that a

124 larify one mechanism by which very different environmental signals cause common phenotypic changes.

125 he rapA-phrA operon to bifurcate as relative environmental signals change in a developing population.

126 cerebral angiogenesis is regulated by local environmental signals contrast with current models of ce

127 We investigated the impact that environmental signals contribute to cell-to-cell chemica

128 To examine how the environmental signals contribute to the gene transcripti

129 is is an important pathway through which the environmental signals control primary dormancy depth.

130 Environmental signals control the timing of this transit

131 genes play a key role in the integration of environmental signaling controlling dormancy release in

132 The regulatory elements and the environmental signals controlling the expression of Long

133 rphogenesis and shows that developmental and environmental signals converge on a common transcription

134 During this process, multiple genetic and environmental signals coordinately regulate protein expr

135 arget of rapamycin (mTOR) integrates various environmental signals/cues to regulate cell growth, prol

136 degree to which developmental programmes or environmental signals determine physiological phenotypes

137 Temperature during seed set is the dominant environmental signal determining the depth of primary do

138 Thus, the integration of two important environmental signals e.g. phosphate availability and th

139 on to ultimately regulate ABA content or how environmental signals (e.g., light and cold) might direc

140 ater flexibility when faced with conflicting environmental signals (e.g., seasonal changes in photope

141 est that, in addition to a range of chemical environmental signals, EHEC is capable of sensing and re

142 tinct transcriptional responses to different environmental signals elicit distinct modes of assembly

143 control FT expression in response to diverse environmental signals, enabling flowering and other deve

144 e expression in response to highly disparate environmental signals encountered in its hosts.

145 hysiology in multicellular organisms and how environmental signals entrain clocks to geophysical time

146 that it may derive from specific patterns of environmental signals, especially those derived from the

147 sence of light by itself is not a sufficient environmental signal for early seedling development [4,

148 es that extracellular Fe(II) is an important environmental signal for P. aeruginosa.

149 erlapping functions with Cbp1 in recognizing environmental signals for Pmk1 activation.

150 d in cyanobacteria that responds to multiple environmental signals, has recently been implicated in t

151 A large number of factors and environmental signals have been implicated in SPI1 regul

152 ession post-transcriptionally in response to environmental signals; however, the molecular mechanisms

153 obal regulators that can integrate different environmental signals (i.e., glucose starvation and the

154 that provide new insights into ways in which environmental signals impact Th17 cell development and f

155 expansion; however, the mechanisms by which environmental signals impinge upon microtubule organizat

156 hares homology with proteins associated with environmental signaling in some plants, we hypothesized

157 important in the evolution of the control of environmental signalling in plants.

158 that multivariate mutual information between environmental signals in a given environment correlates

159 he moss Physcomitrella patens [2] respond to environmental signals in a similar way to those of flowe

160 central role in coordinating endogenous and environmental signals in Arabidopsis.

161 of the complexity of recreating appropriate environmental signals in culture.

162 It also considers the role of the IGFs as environmental signals in linking resource availability t

163 for cells to integrate genetic programs with environmental signals in order produce an adaptive and c

164 ically sense, process, respond, and adapt to environmental signals in real time.

165 ability of EnvZ to receive and/or respond to environmental signals in the periplasm and modulate its

166 ogether, these results provide evidence that environmental signals in the presence of high dietary sa

167 stem to integrate multiple developmental and environmental signals in the regulation of flowering ini

168 l differentiation, is a response to multiple environmental signals including the cytokine milieu.

169 well positioned in host tissue for detecting environmental signals, including allergens, leading to a

170 igella utilizes adhesins that are induced by environmental signals, including bile salts, encountered

171 ides rapid responses to various cellular and environmental signals, including energy and nutrient ava

172 Seed germination is controlled by environmental signals, including light and endogenous ph

173 synchronized with a plant's surroundings via environmental signals, including light and temperature.

174 mancy and germination potential modulated by environmental signals, including temperature and soil mo

175 Environmental signals induce diverse cellular differenti

176 phagocytes from the bloodstream, yet whether environmental signals influence phagocyte longevity in t

177 evious studies indicated that light is a key environmental signal inhibiting germination in dormant g

178 a key question in the field: how are complex environmental signals integrated to enforce binary, orga

179 tion of the molecular mechanisms that define environmental signal integration is key to the developme

180 eprograming of genes central for transducing environmental signals into cellular responses, leading t

181 grouped 21 of the known SPI1 regulators and environmental signals into distinct classes on the basis

182 macromolecules to rapidly integrate multiple environmental signals into one output.

183 e most prevalent for sensing and transducing environmental signals into the cell.

184 tropical ecosystems and ii) determine which environmental signal is dominating cellulose delta(18)O

185 standing of the perception and processing of environmental signals is needed.

186 tes virulence gene expression in response to environmental signals, is critical for fine-tuning HlyA

187 shape, in relation to the myriad of dynamic environmental signals, is key to understanding normal an

188 tory response to pathogen-derived as well as environmental signals long before Th17 cells have sensed

189 In response to environmental signals, macrophages undergo polarized act

190 Environmental signals may modulate the phosphorylation s

191 se expression is regulated by endogenous and environmental signals, may enhance our understanding of

192 Bacterial chemotaxis is a paradigm for how environmental signals modulate cellular behavior.

193 a tractable system for investigating how an environmental signal modulates stomatal development.

194 havioral response to suit a range of dynamic environmental signals motivates the use of biological ma

195 ydia-infected cells showing the effect of an environmental signal on transcription factor-DNA binding

196 propose that the induction of IGS lncRNA by environmental signals operates as a molecular switch tha

197 Memory can record a transient environmental signal or cell state that is then recalled

198 (sRNAs) are induced in response to specific environmental signals or stresses and act by base-pairin

199 LA proteins mediate the response to multiple environmental signals, our results provide an initial mo

200 This is the first characterized environmental signaling pathway targeted directly to a p

201 Light is an environmental signal perceived by most eukaryotic organi

202 regard, B. burgdorferi must adapt to various environmental signals, pHs, temperatures, and O(2) and C

203 ce the ability of sister cells to respond to environmental signals, potentially altering the behavior

204 dynamics of sediment-transport systems from environmental signal preservation.

205 motaxis has long served as a simple model of environmental signal processing, and bacterial responses

206 into specialized effector subsets based upon environmental signals propagated by the cytokine milieu.

207 Temperature is a key environmental signal regulating plant development, but t

208 Our data suggest that the environmental signals regulating germination are conserv

209 e organismal aging in response to changes in environmental signals remains elusive.

210 The observations that very different environmental signals result in a common phenotype (i.e.

211 is a critical element in the transduction of environmental signal(s) required for HmsD-dependent biof

212 The environmental signal(s) resulting in the increase in exp

213 ater flexibility when faced with conflicting environmental signals.SIGNIFICANCE STATEMENT A master ci

214 ts are expected to be sensitive to different environmental signals such as changes in photoperiod, te

215 Plants perceive environmental signals such as day length and temperature

216 lowering was initiated by the integration of environmental signals such as day-length with the intern

217 pour and photosynthetic gases in response to environmental signals such as drought or high levels of

218 ation feedback loops, which are entrained by environmental signals such as light and temperature to a

219 es flexible organ bending in the presence of environmental signals such as light or gravity.

220 xpression of their respiromes in response to environmental signals such as oxygen, nitrate and nitric

221 ents and must monitor and respond to various environmental signals such as the availability of iron,

222 e ChrS sensor kinase may be responsive to an environmental signal, such as hemin.

223 o perceive and integrate both endogenous and environmental signals, such as carbohydrate and hormonal

224 out how stomatal development is modulated by environmental signals, such as light.

225 ridines in mRNA are regulated in response to environmental signals, such as nutrient deprivation in y

226 Environmental signals, such as pH, temperature, nutrient

227 he level of toxin synthesis is influenced by environmental signals, such as phosphotransferase system

228 T cells transmit environmental signals, such as recognition of antigen, i

229 ility and defines phosphate limitation as an environmental signal that activates ESX-5 secretion.

230 Light is the most important environmental signal that entrains the circadian clock l

231 , its production could serve as an important environmental signal that facilitates species evolution

232 In plants, light is an important environmental signal that induces photomorphogenesis and

233 Light is a ubiquitous environmental signal that many organisms sense and respo

234 carbon donor for photosynthesis but also an environmental signal that regulates stomatal movements a

235 Oxidative stress serves as an important host/environmental signal that triggers a wide range of respo

236 ted that their function is to titrate out an environmental signal that would otherwise promote untime

237 nderlying this switch, the identification of environmental signals that affect switching rates, newly

238 t the polyamines spermine and spermidine are environmental signals that alter bacterial stimulation o

239 This step is controlled by various environmental signals that are integrated at the molecul

240 Here, we have examined the environmental signals that CD8(+) T cells use to localiz

241 west coast estuaries and find heterogeneous environmental signals that characterize each estuary, su

242 Blue light is one of the dominant environmental signals that control stomatal movements in

243 Their production of TSP-1 is regulated by environmental signals that establish a threshold for the

244 The environmental signals that promote matrix synthesis rema

245 URs are key effector outputs of hormonal and environmental signals that regulate plant growth and dev

246 pathogenic potential, and identification of environmental signals that regulate swarming.

247 ement complex computations on the continuous environmental signals that they encounter.

248 e importance of PIF4 in integrating multiple environmental signals, the mechanisms by which PIF4 cont

249 cells integrate complex genetic, immune, and environmental signals, therefore alterations in their fu

250 PI1 T3SS is tightly regulated in response to environmental signals through a variety of global regula

251 e that S. epidermidis is "sensing" disparate environmental signals through the modulation of TCA cycl

252 a icosahedral complex that transmits diverse environmental signals to activate the general stress res

253 scriptional control by sRNAs allows multiple environmental signals to affect synthesis of the transcr

254 are involved in transmitting and transducing environmental signals to biochemical cascades.

255 amycin complex 1 (mTORC1) integrates diverse environmental signals to control cellular growth and org

256 ghlight mechanisms bacteria use to integrate environmental signals to control complex adaptive proces

257 hitecture that responds to developmental and environmental signals to control flowering time and the

258 e pathways by which mature stomata integrate environmental signals to control immature epidermal cell

259 Plants integrate multiple environmental signals to detect and avoid shading from n

260 The main factors incorporating environmental signals to developing hematopoietic cells

261 sensory and interaction modules to propagate environmental signals to effector domains.

262 lt, 3D root architecture is shaped by myriad environmental signals to ensure resource capture is opti

263 secondary metabolite in response to various environmental signals to give it an advantage over its c

264 hat, working with Tbx20, integrated multiple environmental signals to maintain ion channel gene expre

265 ne fish species to illustrate sensitivity of environmental signals to modest dating error rates.

266 Animals integrate physiological and environmental signals to modulate their food uptake.

267 g-presenting dendritic cells (DCs) interpret environmental signals to orchestrate local and systemic

268 Roots navigate through soil integrating environmental signals to orient their growth.

269 f constans1 (SOC1) integrates endogenous and environmental signals to promote flowering.

270 cytokines function in combination with other environmental signals to properly modulate the function

271 making depends on an agent's ability to use environmental signals to reduce uncertainty.

272 rs transduce, store, retrieve, and integrate environmental signals to regulate behavior are poorly un

273 a complex in the TOR pathway that integrates environmental signals to regulate cell growth, prolifera

274 d AHR integrate immunological, metabolic and environmental signals to regulate the immune response.

275 Brucella responds to environmental signals to regulate virulence strategies t

276 The circadian clock perceives environmental signals to reset to local time, but the un

277 ss information encoded via developmental and environmental signals to survive and reproduce.

278 of the growing root, perceives and transmits environmental signals to the inner root tissues.

279 bacteriophytochrome-like protein CikA passes environmental signals to the oscillator by directly bind

280 s a 1.8-MDa cytoplasmic complex that conveys environmental signals to the sigma(B) stress factor of B

281 responsible for channeling physiological and environmental signals to their cellular responses.

282 ircuitries coupling extracellular quorum and environmental signals to transcription of T4SS genes are

283 cess controlled by intrinsic programs and by environmental signals transduced by a variety of plant h

284 The genetic loci sensitive to predictable environmental signals underlie local adaptation.

285 and continuously sense, process and react to environmental signals using their inherent signaling and

286 ld modulate the clock response to changes in environmental signals, we identified in a previous large

287 rmanent developmental changes vs. reversible environmental signals, we measured respiratory-related n

288 ells perceive a wide variety of cellular and environmental signals, which are often processed combina

289 tem for disentangling responses to different environmental signals, which balance carbon gain against

290 s the response of many Enterobacteriaceae to environmental signals, which include modifications of li

291 a role for metabolic activity in integrating environmental signals with activation-induced gene-expre

292 Sensory neurons detect environmental signals with dendritic processes near the

293 rlying mechanisms by which plants coordinate environmental signals with endogenous pathways are not f

294 s indicate the benefits for GAS to integrate environmental signals with intercellular communication p

295 bout the intersecting pathways that link the environmental signals with rhythms in cellular metabolis

296 opulation density with other physicochemical environmental signals within the broader c-di-GMP signal

297 an organism to respond to developmental and environmental signals without genetic changes.

298 oute cells to divergent fates in response to environmental signals without modification of native gen

299 ormation, and other processes in response to environmental signals, yet little is known about the fun

300 y) is governed by a variety of antigenic and environmental signals, yet the observed clone sizes foll