ライフサイエンスコーパス: environmental cue

1 d physical state, or the use of stress as an environmental cue.

2 emical program that is executed following an environmental cue.

3 rained to discriminate its presence using an environmental cue.

4 on the higher predictive ability of progeny environmental cues.

5 strategy used by many organisms to adjust to environmental cues.

6 les under constant conditions without cyclic environmental cues.

7 oductive tissues in response to systemic and environmental cues.

8 ion formation is not a response to different environmental cues.

9 to modulate carRS expression in response to environmental cues.

10 ns is fundamental for optimal adaptations to environmental cues.

11 n area but selectively reactive to different environmental cues.

12 solely from sensory information representing environmental cues.

13 f damaged murine mucosa in response to local environmental cues.

14 y alter their phenotype in response to local environmental cues.

15 stress perception and fast cell responses to environmental cues.

16 itiate growth stochastically, independent of environmental cues.

17 lopmental processes, as well as responses to environmental cues.

18 nsduce, process and transmit light-dependent environmental cues.

19 e developmental events driven in response to environmental cues.

20 rsor responsive to nutrient status and other environmental cues.

21 recombination fraction in rapid response to environmental cues.

22 s to coordinate OM remodeling in response to environmental cues.

23 tion or by external sensory information from environmental cues.

24 r growth regulator that responds to multiple environmental cues.

25 uously adapt gene expression to internal and environmental cues.

26 abolism is crucial for T cells responding to environmental cues.

27 te gene expression in response to social and environmental cues.

28 is, in fact, highly plastic and sensitive to environmental cues.

29 intenance of polarity in the face of complex environmental cues.

30 genes, and strikingly different responses to environmental cues.

31 of metabolic reactions, gene regulation, and environmental cues.

32 es metabolic reactions, gene regulation, and environmental cues.

33 rcadian clock control and acute responses to environmental cues.

34 scriptional program of a cell in response to environmental cues.

35 une system and its response to microbial and environmental cues.

36 t adapt rapidly to changes in the meaning of environmental cues.

37 ry pathways to synchronize flowering time to environmental cues.

38 expression and cell phenotype in response to environmental cues.

39 rted in a context-dependent manner by strong environmental cues.

40 ulators, which mediate adaptive responses to environmental cues.

41 thway genes in response to physiological and environmental cues.

42 ry roles in shaping behavioural responses to environmental cues.

43 fast response and slow adaptation to varying environmental cues.

44 activity is affected by local, systemic, and environmental cues.

45 ical membranes in response to nutritional or environmental cues.

46 ent their direction of growth in response to environmental cues.

47 of brain circuits in responding to adaptive environmental cues.

48 ng neural plasticity and keen sensitivity to environmental cues.

49 e plant growth, development and responses to environmental cues.

50 lume to control the pore size in response to environmental cues.

51 ique gene expression programs in response to environmental cues.

52 iently control FOXP3 activity in response to environmental cues.

53 te to their correct locations in response to environmental cues.

54 n sensitivity according to developmental and environmental cues.

55 for accurate collective reactions to shared environmental cues.

56 ks of respiratory tularemia are triggered by environmental cues.

57 ted by the macrophage genetic background and environmental cues.

58 mplex and are regulated by many internal and environmental cues.

59 o probe the responses of individual cells to environmental cues.

60 ulate transcriptional responses and adapt to environmental cues.

61 r functions in response to developmental and environmental cues.

62 constant conditions, even in the absence of environmental cues.

63 preparing lymphoid progenitors to respond to environmental cues.

64 ee distinct phenotypic phases in response to environmental cues.

65 at predominantly affects genes responsive to environmental cues.

66 B enable B cells to appropriately respond to environmental cues.

67 ering CD8 T cells exquisitely dependent upon environmental cues.

68 tly postembryonic and tuned in to respond to environmental cues.

69 ly diverse, ranging from complete genetic to environmental cues.

70 ivate genes in response to a wide variety of environmental cues.

71 rowth and metabolism in response to multiple environmental cues.

72 ng appropriate responses to developmental or environmental cues.

73 esponses can be altered by developmental and environmental cues.

74 mechanism to improve fitness in response to environmental cues.

75 and development as well as plant response to environmental cues.

76 t coordinates gene expression in response to environmental cues.

77 ral decisions relative to internal state and environmental cues.

78 directed behavior in response to appropriate environmental cues.

79 investigate immune cells faced with various environmental cues.

80 ) signaling in response to developmental and environmental cues.

81 of MTs can become stabilized in response to environmental cues, acquiring distinguishing posttransla

82 When pathogens enter the host, sensing of environmental cues activates the expression of virulence

83 tions between group members' observations of environmental cues, adjust strategy as a function of cha

84 rity and couples effector differentiation to environmental cues after antigenic stimulation.

85 produced in response to developmental and/or environmental cues and act via cognate cytokine receptor

86 in a highly sensitive and dynamic manner to environmental cues and alterations in kinase function.

87 es have remarkable plasticity in response to environmental cues and are able to acquire a spectrum of

88 e presence and absence of alcohol-associated environmental cues and contexts.

89 The oscillations are not a response to environmental cues and continue for at least three cycle

90 ts, transgenerational epigenetic influences, environmental cues and developmental noise, which are ra

91 Associations between environmental cues and food are readily formed because o

92 ress granules form in response to particular environmental cues and have been linked to a variety of

93 ferent sources, coupled with the notion that environmental cues and inflammatory stimuli can sculpt a

94 , bridging competent, conformation driven by environmental cues and interaction partners.

95 s a fundamental paradigm for how cells sense environmental cues and interpret these signals to regula

96 However, the environmental cues and molecular mechanisms that trigger

97 On the basis of environmental cues and molecular mediators, these cells

98 y dampened during chronic infection, yet the environmental cues and molecular pathways that influence

99 Some of the same environmental cues and molecular pathways utilized to ge

100 Learned associations between environmental cues and morphine use play an important ro

101 To test the roles of responses to environmental cues and sexual behaviors in longevity reg

102 velopment and in the adult, highlighting the environmental cues and signalling pathways that control

103 e LA-MeA circuit impaired valuation of these environmental cues and subsequent ability to use a cue t

104 s mediated by interactions between extrinsic environmental cues and the intrinsic oscillators of immu

105 ping gene expression profiles in response to environmental cues and the operating molecular mechanism

106 echanisms in response to morphine-associated environmental cues and the underlying alterations in spi

107 intracellular Ca(2+) that were entrained by environmental cues and timed by molecular clocks.

108 -assisted carbohydrate allocation that links environmental cues and tree phenology.

109 hardiness in situ are dependent on effective environmental cues, and (iv) movement of seed sources fr

110 from other tissues, cycles robustly without environmental cues, and affects circadian clock regulati

111 s growth factors, extracellular matrices, 3D environmental cues, and modes of multicellular associati

112 t in the parasitoid S. pupariae under varied environmental cues, and reveal the most favourable condi

113 e wing morphs develop in response to various environmental cues, and that the response to these cues

114 robial ecosystem, which is readily shaped by environmental cues; antibiotic-induced disruption of thi

115 implicated in systemic responses to various environmental cues are discussed.

116 Local environmental cues are indispensable for axonal growth a

117 ally regulated in response to cell cycle and environmental cues are only beginning to emerge.

118 by which the placenta senses and responds to environmental cues are poorly understood.

119 asticity and tactical responses to immediate environmental cues are reflected in the decision of whet

120 ) mechanistic insights into how temporal and environmental cues are transmitted and integrated within

121 Environmental cues are transmitted to the interior of th

122 on of oppA but is not influenced by the same environmental cues as the promoter upstream of oppB.

123 However, exposure to environmental cues associated with drug use often thwart

124 eed-sensing neurons condition preference for environmental cues associated with nutrient or water ing

125 he timing of migration departure is based on environmental cues at distant non-breeding sites.

126 egs to control inflammation may be shaped by environmental cues available to them.

127 In response to environmental cues, bacteria are able to orchestrate wid

128 asmodesmal flux is regulated by a variety of environmental cues but the downstream signalling pathway

129 quired for the tropic responses of hyphae to environmental cues, but the regulatory link between thes

130 , each enzyme senses and responds to cognate environmental cues by alteration of enzymatic activity.

131 einforces developmental fates in response to environmental cues by modulating autocrine and paracrine

132 rate that primary T cells respond to various environmental cues by regulating ribosome biogenesis and

133 rotein kinases control cellular responses to environmental cues by swift and accurate signal processi

134 ndings establish the link between sensing of environmental cues by the external proteins and activati

135 s can enable mitochondria to use light as an environmental cue, by absorbing light and transferring t

136 In the intestine, diverse environmental cues can be sensed by immune cells, which

137 city for human ILC2 and further suggest that environmental cues can dictate ILC phenotype and functio

138 a critical period in early life during which environmental cues can set an individual on a trajectory

139 icularly important are findings that certain environmental cues can tilt the delicate balance between

140 here small responses of individuals to local environmental cues cause spontaneous changes in the coll

141 T cell populations and discuss the potential environmental cues, cellular factors, and molecular medi

142 nts can protect cell identity by sensing key environmental cues central to both cell identity formati

143 Diverse environmental cues converge on and are integrated by the

144 benefited by sensory pathways that recognize environmental cues corresponding to stress and nutrient

145 One such environmental cue could be low oxygen, which often accom

146 ons between the drug's rewarding effects and environmental cues, creating powerful, enduring triggers

147 R) is emerging as an important integrator of environmental cues critical for the regulation of T cell

148 r peripheral T cells in response to host and environmental cues, culminating in induction of the tran

149 The initial recognition integrates environmental cues derived from pathogen-associated mole

150 Taken together, our results indicate that environmental cues dictate the instability of the Th9 ph

151 In temperate zones, the primary environmental cue driving seasonal reproductive cycles i

152 expression of cold hardiness is a product of environmental cues (E), genetic differentiation (G), and

153 onstrate a common mechanism by which diverse environmental cues (e.g., certain short-chain fatty acid

154 tween genetic susceptibility and exposure to environmental cues (e.g., food marketing); however, the

155 chloroplast protein import is responsive to environmental cues, enabling dynamic regulation of the o

156 reover, exposure of V. cholerae to different environmental cues encountered by the bacterium in its l

157 icates dominance of neural activity by local environmental cues even when these conflicted with the g

158 formation on maternal effects by showing how environmental cues experienced by one generation can tra

159 dently each life stage can respond to shared environmental cues, focusing on vernalization, in Arabid

160 tion are dynamically regulated to respond to environmental cues for clonal expansion and memory cell

161 Daily light cycles are well known environmental cues for setting circadian rhythms.

162 Using environmental cues for the prediction of future events i

163 ramework for characterizing the influence of environmental cues, genes and neural activity on behavio

164 Although several environmental cues have been implicated in the timing of

165 A number of diverse environmental cues have been linked to B lymphocyte diff

166 stically modulate development in response to environmental cues, have contributed to repeated cooptio

167 species to obtain, interpret and respond to environmental cues, highly novel environmental acoustics

168 Our results show that morphine pairing with environmental cues (ie, the conditioned place preference

169 sponsive medial entorhinal neurons depend on environmental cues in a more complex manner than previou

170 n both during development and in response to environmental cues in all organisms with methylated DNA,

171 exibility in responding to developmental and environmental cues in health and disease.

172 ing appropriate Ab responses is regulated by environmental cues in lymphoid tissues draining the site

173 ations affect gene expression in response to environmental cues in marine environments.

174 ze the use of host space for growth and that environmental cues in the host can regulate a developmen

175 in the neobladder not only implicates local environmental cues in the shaping and maintenance of the

176 xpress considerable plasticity responding to environmental cues, in part, through subcellular mRNA re

177 scription factor, SOX10, in combination with environmental cues including WNT activation.

178 s a master growth regulator that senses many environmental cues, including amino acids.

179 cell to achieve combinatorial integration of environmental cues, including Boolean response programs,

180 blakesleeanus are single cells that react to environmental cues, including light, but the mechanisms

181 c and its expression is modulated by various environmental cues, including temperature and carbon sou

182 These factors, in combination with environmental cues, induce a stable intrinsic pluripoten

183 localization of cells is important as local environmental cues influence both phenotype and effector

184 by the density of infection, suggesting that environmental cues influence the dynamics of the pathoge

185 Thus, environmental cues instruct TRMs to express CRIg, which

186 d epitope specificity are shaped by multiple environmental cues integrated by dendritic cell "hubs" a

187 ling pathways are responsible for converting environmental cues into discrete intracellular events.

188 by which cells can encode information about environmental cues into distinct signaling dynamics thro

189 ever, the mechanisms involved in translating environmental cues into reproductive outcomes remain unk

190 s are established, maintained and altered by environmental cues is an area of considerable and growin

191 Sensing its biotic and abiotic environmental cues is critical to the survival and repro

192 The ability to orient oneself in response to environmental cues is crucial to the survival and functi

193 mic ABA concentration changes in response to environmental cues is essential for understanding ABA ac

194 ally different cellular roles in response to environmental cues is unknown.

195 s are genetically programmed or triggered by environmental cues is unknown.

196 ion during an individual life span driven by environmental cues - is an exceedingly rare sexual syste

197 ular memory, which records developmental and environmental cues, is epigenetics.

198 Following diverse developmental and environmental cues, jasmonate is produced, conjugated to

199 Age and phenotype-specific environmental cues (lactose exposure after weaning) indu

200 signals are typically similar to attractive environmental cues like food [3-6], which amplifies thei

201 This mechanism explains how environmental cues may act upon the florigen genes in a

202 tion and how Treg subsets respond to ranging environmental cues may be keys to reconciliation.

203 dify their behavioral responses according to environmental cues, metabolic demands, and physiological

204 ity of shaping their function in response to environmental cues, namely TGF-beta and IL-4, adopting a

205 roe deer is linked to its inability to track environmental cues of variation in resource availability

206 , yet little is known about the influence of environmental cues on the development or expression of t

207 study is the first to quantify the effect of environmental cues on the human epigenome and show that

208 PI-1 expression with anatomical location via environmental cues, one of which is bile, a complex dige

209 mpatible phenotypes, which vary according to environmental cues or exposures as well as stochastic pr

210 h whether grid firing is determined by local environmental cues, or provides a coherent global repres

211 Our data indicate that environmental cues perceived by the female nervous syste

212 rs such as social context, responsiveness to environmental cues, personality traits, neurochemical an

213 activity, attenuates not only the ability of environmental cues predictive of reward availability to

214 mote reward seeking, but also the ability of environmental cues predictive of reward omission to supp

215 Here, we show that lung environmental cues program recently recruited central-li

216 abolism is further interconnected with other environmental cues provided by the day-night cycles impo

217 Environmental cues provoke rapid transitions in gene exp

218 Environmental cues received during development and by th

219 ocus in the field has been to understand how environmental cues regulate CTL differentiation on a gen

220 of stomatal patterning to many exogenous and environmental cues remain less clear.

221 grid firing patterns were dominated by local environmental cues, replicating between the two compartm

222 yte recruitment into the lung in response to environmental cues represents a key factor for the induc

223 ranscription factor PPAR-gamma; however, the environmental cues required for their differentiation ar

224 smart materials that assemble in response to environmental cues requires strategies that can discrimi

225 nflammatory properties and depend on similar environmental cues, reside in the epithelium.

226 The cellular origin and the environmental cues responsible for this ectopic calcific

227 arguing that their responses to neuronal and environmental cues shape form and function in dynamic wa

228 This decoupling of previously reliable environmental cues shifts adaptive landscapes, favors no

229 Understanding how these organisms respond to environmental cues should provide insights into the mech

230 s for a dynamic integration of endogenous or environmental cues signaled by BRs into cell fate decisi

231 ar environmental conditions and despite 24-h environmental cues, social synchronization can generate

232 nsport of proteins and lipids in response to environmental cues such as amino acid and cholesterol le

233 developmental signal and as an integrator of environmental cues such as drought and cold.

234 Hence, lysosomal adaptation to environmental cues such as nutrient levels requires mTOR

235 asmatic nucleus synchronizes to light, while environmental cues such as temperature and feeding, out

236 flowering is often coordinated with seasonal environmental cues such as temperature and photoperiod.

237 arget of rapamycin (mTOR) integrates various environmental cues such as the presence of antigen, infl

238 ToxR is thought to be responsive to various environmental cues, such as bile salts and alkaline pH,

239 adipocytes and emerge in response to certain environmental cues, such as chronic cold exposure, a pro

240 found metabolic reprogramming in response to environmental cues, such as hypoxia or nutrient alterati

241 xin-BR signaling, which is also triggered by environmental cues, such as light, to promote cell expan

242 y, enabling them to respond to and cope with environmental cues, such as limited availability of phos

243 ey pre- and post-natal events that integrate environmental cues, such as molecular signals from the g

244 ar regions that are thought to interact with environmental cues, such as Na(+), Cl(-), protons, prote

245 signal transduction pathways in coordinating environmental cues, such as nutritional status and mecha

246 that like foraging animals, T cells adapt to environmental cues, suggesting that adaption is a fundam

247 thelial cells may serve as a tissue-specific environmental cue that initiates reactivation in B cells

248 of alcohol relapse is the craving caused by environmental cues that are associated with alcohol.

249 ctively protect cell identity in response to environmental cues that confer functional plasticity.

250 metabolites produced by microbes may provide environmental cues that contribute to pathogen recogniti

251 We are only beginning to understand the environmental cues that contribute to transient retentio

252 the importance of understanding the specific environmental cues that drive species' phenological resp

253 ase in nonobese diabetic (NOD) mice, but the environmental cues that govern macrophage polarization a

254 rcellular signaling, and stress responses to environmental cues that have been maintained by extant p

255 ury results in the generation of a myriad of environmental cues that macrophages respond to by changi

256 d what to avoid, involves assigning value to environmental cues that predict positive and negative ev

257 In response to environmental cues that promote IP3 (inositol 1,4,5-tris

258 A comprehensive understanding of the environmental cues that regulate FCSC fate decisions may

259 Furthermore, these data suggest that environmental cues that regulate RBP-J expression/functi

260 during the infection cycle, and the dominant environmental cues that shape this response.

261 equired for using social cues to learn about environmental cues that signal imminent threats.

262 orms matrix-enclosed biofilms in response to environmental cues that to date remain poorly defined.

263 s important to understand the conditions and environmental cues that were driving this specific bloom

264 Subsequently, in response to environmental cues the PPR is further subdivided into pl

265 In response to environmental cues, the mitogen-activated protein kinase

266 tudy reveals that, in response to particular environmental cues, the role of PDCD4 is up-regulated an

267 bidirectional COPI transport is modulated by environmental cues through CDC42.

268 ing of oligodendrocytes results from sensing environmental cues through membrane-bound receptors and

269 ulate their swimming behavior in response to environmental cues through the CheA/CheY signaling pathw

270 nal benefits, including defense responses to environmental cues throughout the host plant, which, in

271 t life stages frequently respond to the same environmental cue to regulate development so that each l

272 ave developed strategies to sense bile as an environmental cue to regulate virulence genes during inf

273 ls their specialization in response to local environmental cues to contribute to the development and

274 combine relevant information from different environmental cues to develop integrated phenotypes.

275 discuss how phagocytosis is integrated with environmental cues to drive appropriate responses.

276 rs, or "master splicing factors," respond to environmental cues to establish and maintain tissue tran

277 Bacteria rely on environmental cues to influence biofilm development, inc

278 photoautotrophic sessile organisms that use environmental cues to optimize multiple facets of growth

279 Evidence suggests that Tregs respond to environmental cues to permit or suppress inflammation.

280 The ability to use environmental cues to predict rewarding events is essent

281 is a crucial signaling node that integrates environmental cues to regulate cell survival, proliferat

282 These data define novel mechanisms linking environmental cues to the acquisition of a pro-inflammat

283 Among these, mechanisms that couple environmental cues to the regulation of protein translat

284 kinase complex, which connects metabolic and environmental cues to the vacuolar delivery of autophagi

285 OFC and NAC were impaired in learning to use environmental cues to withhold a response, an effect tha

286 tial flexibility, most likely in response to environmental cues, to adopt defined immune profiles tha

287 However, there is limited knowledge on how environmental cues translate into dendrite initiation or

288 ular identity is shaped by developmental and environmental cues under homeostasis and stress conditio

289 In summary, warming blurred the environmental cue used by mayflies to tune their phenolo

290 on, and the relative importance of different environmental cues used for tracking the seasons might d

291 ting their direction after displacement, the environmental cues used to achieve this remain elusive.

292 tical structures involved in the learning of environmental cues used to predict motivationally releva

293 adR, and provides a link between nutritional environmental cues utilized by spirochaetes to adaptatio

294 cin (mTOR) senses and incorporates different environmental cues via the two signaling complexes mTOR

295 ologically regulated dormancy in response to environmental cues was present at the origin of seed pla

296 vels resulting from genetic polymorphisms or environmental cues will govern tissue DC numbers and, th

297 Sensory regions of the brain integrate environmental cues with copies of motor-related signals

298 enetic regulation can integrate a variety of environmental cues with developmental signals.

299 K12 differ in their response to cellular and environmental cues, with the allele from the Cape Verde

300 Pol III regulation is thus sensitive to environmental cues, yet a diurnal profile of Pol III tra