ライフサイエンスコーパス: cell fate determination

1 ctor, Nkx2.1, for lung epithelial progenitor cell fate determination.

2 layers to regulate embryonic development and cell fate determination.

3 ed with embryonic stem cell self-renewal and cell fate determination.

4 maintaining immune homeostasis by regulating cell fate determination.

5 ells, as well as its function in C. albicans cell fate determination.

6 t connects DNA damage signaling to SirT1 and cell fate determination.

7 on is a classical embryologic model to study cell fate determination.

8 provides a prototypic example of collective cell fate determination.

9 to which endogenous secretion contributed to cell fate determination.

10 for Nup210 in gene expression regulation and cell fate determination.

11 l regulatory network that guides progressive cell fate determination.

12 al role in controlling embryonic neural stem cell fate determination.

13 gulatory T cells (T(reg) cells) and controls cell fate determination.

14 nes are involved in embryonic patterning and cell fate determination.

15 om proliferation, death and morphogenesis to cell fate determination.

16 ors are cell surface molecules essential for cell fate determination.

17 , tumor suppression, and monocyte/macrophage cell fate determination.

18 tin with proper heterochromatin assembly and cell fate determination.

19 bryo development is a process of progressive cell fate determination.

20 in cells, leads to a complete loss of proper cell fate determination.

21 nected to cell signaling, cell survival, and cell fate determination.

22 e associated with tissue differentiation and cell fate determination.

23 sicle initiates morphogenesis and prosensory cell fate determination.

24 ng a reciprocal negative regulation of CD4 T cell fate determination.

25 ished mechanisms of early neural and retinal cell fate determination.

26 determination cascade involved in embryonic cell fate determination.

27 al progenitor cells is required for neuronal cell fate determination.

28 on are crucial for lineage specification and cell fate determination.

29 ave been shown to play a significant role in cell fate determination.

30 the timing of precursor differentiation and cell fate determination.

31 l-basal cell polarity to Notch signaling and cell fate determination.

32 role for Ctr1 during amphibian and mammalian cell fate determination.

33 plasticity and dissect mechanisms underlying cell fate determination.

34 ifferent, but overlapping aspects of retinal cell fate determination.

35 ulation of epigenetic information influences cell fate determination.

36 tes this act to control cleavage pattern and cell fate determination.

37 ins couple leaf morphogenesis with epidermal cell fate determination.

38 for Notch signaling, a pathway critical for cell fate determination.

39 esting an important role of phytohormones in cell fate determination.

40 for delineating early steps in photoreceptor cell fate determination.

41 through meiosis, cytoskeletal regulation and cell fate determination.

42 resolution of mixed lineage patterns during cell fate determination.

43 egulatory molecules that orchestrate B and T cell fate determination.

44 ession in HPC play a key role in promoting B cell fate determination.

45 on by chromatin remodeling factors underlies cell fate determination.

46 for the native signaling process in neuronal cell fate determination.

47 essor complex Mi-2/NuRD, for BCL-6-dependent cell fate determination.

48 on did not affect neural induction or neural cell fate determination.

49 shment of H3K27me3-mediated silencing during cell fate determination.

50 ogenitor cells could play important roles in cell fate determination.

51 upts pigmentation, somitogenesis and retinal cell fate determination.

52 and p17Xic3 have an activity that influences cell fate determination.

53 hancer-mediated transcription attenuation in cell fate determination.

54 emodeling and unravel the complexity of stem cell fate determination.

55 f signal transduction in cells are vital for cell fate determination.

56 ging from metabolism to redox homeostasis to cell fate determination.

57 cycle to allow ample time for DNA repair and cell fate determination.

58 provides new insights into the mechanisms of cell fate determination.

59 aste cell proliferation, differentiation and cell fate determination.

60 the proteomic dynamics during the process of cell fate determination.

61 om FGF signaling to balance self-renewal and cell fate determination.

62 s that couple metabolism to pluripotency and cell fate determination.

63 ritical to transcriptional reprogramming and cell fate determination.

64 shment of EpiLCs, the epigenome is reset for cell fate determination.

65 utrient-triggered mitochondrial dynamics and cell fate determination.

66 3K9me3 is reorganized during development and cell fate determination.

67 in cell proliferation, differentiation, and cell fate determination.

68 f the Shh morphogen gradient and influencing cell fate determination.

69 ole in epigenetic control of SE activity for cell fate determination.

70 ory network (GRN), corresponding to specific cell fate determination.

71 r, gene expression, chromatin structure, and cell fate determination.

72 and cadherins required for NC migration and cell fate determination.

73 ave emerged as important factors influencing cell fate determination.

74 anisms modelling lineage differentiation and cell-fate determination.

75 , chromosome copy number could contribute to cell-fate determination.

76 rgoes lineage-specific reorganization during cell-fate determination.

77 ivation of gene expression during vertebrate cell-fate determination.

78 lated by ADAM10 is critical to hematopoietic cell-fate determination.

79 tat4 to achieve complete IL-12-dependent Th1 cell-fate determination.

80 te neuroblast formation, cell-cycle exit and cell-fate determination.

81 family involved in chromatin remodeling and cell-fate determination.

82 cts of cancer cell biology: inflammation and cell-fate determination.

83 both the A and B classes of genes in vulval cell-fate determination.

84 vation of quiescent cells and/or a switch in cell-fate determination.

85 ll protrusion, migration, proliferation, and cell-fate determination.

86 on of translation is an important feature of cell-fate determination.

87 to explore the functional role of Jagged in cell-fate determination.

88 signaling activation and cause a gradient of cell fate determination along the direction of flow.

89 cts of misexpressing NeuroD genes on retinal cell fate determination also suggested shared and diverg

90 Cell fate determination and cell migration are two essen

91 ll form the basis for understanding not only cell fate determination and cellular homeostasis in the

92 TGFbeta signaling in the earliest stages of cell fate determination and demonstrate an interconnecti

93 of various adult stem cells, but its role in cell fate determination and differentiation during liver

94 ple independent pathways to promote neuronal cell fate determination and differentiation.

95 Sox1 appears to play a direct role in neural cell fate determination and differentiation.

96 Numb functions in progenitor cell fate determination and early development, but it is

97 e most critical genes acting in the steps of cell fate determination and early differentiation of var

98 es for Wnt/beta-catenin signaling in granule cell fate determination and for Wnt/PCP signaling in con

99 ce, supporting distinct pathways for human T cell fate determination and homeostasis.

100 croRNAs (miRNAs) are important regulators of cell fate determination and homeostasis.

101 egulating protein Lis1 in hematopoietic stem cell fate determination and in leukemogenesis.

102 Notch1 regulates binary cell fate determination and is critical for angiogenesis

103 ing cascade plays a crucial role in myogenic cell fate determination and lineage progression during t

104 wn to modulate developmental events, such as cell fate determination and maintenance in many species,

105 volutionarily conserved process critical for cell fate determination and maintenance of gene expressi

106 Notch receptors mediate binary cell fate determination and may regulate the function of

107 conserved across metazoans, including neural cell fate determination and migration, axon guidance, sy

108 2 and morphogenesis (RAM) network integrates cell fate determination and morphogenesis.

109 requires coordination of cell proliferation, cell fate determination and morphogenetic movements.

110 gions associated with key factors central to cell fate determination and neural tube patterning.

111 atin and the signaling pathways that control cell fate determination and organism development.

112 dentified HLH protein GCIP/CCNDBP1 modulates cell fate determination and plays a role in hepatocyte g

113 ssential players in development by acting on cell fate determination and progression towards cell dif

114 criptional dominance' model of photoreceptor cell fate determination and provide insights into the pa

115 beta-catenin and are critically involved in cell fate determination and stem/progenitor self-renewal

116 hlight the importance of metabolic cues in T cell fate determination and suggest that metabolic modul

117 es a synthetic biology framework to approach cell fate determination and suggests a landscape-based e

118 s the sex determination signal TRA-1 and the cell fate determination and survival signal UNC-86 to co

119 tin proteasome pathway is necessary for hair cell fate determination and survival.

120 d fibroblastic cell-cell interactions affect cell fate determination and the organization of skeletal

121 ipheral taste system: embryonic chemosensory cell fate determination and the specification of lingual

122 gulation of gene expression is essential for cell fate determination and tissue development.

123 events during animal development, regulating cell fate determination and tissue growth in a variety o

124 enabled us to identify key genes involved in cell fate determination and to obtain new insights about

125 y has essential roles in cell proliferation, cell fate determination and tumorigenesis by regulating

126 ly dividing cell population just upstream of cell fate determination and updates previous models of s

127 h signaling is a cellular pathway regulating cell-fate determination and adult tissue homeostasis.

128 onsider our current understanding of cardiac cell-fate determination and cardiogenesis--largely deriv

129 ine 27 (H3K27me3) regulates gene repression, cell-fate determination and differentiation.

130 We elucidate the role of Jagged in cell-fate determination and discuss its possible implica

131 ytic-independent role of DOT1L in modulating cell-fate determination and in transcriptional elongatio

132 st histone demethylase discovered, regulates cell-fate determination and is overexpressed in multiple

133 damentally changed our view on developmental cell-fate determination and led to a cascade of technolo

134 for ERECTA-mediated signaling in growth and cell-fate determination and reveal a role for ERECTA-LIK

135 Ddx3x as essential for hindbrain patterning, cell fate determination, and as a tumor suppressor gene

136 gehog (Shh) signaling is crucial for growth, cell fate determination, and axonal guidance in the deve

137 target transcription factors that influence cell fate determination, and biological functions of miR

138 of the WNT7A-PAX6 axis in corneal epithelial cell fate determination, and point to a new strategy for

139 s essential for many aspects of development, cell fate determination, and tissue homeostasis.

140 ritical to ensure proper lineage commitment, cell fate determination, and ultimately, organogenesis.

141 al key transcription factors that regulate T cell fate determination are methylated on arginine.

142 Alternate models of Notch pathway control of cell fate determination are presented.

143 ring development, extracellular cues guiding cell fate determination are provided by morphogens.

144 he functions of Ras in regulating growth and cell-fate determination are separable.

145 signaling has been described in neuro/glial cell fate determination as well as in modulating neuroge

146 NOTCH receptors have been implicated in cell fate determination, as well as maintenance and diff

147 In a retinal cell fate determination assay, both p16Xic2 and p17Xic3

148 maintenance, but may have a critical role in cell-fate determination at the initiation stage.

149 echanisms that underlie proneural induction, cell fate determination, axonal targeting, dendritic bra

150 ro-RNAs (miRNAs) are important in regulating cell fate determination because many of their target mRN

151 Cell-fate determination between the three phenotypes is

152 e and cellular metabolism both contribute to cell fate determination, but their interplay remains poo

153 Thus, excess beta-catenin can alter cell fate determination by both direct and paracrine mec

154 Cell fate determination by lateral inhibition via Notch/

155 date, the mechanisms underlying multipotent cell fate determination by retinal progenitors remain po

156 g efforts to link copy number variation with cell fate determination by viruses, dynamics of syntheti

157 to demonstrate that stochastic and permanent cell fate determination can be achieved through initiali

158 Several models of cell fate determination can be invoked to explain how si

159 roblast 5-6 by simultaneously activating two cell fate determination cascades and a sub-temporal regu

160 Wnt signaling is a major pathway regulating cell fate determination, cell proliferation and cell mov

161 idered a passive component or "passenger" of cell-fate determination, cell metabolism is now starting

162 upporting a model of a stochastic process of cell fate determination coupled with dynamic patterns of

163 lates multiple cellular processes, including cell fate determination, development, differentiation, p

164 ent consists of several processes, including cell fate determination, differentiation, and maturation

165 of genes involved in cell cycle progression, cell fate determination, DNA damage repair, and apoptosi

166 ulation, the importance of cic in regulating cell-fate determination downstream of Ras appears to var

167 e the relationship between PCP signaling and cell fate determination during asymmetric division of ne

168 es regulated by Groucho, thereby controlling cell fate determination during development.

169 y conserved signaling pathway that regulates cell fate determination during development.

170 ption factors regulate tissue patterning and cell fate determination during development; however, exp

171 players in the control of proliferation and cell fate determination during differentiation.

172 ver the AMPK pathway as a novel regulator of cell fate determination during differentiation.

173 ptional factors that play essential roles in cell fate determination during early embryogenesis and o

174 ghly conserved signaling cascade crucial for cell fate determination during embryogenesis.

175 e Notch signal transduction pathway controls cell fate determination during metazoan development.

176 he Dictyostelium homologue of GSK3 (gskA) in cell fate determination during morphogenesis of the frui

177 damage signaling have all been implicated in cell fate determination during neurogenesis, our finding

178 igand for the EMS1 receptor kinase to signal cell fate determination during plant sexual reproduction

179 Notch signaling pathway mediates cell-fate determination during embryonic development, wo

180 The Hedgehog (Hh) pathway is required for cell-fate determination during the embryonic life, as we

181 mb and Numbl in the control of myoepithelial cell fate determination, epithelial identity, and lactog

182 The mechanisms that specify photoreceptor cell-fate determination, especially as regards to short-

183 n modifications, but their specific roles in cell fate determination events are poorly understood.

184 The cell fate determination factor DACH1 plays a key role in

185 The cell fate determination factor Dachshund was cloned as a

186 Dachshund homolog 1 (DACH1), a key cell fate determination factor, contributes to tumorigen

187 The cell fate determination factor, DACH1, arrests breast tu

188 ta identify a pathway by which an endogenous cell-fate determination factor blocks oncogene-dependent

189 Expression of the cell-fate determination factor Dachshund (DACH1) was los

190 l whereby Lim1 lies downstream of horizontal cell fate determination factors and functions cell auton

191 g takes advantage of this knowledge and uses cell fate determination factors to convert one lineage i

192 Our data show that the initial cell fate determination for the vestibuloacoustic neuron

193 rfamily pathways, that are involved in their cell-fate determination from pre-specified embryonic for

194 and a change in splicing isoforms of Numb, a cell-fate determination gene.

195 mbers of the let-7 miRNA family control many cell-fate determination genes to influence pluripotency,

196 The process of cell fate determination has been depicted intuitively as

197 OR) plays a crucial role in the control of T cell fate determination; however, the precise regulatory

198 nobiotic metabolism, cell cycle progression, cell fate determination, immune function, and inflammato

199 s establish that PBX1 regulates adult neural cell fate determination in a manner beyond that of its h

200 ch signaling makes critical contributions to cell fate determination in all metazoan organisms, yet r

201 roles in regulating somatic and reproductive cell fate determination in Arabidopsis anthers.

202 Notch signaling governs binary cell fate determination in asymmetrically dividing cells

203 ggests a previously undescribed mechanism of cell fate determination in at least a subset of retinal

204 other EJC components apparently function in cell fate determination in developing male gametophytes

205 on as early events in a program of secretory cell fate determination in developing murine airways.

206 ntext of early embryonic stem cell state and cell fate determination in humans.

207 he latter have been implicated in regulating cell fate determination in invertebrates and vertebrates

208 Proper cell fate determination in mammalian gonads is critical

209 signaling proteins is a master regulator of cell fate determination in metazoans, contributing to bo

210 eless, and sine oculis (so) genes, regulates cell fate determination in metazoans, with dac serving a

211 three Foxp3 CNS elements (CNS1-3) in T(reg) cell fate determination in mice.

212 proper balance between neural and mesodermal cell fate determination in mouse embryos and ESCs.

213 ssential for apical protein localization and cell fate determination in neuroepithelial cells.

214 The Notch pathway regulates cell fate determination in numerous developmental proces

215 c1, is a critical factor required for proper cell fate determination in S. pombe.

216 ion of the MOF/FAO/OXPHOS axis in regulating cell fate determination in stem cells.

217 Cell fate determination in the asymmetric bacterium Caul

218 and intrinsic competence act in concert for cell fate determination in the developing vertebrate ret

219 e interested in the mechanisms that underlie cell fate determination in the endosporic male gametophy

220 he silent mating-type region is critical for cell fate determination in the form of mating-type switc

221 on cycle 7 (Cdc7) has been shown to regulate cell fate determination in the initial phase of transfor

222 plate, in that it plays an essential role in cell fate determination in the lateral CNS and also, lat

223 histone modifications are integral to normal cell fate determination in the mammalian lens.

224 termine whether beta-catenin regulates basal cell fate determination in the mouse trachea.

225 understanding of the molecular mechanisms of cell fate determination in the nervous system requires t

226 To understand the mechanisms of cell fate determination in the vertebrate retina, the ti

227 Dpp activity and DE-cadherin and Rho1 during cell fate determination in the wing, suggesting a broade

228 thematical analysis predicts that stochastic cell fate determination in this case can only be realize

229 an important regulator of EGFR activity and cell fate determination in vivo.

230 tigate the roles of these protein kinases in cell fate determination in Xenopus epidermis.

231 fter the first cell division plays a role in cell fate determinations in the early mouse embryo.

232 ic regulation of nuclear architecture during cell-fate determination in a mouse cell line.

233 amily of cell surface receptors important in cell-fate determination in both vertebrates and inverteb

234 not, the mechanisms at play during the first cell-fate determination in mammalian embryos have been d

235 Notch (N) signaling is used for cell-fate determination in many different developmental

236 key regulators of development by controlling cell-fate determination in many multicellular organisms.

237 calloped beyond growth to encompass specific cell-fate determination in the context of blood developm

238 nct and common roles for the three miRNAs in cell-fate determination in the inner ear, and these prin

239 ugh LRP6 appeared to be critical for granule cell fate determination, in vivo knockdown of PCP core p

240 o TSS region of genes involved in Lgr5+ stem cell fate determination, including Lgr5, Tgfb1 and Tgfbr

241 are highly conserved proteins that regulate cell fate determination, including those involved in mam

242 ism by which a known physiologic mediator of cell fate determination interfaces with cell cycle contr

243 In C. elegans, the timing of cell fate determination is controlled by the heterochron

244 served signaling pathway and its function in cell fate determination is crucial in embryonic developm

245 ology, but its role in brain development and cell fate determination is less well understood.

246 widely accepted that the process of retinal cell fate determination is under tight transcriptional c

247 ultiple receptor tyrosine kinases coordinate cell fate determination is yet to be elucidated.

248 When the process of cell-fate determination is examined at single-cell resol

249 Cell-fate determination is influenced by interactions be

250 yet whether other regulatory events support cell-fate determination is less well understood.

251 est that RAS-induced senescence represents a cell fate determination-like process characterised by a

252 f apically constricting cells, downstream of cell fate determination mechanisms.

253 ls and could provide powerful mechanisms for cell fate determination more broadly.

254 This reveals a role for nmy-2 in cell fate determination not obviously linked to the prim

255 s in plant morphogenesis, hormone signaling, cell fate determination, nutrient deficiency, nitrogen m

256 ositive selection results in a change in the cell fate determination of developing iNKT cells, with a

257 ch signaling-mediated lateral inhibition and cell fate determination of external sensory organs.

258 the immature B cell stage and contributes to cell fate determination of marginal zone B cells.

259 resence of a novel mechanism for controlling cell fate determination of mesenchymal lineages by preve

260 Thus, Epfn has multiple functions for cell fate determination of the dental epithelium by regu

261 ble, which enables direct study of quadruple cell fate determination on an engineered landscape.

262 neuronal stage, without impairing subsequent cell fate determination or differentiation.

263 enes initially identified for their roles in cell fate determination or signaling during development

264 ivity of Sox2 in promoting proliferation and cell fate determination, our data demonstrate that Sox2

265 Attenuation of FOX function by the cell fate determination pathway has broad implications g

266 tant ellipse, encodes a key component of the cell fate determination pathway involved in Drosophila e

267 How these unusual cell-fate determination patterns are generated is unclea

268 Here we identify a stochastic cell fate determination process that operates in Bacillu

269 Wnt signaling regulates cell fate determination, proliferation, and survival, am

270 ion of genes involved in lineage commitment, cell fate determination, proliferation, and tumorigenesi

271 s are potent morphogens that are involved in cell fate determination, proliferation, apoptosis and ad

272 tion and refinement of these patterns during cell fate determination remain unexplored because of the

273 Cell fate determination requires faithful execution of g

274 The data reveal Bcl-3 as a regulator of B cell fate determination, restricting the MZ path and fav

275 inciple for how cells acquire competence for cell fate determination, resulting in the context-depend

276 Ras family GTPases play a pivotal role in cell fate determination, serving as molecular switches t

277 ses in eukaryotes, including axis formation, cell fate determination, spindle pole regulation, cell m

278 in CSCs in a variety of cancers and controls cell fate determination, survival, proliferation, and th

279 s a foundation for studies of when and where cell fate determination takes place.

280 Despite its critical involvement in cell fate determination, the enrichment of germline dete

281 le for detrusor smooth muscle and urothelial cell fate determination, the mutants have significantly

282 ling pathways, suggest that Adam10 regulates cell fate determination through the activation of Notch

283 ch intercellular signaling pathway regulates cell fate determination throughout metazoan evolution, a

284 spindle during cell division is crucial for cell fate determination, tissue organization, and develo

285 ticellular organisms actively regulate their cell fate determination to cope with changing environmen

286 e biogenesis, and cellular stress that links cell fate determination to disease pathology.

287 important for diverse processes ranging from cell fate determination to synaptic plasticity; however,

288 nctions by a novel mechanism, independent of cell fate determination, to mediate the decision of neur

289 rocesses, including embryo development, stem cell fate determination, trichome branching, leaf morpho

290 tion to exhibiting spiral cleavage and early cell fate determination, trochozoans typically undergo i

291 neuromuscular junction formation, and neuron cell fate determination, typically during the pupal stag

292 roles of PKCdelta-dependent signaling in the cell fate determination upon hypoxic exposure.

293 iptional regulation that coordinates retinal cell fate determination, very little is known about the

294 To examine the role of NRL in cell fate determination, we generated transgenic mice th

295 To further evaluate its role in cell fate determination, we investigated INSM1 effects o

296 To further examine the role of Olig2 in NG2 cell fate determination, we used genetic fate mapping of

297 Thus, the APC/C coordinates cell-fate determination with the cell cycle through the

298 ults suggest that Math1 is critical for both cell fate determination within the intestinal epithelium

299 in disease states with opposing responses in cell fate determination, yet its contribution in pro-sur

300 s crucial for understanding their effects on cell-fate determination, yet it is difficult to obtain t