ライフサイエンスコーパス: cell physiology

1 usion) and pHi (a potent modulator of cancer cell physiology).

2 cells, connecting protein biochemistry with cell physiology.

3 ferating cells requires major alterations in cell physiology.

4 rization and bundling play a central role in cell physiology.

5 e' signals that alter gene expression and/or cell physiology.

6 anges to the cytoskeleton, thereby impacting cell physiology.

7 thesis of alarmones, which drastically alter cell physiology.

8 ion homeostasis is essential for eukaryotic cell physiology.

9 ed, potentially fundamental aspects of brain cell physiology.

10 e to efficient protein biogenesis and proper cell physiology.

11 RC2 exerts over diverse aspects of eukaryote cell physiology.

12 ks between tRNA biology and other aspects of cell physiology.

13 mutations through ploidy-specific changes in cell physiology.

14 ale, adaptive changes in gene expression and cell physiology.

15 w perspective on Cdc42 as key regulator of B cell physiology.

16 rget bacteria, most are known to affect host cell physiology.

17 L. monocytogenes pathogenesis and bacterial cell physiology.

18 dynamics can provide molecular insights into cell physiology.

19 NA, demographic variables, and primary human cell physiology.

20 assess how materials and technologies affect cell physiology.

21 to the effects of macromolecular crowding on cell physiology.

22 damental process involved in many aspects of cell physiology.

23 luate the impact of systems and materials on cell physiology.

24 lular proteins is critical for understanding cell physiology.

25 relevant stressor affects downstream target cell physiology.

26 potential to regulate almost every aspect of cell physiology.

27 nodes to understand normal and pathological cell physiology.

28 Cell size is fundamental to cell physiology.

29 s and regulates multiple aspects of neuronal cell physiology.

30 ole in pancreatic development and adult beta-cell physiology.

31 ng waves have emerged as important themes in cell physiology.

32 cytokines or hormones to adaptive changes in cell physiology.

33 dent influences of these two related RNAs on cell physiology.

34 NK pathway has no direct adverse effect on B cell physiology.

35 tance of miR-650 in CLL biology and normal B-cell physiology.

36 rks and bundles that support many aspects of cell physiology.

37 ipid that is vital for many aspects of yeast cell physiology.

38 hosphate stress connects to other aspects of cell physiology.

39 deration for therapeutic development and NKT cell physiology.

40 ane is believed to play an important role in cell physiology.

41 rtant process involved in several aspects of cell physiology.

42 regulatory network that regulates bacterial cell physiology.

43 NA supercoiling that is important for normal cell physiology.

44 algal species to improve growth and to assay cell physiology.

45 olic pathways and as mediators of changes in cell physiology.

46 for numerous aspects of muscle and nonmuscle cell physiology.

47 nses to mechanical perturbation are vital to cell physiology.

48 lle and varying in location depending on the cell physiology.

49 y regulate downstream signaling pathways and cell physiology.

50 ll division, migration, and other aspects of cell physiology.

51 maintaining epithelial barrier function and cell physiology.

52 taxis is coordinated with dynamic changes in cell physiology.

53 le essential roles in animal development and cell physiology.

54 membrane domains is necessary for excitable cell physiology.

55 ownregulation exerts a significant impact on cell physiology.

56 orphic organelles that have central roles in cell physiology.

57 quired for maintenance of normal endothelial cell physiology.

58 mber of genes critical in various aspects of cell physiology.

59 ed tumor antigens that interfere with normal cell physiology.

60 T to better understand how this toxin alters cell physiology.

61 that cytokine to broadly modify endothelial cell physiology.

62 , morphogenetic movements and alterations in cell physiology.

63 nd effects on cellular protein synthesis and cell physiology.

64 face receptors that have key roles in normal cell physiology.

65 lationship between mechanical properties and cell physiology.

66 ential for its roles in lipid metabolism and cell physiology.

67 assium channels (Kir) play critical roles in cell physiology.

68 lved in multiple aspects of animal and plant cell physiology.

69 ntegrating environmental stimuli that affect cell physiology.

70 nown to have an important regulatory role in cell physiology.

71 e facilitated by a better understanding of L-cell physiology.

72 e the contribution of these channels to beta-cell physiology.

73 egulatory roles in all aspects of eukaryotic cell physiology.

74 ined effects of telomerase overexpression on cell physiology.

75 roteins that allow regulation in response to cell physiology.

76 ibution of bacterial interactions to shaping cell physiology.

77 ution of organelle biogenesis is crucial for cell physiology.

78 paradigm for connecting molecular biology to cell physiology.

79 ce, and humans, highlights its importance to cell physiology.

80 r results establish a novel role for IPPs in cell physiology.

81 may have distinct effects on normal cardiac cell physiology.

82 ell cycle or in response to other changes in cell physiology.

83 phosphate metabolism is essential for proper cell physiology.

84 anslational O-GlcNAc modification in general cell physiology.

85 etwork is therefore critical for normal beta-cell physiology.

86 and genomic stability is critical for normal cell physiology.

87 estrogen content, and hippocampal pyramidal cell physiology.

88 nslational modification mechanism underlying cell physiology.

89 lar responses controlling diverse aspects of cell physiology.

90 dies of the temperature dependence of single-cell physiology.

91 ng an important role for GATA6 in human beta-cell physiology.

92 how that IL4I1 regulates multiple steps in B cell physiology.

93 enin signaling and normal mammary epithelial cell physiology.

94 llular membranes have important functions in cell physiology.

95 lose connection with the regulation of basic cell physiology.

96 s measurements without perturbing the native cell physiology.

97 ts of acute exposure to aflatoxins on airway cell physiology.

98 gets becoming signaling platforms crucial in cell physiology.

99 omplex 2 (PRC2) is an essential regulator of cell physiology.

100 nvestigate the role of a rhomboid protein in cell physiology, a glpG mutant of E. coli was constructe

101 d by Src-family-kinases (SFKs) in regulating cell physiology, activity patterns of individual SFKs ha

102 lar metabolism, suggesting a major change in cell physiology allowing the bacterium to grow in the ho

103 syl)ation of mammalian proteins to influence cell physiology and adaptive immunity.

104 (PRCP), or angiotensinase C, in endothelial cell physiology and angiogenesis.

105 After an update on B cell physiology and antibody generation, the 2015 Beaune

106 recently been revisited in the context of B-cell physiology and antigen presentation.

107 in NS levels are required to maintain normal cell physiology and are dysregulated in disease.

108 rs of kinesin would be valuable as probes of cell physiology and as potential therapeutics.

109 h severe disease, yet the role of SRSF1 in T cell physiology and autoimmune disease is largely unknow

110 onse linking ribosome homeostasis with basic cell physiology and behaviour.

111 le methods for cell concentration can affect cell physiology and bias readouts of cell behavior and f

112 (CREM) alpha has important roles in normal T cell physiology and contributes to aberrant T cell funct

113 pled receptors (GPCRs) are key regulators of cell physiology and control processes ranging from gluco

114 s were significantly more toxic in assays of cell physiology and death.

115 Study of normal cell physiology and disease pathogenesis heavily relies

116 advances in our deep understanding of normal cell physiology and disease pathogenesis.

117 f the UFM1 pathway, and its implications for cell physiology and disease.

118 mits our ability to understand their role in cell physiology and disease.

119 lycocalyx is thus essential to understanding cell physiology and elucidating its role in promoting he

120 a powerful strategy for pathogens to subvert cell physiology and establish infection.

121 ying toxins, which function to modulate host cell physiology and evade immune responses.

122 mpacts cell function would enable control of cell physiology and fate in medical applications, partic

123 oenvironment ex vivo that is able to sustain cell physiology and function in order to generate the de

124 elial cell lining but also induce changes in cell physiology and function such as cell shape, membran

125 d the effects of their interactions on guard cell physiology and function.

126 xic, and that low oxygen tension () alters B cell physiology and function.

127 portance of membrane potential in regulating cell physiology and growth, and demonstrate that antimic

128 rences in adhesion, proliferation, bacterial cell physiology and host cell responses.

129 icable to define lineage specificity in both cell physiology and human disease contexts.

130 , has emerged as a central regulator of both cell physiology and human health.

131 trol by Cdc123 may prove relevant for normal cell physiology and human health.

132 s that play key roles in multiple aspects of cell physiology and identity, including regulation of al

133 positive and negative growth factors play in cell physiology and in human diseases.

134 Studies of the cell physiology and indeed pathophysiology of ER-PM junc

135 e notion that Fpn plays an important role in cell physiology and is not simply dedicated to toxin bio

136 new insight into how folate influences human cell physiology and may have implications for our unders

137 However, the host cell physiology and metabolic requirements supporting ba

138 ion factor Egr1 controls multiple aspects of cell physiology and metabolism.

139 resentation will illuminate novel aspects of cell physiology and might lead to improved vaccine desig

140 mplications with regard to both normal glial cell physiology and pathogenesis.

141 rget types can provide in-depth insight into cell physiology and pathology, but remains challenging o

142 r environment is involved in many aspects of cell physiology and pathology.

143 hanical signaling plays an important role in cell physiology and pathology.

144 egulation and mitochondrial function, and to cell physiology and pathophysiology, the structure and c

145 pled receptors (GPCRs) play crucial roles in cell physiology and pathophysiology.

146 ent findings on the effects of aneuploidy on cell physiology and proliferation.

147 ur understanding on the role of the Golgi in cell physiology and provide a potential target for treat

148 map the impact of cost/benefit tradeoffs on cell physiology and regulation.

149 o elucidate how signaling dynamics determine cell physiology and represents a paradigm shift from des

150 ey lessons on the interaction between single-cell physiology and selection that should inform the des

151 To manipulate host cell physiology and subvert plant immune responses, path

152 an unexpected role for DISC1 in normal beta-cell physiology and suggest that DISC1 dysregulation con

153 ction by revealing critical roles in Schwann cell physiology and suggest that PNH in SJS originates d

154 O-GlcNAcylation in various aspects of tumor cell physiology and suggest that this modification may s

155 cal processes that have a profound effect on cell physiology and that are related to cell death.

156 en demonstrated to play an important role in cell physiology and the development of cardiovascular an

157 However, the role of PMP22 in Schwann cell physiology and the mechanisms by which PMP22 mutati

158 insights into lacrimal gland stem/progenitor cell physiology and their potential for treating severe

159 investigation of pericyte and smooth muscle cell physiology and their role in regulating rCBF.

160 RANKL-RANK inhibition could interfere with B cell physiology and thereby trigger immunologic side-eff

161 ion that exofacial CA is critical for cancer cell physiology and they establish the immunotherapeutic

162 ortant regulatory role for PPARgamma in beta-cell physiology and thiazolidinedione pharmacology of ty

163 Although the role of STAT3 in cell physiology and tissue development has been largely

164 Correct polarization is crucial for normal cell physiology and tissue homeostasis, and is lost in c

165 viruses in vertebrate cells strongly affects cell physiology and ultimately leads to development of a

166 ng stoichiometry and its ion-to-ATP ratio on cell physiology, and also demonstrate the bioenergetic c

167 tor receptor (EGFR) is central to epithelial cell physiology, and deregulated EGFR signaling has an i

168 Protein translation is essential for cell physiology, and dysregulation of this process has b

169 sion of GP1,2 at high levels disrupts normal cell physiology, and EBOV uses an RNA-editing mechanism

170 systems ensures basal catabolism and normal cell physiology, and failure of either system causes dis

171 cts of RbpA truncations on transcription and cell physiology, and indicate additional functions for R

172 This process participates in many aspects of cell physiology, and is conserved in all eukaryotes.

173 pathway connects adipocyte function to beta cell physiology, and manipulation of this molecular swit

174 ilized as vaccines, as tools to dissect host cell physiology, and more recently for the development o

175 RNA helicase A (RHA) plays numerous roles in cell physiology, and post-transcriptional activation of

176 s pathway is critically important for normal cell physiology, and recent advances in our understandin

177 rs of this superfamily have crucial roles in cell physiology, and some of the transporters are linked

178 sive macroautophagy can seriously compromise cell physiology, and thus, it needs to be properly regul

179 Imbedded in immune cell physiology are metabolic pathways and metabolites t

180 d with AZM, likely due to general changes in cell physiology as a result of the increased effectivene

181 couple the rate of transposition to the host cell physiology as both of these proteins are integrated

182 oducts interact can help to elucidate normal cell physiology as well as the genetic architecture of p

183 mercury methylation due to its influence on cell physiology (as a potential nutrient) and its influe

184 fied in the CNS, including neural progenitor cell physiology, astrocyte and microglia activation, neu

185 Cell size is important for cell physiology because it sets the geometric scale of o

186 Cell size is fundamental to cell physiology because it sets the scale of intracellul

187 d provide insights into genetic variation in cell physiology between yeast strains.

188 skeletal structures plays a critical role in cell physiology, but how proteins localize differentiall

189 transmembrane domains play critical roles in cell physiology, but little is known about the machinery

190 Scaling changes can affect cell physiology, but problems associated with WGD in lar

191 nase A (PKA) is known to play a role in beta cell physiology, but the role of its anchoring protein i

192 mechanisms that control important aspects of cell physiology, but this ambition is often limited by t

193 GPCRs modulate cell physiology by activating diverse intracellular tran

194 MicroRNAs (miRNAs) regulate cell physiology by altering protein expression, but the

195 e explore the impact of cryptic prophages on cell physiology by precisely deleting all nine prophage

196 ondrial calcium uptake has a central role in cell physiology by stimulating ATP production, shaping c

197 ng protein that regulates critical events in cell physiology by the regulation of pre-mRNA splicing a

198 abolic reaction of fundamental importance in cell physiology, can be regulated.

199 effects of autonomic nervous input on islet cell physiology cannot be studied in the pancreas.

200 f target genes and their widespread roles in cell physiology, circadian rhythms are also modulated by

201 e cell density plays a major role in sessile cell physiology, commencing with the first stage of biof

202 Epithelial cell physiology critically depends on the asymmetric dis

203 ions of cellular membranes, and thus overall cell physiology, depend on the distribution of crucial l

204 would account for several aspects of T(reg) cell physiology, differentiation and stability.

205 t is, whether RANKL-RANK signaling affects B cell physiology directly or the observed defects are sec

206 amage is not insulated from other aspects of cell physiology during development and multiple features

207 the function of carbonic anhydrases (CAs) in cell physiology emphasizes the role of membrane-bound CA

208 Autophagy plays a central role in cell physiology, energy and metabolism, and cell surviva

209 In this article we review normal red blood cell physiology; etiologies of anemia in the intensive c

210 d and open new paths for research in the red cell physiology field.

211 substrates in cells, and key roles in yeast cell physiology have been uncovered by introducing subun

212 Auditory system and hair cell physiology, histology, and anatomy studies reveal n

213 ir well-known function in maintaining normal cell physiology, how inorganic elements are relevant to

214 bronectin-rich extracellular matrix regulate cell physiology in a number of diseases, prompting effor

215 play an important role in the regulation of cell physiology in a wide variety of excitable and nonex

216 d its intracellular processes in relation to cell physiology in healthy and diseased states.

217 T cells, leading to the assumption that iNKT cell physiology in human and mouse is similar.

218 een caveolin/caveolae expression and altered cell physiology in IPAH contrast with previous results o

219 loning of a novel protein required for Clara cell physiology in mouse lung development.

220 rther avenues to probe and direct changes in cell physiology in response to dynamic biochemical signa

221 novel strategy to assess gene expression and cell physiology in single living cells.

222 enetic technology to beneficially manipulate cell physiology in the context of neuronal regeneration

223 model will enable meaningful studies of beta-cell physiology in the endogenous islet niche.

224 by the lack of methods to interrogate single-cell physiology in vivo.

225 Purkinje cell physiology, in contrast, was normal in AS mice as s

226 intics, as it plays critical roles in normal cell physiology, in removal of drugs from cells, and pot

227 esses involved in signaling, cell cycle, and cell physiology including detoxification, protein biogen

228 ted kinase (ERK) controls various aspects of cell physiology including proliferation.

229 (CaCCs) perform many important functions in cell physiology including secretion of fluids from acina

230 ranscription to regulate numerous aspects of cell physiology, including cell growth, senescence, stre

231 CaCCs perform important functions in cell physiology, including regulation of epithelial secr

232 hers has revealed a multiplicity of roles in cell physiology, including regulation of intracellular C

233 active lipid involved in multiple aspects of cell physiology, including signaling and membrane traffi

234 and systems that interact with cells impact cell physiology is crucial for the development and ultim

235 acellular concentration of macromolecules on cell physiology is increasingly appreciated, but its imp

236 as calcium ion channels, but their impact on cell physiology is not fully known.

237 le of miRNAs in regulation of differentiated cell physiology is not well established.

238 his phenomenon and its overall importance to cell physiology is not well understood.

239 echanism(s) by which heparin alters vascular cell physiology is not well understood.

240 atory mechanisms controlling intestinal stem cell physiology is of great importance.

241 p between receptor endocytic trafficking and cell physiology is unclear.

242 a suitable animal model for studies on hair cell physiology, it is advisable to consider that the ag

243 a novel tool/compound for investigating beta-cell physiology, KATP channel gating, and a new chemical

244 be introduced using techniques that perturb cell physiology, limit throughput, or generate fluoresce

245 should consider that monocyte and macrophage cell physiology may be affected by this system.

246 el for studying how abnormalities in Schwann cell physiology may facilitate and sustain chronic pain.

247 ovide chemical tools to study the changes in cell physiology mediated by these lipids, three new meta

248 effect of deposited cell density on E. coli cell physiology, metabolic activity, and gene expression

249 ltiple other chromosomal genes implicated in cell physiology, multiple drug resistance and virulence.

250 e formation of ROS and their consequences on cell physiology of Escherichia coli.

251 Using in vitro whole-cell physiology, optogenetics, and pharmacology, we dete

252 a useful pharmacological tool to study beta-cell physiology or even open a new therapeutic avenue fo

253 respiratory enzymes did not detectably alter cell physiology or mitochondrial function.

254 RK pathway signaling, but their role(s) in B-cell physiology or pathology are unknown.

255 e have been no functional descriptions of M3 cell physiology or synaptic inputs.

256 late the host ubiquitin system to alter host cell physiology or the location, stability, or function

257 sessed pancreatic development and adult beta-cell physiology phenotypes.

258 hat such contacts play more general roles in cell physiology, pointing to the existence of additional

259 um of the placenta, though having many basic cell physiology properties similar to those of other tra

260 cle we review major open questions in single-cell physiology, provide a brief introduction to the tec

261 leton plays a variety of roles in eukaryotic cell physiology, ranging from cell polarity and migratio

262 n exposure and might drive direct changes in cell physiology rather than acting through rare mutation

263 Aside from maintaining normal and adapted cell physiology, recent studies indicate that PGC-1 coac

264 pose that the effects of intact alpha(2)M on cell physiology reflect the degree of penetration of act

265 zed that the overall effects of alpha(2)M on cell physiology reflect the integrated activities of mul

266 tational models for analyzing and predicting cell physiology rely on in vitro data collected in dilut

267 otypes and the consequences of aneuploidy on cell physiology remain poorly understood.

268 romise for biomedicine, yet their effects on cell physiology remain poorly understood.

269 This organism can modify many aspects of cell physiology, rendering experiments that are conducte

270 Exploitation of this technology for studying cell physiology requires the further development of phot

271 d a complex dependence of this virus on host cell physiology, requiring a wide variety of molecules a

272 r PKD-mediated regulation of a key aspect of cell physiology, secretion, and innate immunity in vivo.

273 t DnaA plays an important role in modulating cell physiology, separate from its role in replication i

274 M) phosphoinositides play essential roles in cell physiology, serving as both markers of membrane ide

275 ic pHluorin proved to be a valuable tool for cell physiology studies.

276 reviously described virus-induced changes in cell physiology, such as apoptosis, autophagy, and inhib

277 Despite its important role in muscle cell physiology suggested by various in vitro studies, t

278 t METH has a stronger effect on DAT-mediated cell physiology than AMPH, which may contribute to the e

279 spermatogonia and meiotic spermatocytes have cell physiologies that require high levels of mitochondr

280 a simple whole-cell coarse-grained model of cell physiology that combines the proteome allocation th

281 as sustained changes in gene expression and cell physiology that do not involve permanent genetic ch

282 SYT-alpha and SYT-beta are important for NE cell physiology, that one or both are integral membrane

283 Despite its potentially important role in cell physiology, the mechanisms that regulate tescalcin

284 REC domains control cell physiology through diverse mechanisms, many of whic

285 n kinase C (PKC) family of enzymes regulates cell physiology through phosphorylation of serine and th

286 We investigated if ECs influence beta-cell physiology through regulating insulin action and de

287 he extensive interplay between the clock and cell physiology through the regulation of core clock gen

288 tein-coupled receptors (GPCRs) that regulate cell physiology throughout the nervous system.

289 e cytosol of host cells, where they modulate cell physiology to favor the pathogen.

290 ue set of effectors that subvert normal host cell physiology to promote pathogenesis.

291 ted during the CE experiments and that basal cell physiology was not perturbed prior to cell lysis.

292 address how individual ClpP proteases impact cell physiology, we constructed a S. aureus mutant expre

293 h significantly facilitates studies of coral cell physiology, we demonstrate in vitro excretion of EC

294 the immediate consequences of aneuploidy on cell physiology, we identified mechanisms that eliminate

295 nvestigate the function of TRPC1 proteins in cell physiology, we studied heterologously expressed TRP

296 l consequences of VacA infection on parietal cell physiology were studied using freshly isolated rabb

297 This has potential consequences in normal cell physiology, where the chromatin environment changes

298 xamine VRAC diversity in normal and diseased cell physiology, which is key to exploring novel therape

299 What effects on cell physiology would result from their conversion to hi

300 of electron transport routes is crucial for cell physiology, yet the factors that control the predom