ライフサイエンスコーパス: cellular structure

1 g are opening doors to new ways of analyzing cellular structure.

2 at incorporates aspects of the inhomogeneous cellular structure.

3 in plants and their highly compartmentalized cellular structure.

4 d in seed viability, colour of the beans and cellular structure.

5 s with definable number of MPs within the 3D cellular structure.

6 ers formed at substantial distances from any cellular structure.

7 al mechanism for the construction of a large cellular structure.

8 is broadening our in-depth understanding of cellular structure.

9 ffer better preservation of histological and cellular structure.

10 architecture of macromolecular complexes or cellular structures.

11 copy now permits the recording of such small cellular structures.

12 multaneously damaging other biomolecules and cellular structures.

13 tion, dynamics, and stability of actin-based cellular structures.

14 nt insight into the relative organization of cellular structures.

15 providing important insights into details of cellular structures.

16 al mechanical properties with the underlying cellular structures.

17 in nucleation factors in generating distinct cellular structures.

18 configurations, which allow imaging in deep cellular structures.

19 , which have all produced stunning images of cellular structures.

20 o measure the density and integrity of other cellular structures.

21 coupled to the assembly/disassembly of these cellular structures.

22 ors due to its ability to form complex multi-cellular structures.

23 zed for MAP localization and function within cellular structures.

24 s for metabolism, growth, energy stores, and cellular structures.

25 on pathways collaborate to form higher-order cellular structures.

26 es by executing biochemical assays on intact cellular structures.

27 for cytokinetic contractile rings and other cellular structures.

28 ondria do not divide in isolation from other cellular structures.

29 at microtubule plus ends and BICD2-positive cellular structures.

30 ly of complex and dynamic cytoskeleton-based cellular structures.

31 semble unbranched actin filaments in diverse cellular structures.

32 ossess highly diverse and spatially confined cellular structures.

33 e precision along the optical axis in motile cellular structures.

34 s, significantly improving the resolution of cellular structures.

35 e in the presence of interference or complex cellular structures.

36 to differences in confinement geometries of cellular structures.

37 d the other to binding of molecules to small cellular structures.

38 the need to move away from a static view of cellular structures.

39 rlies A beta-peptide generation within these cellular structures.

40 s to resolve the 3D morphology of nanoscopic cellular structures.

41 namic tubular networks interacting with many cellular structures.

42 rom severing, that could be capped in stable cellular structures.

43 e vital for targeting kinesin-1 to different cellular structures.

44 and interactions of microtubules with other cellular structures.

45 ded it, which in turn stimulates assembly of cellular structures.

46 ces microtubule dynamics to generate complex cellular structures.

47 ly and connect the microtubule tips to other cellular structures.

48 esponse, and cell death by targeting various cellular structures.

49 the mono-resonance characteristics of simple cellular structures.

50 nd other molecules affects numerous internal cellular structures.

51 eneric that it may be applied to nonneuronal cellular structures.

52 tags labeling 10 proteins representing major cellular structures.

53 rmation, along with super-resolved images of cellular structures.

54 within a variety of signaling complexes and cellular structures.

55 hology of the primary cilium, a tiny tubular cellular structure (~2-6 mum long and 200-300 nm in diam

56 tive stabilities of spherical or cylindrical cellular structures (acini or tubes).

57 Our studies indicate that a central cellular structure affected by schizophrenia susceptibil

58 Fine grained cellular structures allow for fabrication of foams for u

59 Cellular structures also occur in biological tissue, and

60 We review the function of cellular structure and components such as Hertwig's epit

61 trical properties of cells, dependent on the cellular structure and content, are also label-free indi

62 pathway by neuroD developed a highly ordered cellular structure and could integrate into the outer nu

63 The differences in cellular structure and defense systems among prokaryotic

64 hase imaging, functional characterization of cellular structure and dynamics through silicon substrat

65 ctionally and biochemically links control of cellular structure and energy utilization through activa

66 complex disruption can result in defects in cellular structure and function that may contribute to t

67 important but largely unexplored aspects of cellular structure and function, including the organizat

68 vital component of cells and are critical to cellular structure and function, so much so that alterat

69 of the super-resolution toolbox for probing cellular structure and function.

70 ly dynamic, filamentous network underpinning cellular structure and function.

71 lar program responsible for its development, cellular structure and function.

72 sms, which permits the real-time analysis of cellular structure and function.

73 study in parameter variation and shows that cellular structure and geometry has a nontrivial impact

74 To maintain cellular structure and integrity during division, Gram-n

75 water and ion transport, and maintenance of cellular structure and integrity.

76 ce of a protein in a specific compartment or cellular structure and its functional significance.

77 microscopy (EM) is widely used for studying cellular structure and network connectivity in the brain

78 lexibility is one of the keys to maintaining cellular structure and organization.

79 ep towards more realistic representations of cellular structure and organization.

80 be combined with fluorescence to image both cellular structure and trace element distribution in fro

81 lism (ENPP5, PLSCR2), beta-oxidation (ECH1), cellular structure and transport (HEATR4), and transcrip

82 ormance of deep neural networks on different cellular structures and achieve multi-color, live-cell s

83 n applied the method to experimental data of cellular structures and demonstrated that deconSTORM ena

84 techniques advantageously for investigating cellular structures and dynamics to promote new discover

85 ich can alter the biological function of key cellular structures and eventually lead to cell death.

86 hat we uncover may be used to study emergent cellular structures and forces and to develop programmab

87 techniques for building increasingly complex cellular structures and functions from purified componen

88 lear how its presence in the gut affects the cellular structures and functions of this organ.

89 Proteins involved in many different cellular structures and functions were present, includin

90 drift and evaluating the energetic costs of cellular structures and functions.

91 Thiols are critical to cellular structures and functions.

92 on and applied it to correct images of fixed cellular structures and living entire cells.

93 Alterations that impair cellular structures and metabolism are implicated in see

94 Because cellular structures and molecules are invisible to the h

95 teins and dehydrins, which help preserve the cellular structures and nutrients within the seed during

96 Many cellular structures and organelles are too small to be p

97 Imaging cellular structures and organelles in living cells by lo

98 time-lapse, live-cell nanoscopy of discrete cellular structures and organelles with high spatiotempo

99 cycle-dependent mobile protein fractions in cellular structures and provides a valuable dataset, tha

100 fish tissue are due to the breakdown of the cellular structures and release of cytoplasmic contents.

101 n morphology and distribution in relation to cellular structures and the MnCO3 surface.

102 py (STORM) as a tool to quantitatively probe cellular structures and their interactions.

103 The ability to directly visualize nanoscopic cellular structures and their spatial relationship in al

104 l to learn the relationships among these sub-cellular structures and use reference structures to infe

105 ls, an altered pattern of GFP-ATG8-decorated cellular structures, and altered recovery from darkness-

106 of cells will reveal biological mechanisms, cellular structures, and physiological processes in nano

107 ty to bind filaments, localize to particular cellular structures, and regulate filament severing by c

108 oiting morphological differences between sub-cellular structures, and their local spatial context.

109 Cellular structures are continually subjected to forces,

110 basal bodies and the formation of polarized cellular structures are disrupted in mice with mutant ci

111 clonal lines corresponding to each of the 10 cellular structures are now available to the research co

112 Guided by extensive theoretical analysis, cellular structures are rationally designed, in which bu

113 Cellular structures are shaped by hydrogen and ionic bon

114 Hierarchical cellular structures are ubiquitous in nature because of

115 This allows for precise observation of cellular structures as well as cryopreservation of cells

116 of intracellular signaling and submicrometer cellular structures as well as large-scale cell morpholo

117 e easily applied to detection tasks of other cellular structures as well.

118 that determines production of the branching cellular structures, as optimization of this component r

119 ended to analyze the micromechanics of other cellular structures assembled in cell-free extracts.

120 ay epithelia, and BBS2 and BBS4 localized to cellular structures associated with motile cilia.

121 thods allowed us to investigate a variety of cellular structures at <50 nm lateral and <100 nm axial

122 This process allows us to produce complex cellular structures at a scale that is finer than the na

123 gy is limited by difficulties in visualizing cellular structures at high spatial resolution within th

124 osure; AOE) induces hearing loss and damages cellular structures at multiple locations in the auditor

125 ctly visualize molecular interactions within cellular structures at the nanometer scale.

126 powerful tool to visualize biomolecules and cellular structures at the nanometer scale.

127 imple and versatile live-cell imaging of sub-cellular structures at the nanoscale.

128 may reveal where the protein interacts with cellular structures, because binding of proteins to such

129 nabled superresolution optical microscopy of cellular structures beyond Abbe's diffraction limit, ext

130 requires an intensive crosstalk within liver cellular structures, but also with other organs.

131 st a novel method of building a hierarchical cellular structure by stacking cell-attached microplate

132 ome also extensively communicates with other cellular structures by exchanging content and informatio

133 oswitchable protein Dronpa, and we visualize cellular structures by imaging the mammalian nuclear por

134 addition, the localizations of generated sub-cellular structures by our approaches are consistent wit

135 have minimized their genome content and sub-cellular structures by reductive evolution.

136 egulation of gene expression and assembly of cellular structures, by and large, the key questions reg

137 We recently identified a cellular structure called the mitochondrial-derived comp

138 th increased carotenoid content suggest that cellular structures can adapt to facilitate the sequestr

139 at the cell topology and formulation of such cellular structures can be engineered to reduce the leng

140 s not just one "wild-type" form, rather that cellular structures can exhibit a surprisingly broad div

141 Mechanochemical disruption of cellular structures can potentially induce phenotypic al

142 s mature neural marker expression as well as cellular structure changes accompanying neuronal differe

143 In parallel to functional reactions, cellular structure changes as well; however, the mechani

144 During the acute attack, hyperreflective cellular structures consistent with inflammatory cells t

145 architecture of its actin network.Protrusive cellular structures contain a heterogeneous density of a

146 P) is a property of epithelial tissues where cellular structures coordinately orient along a two-dime

147 have the ability to generate the desired sub-cellular structures correctly.

148 A streamlined cellular structure could be advantageous to microorganis

149 possibly within the hydrogen-bond network of cellular structures, could explain the maintenance of wa

150 The assembly of microtubule-based cellular structures depends on regulated tubulin polymer

151 hermia-hypoxia challenge stabilized the HK-2 cellular structure, diminished cytoplasmic translocation

152 The nucleolinus is a little-known cellular structure, discovered over 150 years ago.

153 similar in apoptotic cells, suggesting that cellular structures do not dramatically alter substrate

154 Processing resulted in disruption of the cellular structure during digestion, as observed by scan

155 al grafts ex vivo and is likely to stabilize cellular structure during ischemic insult.

156 allus, we propose that disintegration of the cellular structure during wheat grain desiccation facili

157 hermore, we noted potential modifications of cellular structures during sulfur deprivation, including

158 The microviscosity of cellular structures effects the diffusion rate of molecu

159 RNA granules are dynamic cellular structures essential for proper gene expression

160 Herein we develop an elastomeric cellular structure filled with nanoporous material funct

161 other functional materials into hierarchical cellular structures for various applications where high

162 e not generally applicable to imaging of sub-cellular structure (for example, magnetic resonance imag

163 This allows quantitative access to cellular structures, for example, how proteins are distr

164 However, many key cellular structures (from mitochondrial cristae to nucle

165 To explain how micrometer-sized cellular structures generate and respond to forces, we n

166 's surface in the form of two characteristic cellular structures: granules and supergranules (~1000 a

167 uid and its interaction with cell walls, the cellular structure has a much enhanced mechanical perfor

168 icient to reproduce mechanical influences on cellular structure has important implications in a diver

169 gand-responsive signaling complexes in other cellular structures has motivated studies of site-specif

170 Additive manufacturing of cellular structures has numerous applications ranging fr

171 Although all three cellular structures have been separately implicated in B

172 cence method capable of real-time imaging of cellular structure height with nanometre resolution.

173 ative sensitivity of each probe to different cellular structures, here we took a comprehensive approa

174 From an initial fascination with cellular structures I came to appreciate that cells exhi

175 We combined MERFISH with cellular structure imaging to determine subcellular comp

176 Here we describe a technique for producing cellular structures implicitly by inducing viscous threa

177 Podosomes are ubiquitous cellular structures important to diverse processes inclu

178 high-resolution phenotyping to characterize cellular structure in inherited retinal disease; such in

179 y of the salivary glands, unique features of cellular structure in the oral mucosa and palatine tonsi

180 ging is ubiquitous and essential for shaping cellular structures in all organisms.

181 zes the formation and polarity of developing cellular structures in frog, fish and mouse embryos.

182 ilities open a new window for characterizing cellular structures in living cells at the ultrastructur

183 two to five-fold, recovers cellular and sub-cellular structures in many regions that are not resolve

184 the coordination of microtubules with other cellular structures in multiple contexts, although the m

185 ired by biological shells and honeycomb-like cellular structures in nature, we introduce a class of h

186 , receptor complexes, invadopodia, and other cellular structures in the malignant process.

187 n microscopy methods allow the resolution of cellular structures in the range of tens of nanometers.

188 tment without any significant changes in the cellular structure including cell walls.

189 uch as buds and tubules is essential to many cellular structures including endocytic pits and filopod

190 Spinal cord cellular structure, including astrocytes, microglia, neu

191 ck a circulatory system, and have additional cellular structures, including cell walls and chloroplas

192 k state characterized by deformation of many cellular structures, including mitochondria.

193 demonstrate a route to incorporate a complex cellular structure into microelectromechanics by interfa

194 These findings shed light on the cellular structures involved in anterograde and retrogra

195 ors are enriched in processing bodies (PBs), cellular structures involved in degradation and/or stora

196 Understanding cellular structure is key to understanding cellular regu

197 The equilibrium adaptive cellular structure is responsible for long-sought non-di

198 derstanding of force transmission within sub-cellular structures is a major obstacle to unravelling m

199 Self-organization of cellular structures is an emerging principle underlying

200 rality using macro- and microscale supported cellular structures is described.

201 semble into highly organized, supramolecular cellular structures known as filamentous (F)-actin and b

202 1) immediate-early protein ICP0 localizes to cellular structures known as promyelocytic leukemia prot

203 The forebrain is one of most complex cellular structures known.

204 ophagic vacuoles accompany the disruption of cellular structure, leading to cell lysis.

205 esses have been used to produce open regular cellular structures limited only by the resolution of th

206 ngth is attributed to solidification-enabled cellular structures, low-angle grain boundaries, and dis

207 l and self-cell recognition, cell signaling, cellular structure maintenance, and immune protection.

208 Disruption of cellular structure may affect LTCC in a microdomain-spec

209 biological systems, including their role in cellular structure, metabolism, and disease development,

210 netics of organelle biogenesis, formation of cellular structures, metabolism, and coexpression patter

211 eral and can be potentially applied to other cellular structures near the onset of disorder.

212 llular machinery to access molecules and sub-cellular structures needed for infection.

213 lves the de novo generation of two different cellular structures: novel membrane compartments within

214 CPHE) process which primarily decomposes the cellular structure of algae and facilitates the release

215 culture system mimics the three-dimensional cellular structure of bone, consisting of collagen gel-e

216 gene encodes SGCA, which is involved in the cellular structure of muscle fibers and, along with DMD,

217 conomo and Koskinas (1925) on the microscale cellular structure of the human cortex with data on macr

218 D maps of the connecting cilium and adjacent cellular structures of a modified primary cilium, the ro

219 his feature makes it particularly useful for cellular structures of heterogeneous densities and irreg

220 EGFP2 for live-cell RESOLFT nanoscopy of sub-cellular structures of intact Drosophila melanogaster la

221 automatically localize and recognize in situ cellular structures of interest captured by cryo-ET, we

222 Assembly of the organized cellular structures of RNase II required the RNase II am

223 infectious organisms revealed unprecedented cellular structures of this unusual member of the spiroc

224 We also characterize the cellular structures of three endogenously expressed non-

225 croscopic hollow structure and a microscopic cellular structure) offer unique inspiration for designi

226 n accurately localize and identify important cellular structures on both the 2D tilt images and the r

227 is characterized by formation of specialized cellular structures or 'traps'.

228 Cellular structures or tessellations are ubiquitous in n

229 able specificity have also localized CLN3 in cellular structures other than lysosomes.

230 tion and assembly of RNase II into organized cellular structures play an important role in the normal

231 as cuttlebone, which is an ultra-lightweight cellular structure (porosity, ~93 vol%) used as the anim

232 uding identification of restriction factors, cellular structures promoting viral transmission includi

233 Elastomeric cellular structures provide a promising solution for ene

234 e assists in the assembly of a wide range of cellular structures, ranging from the cytoskeleton to ch

235 sents molecule counts and positions within a cellular structure, rather than only summarizing structu

236 the signaling events that connect these two cellular structures remain poorly understood.

237 rane ruptures and rebuild damaged or missing cellular structures remain poorly understood.

238 ntations of molecule counts and positions in cellular structures, require the application of a cluste

239 nction of adhesions and invadopodia, two key cellular structures required for breast cancer metastasi

240 ty of the protein to assemble into organized cellular structures required the membrane binding domain

241 cal processes, influence the architecture of cellular structures, reveal the stoichiometries of prote

242 on would be also responsible for the loss of cellular structure, seed viability and sensory changes.

243 challenging to experimentally label all sub-cellular structures simultaneously in the same cell.

244 are able to form relatively stable links to cellular structures, so that when a microtubule grows it

245 e of their prevalence in stable, high-stress cellular structures such as cilia, we sought to determin

246 sis of experimental tracks of rapidly moving cellular structures such as endosomes and lysosomes.

247 filaments are central to a large variety of cellular structures such as filopodia, stress fibers, cy

248 g to specific membrane lipids or by altering cellular structures such as membrane microdomains (lipid

249 ctional imaging of complex three-dimensional cellular structures such as neuronal dendrites or neural

250 construct composite assemblies, evocative of cellular structures such as spindles, where the inherent

251 acellular matrix in the exterior or internal cellular structures such as the cytoskeleton, locally pi

252 Cellular structures such as the nucleus, Golgi, centriol

253 SH2 domain-based photoprobe was targeted to cellular structures, such as the actin cytoskeleton, mit

254 ymers of alphabeta-tubulin that form diverse cellular structures, such as the mitotic spindle for cel

255 ccur, chromosomes must be segregated and new cellular structures, such as the spindle apparatus, must

256 pproximately 1,000-fold to be contained in a cellular structure termed the nucleoid.

257 ium, the organ of Corti, is a highly ordered cellular structure that comprises two types of auditory

258 The primary cilium is a singular cellular structure that extends from the surface of many

259 nk PtdIns signaling to the primary cilium, a cellular structure that is becoming increasingly recogni

260 t unanswered questions about this remarkable cellular structure that merit new consideration in light

261 HB-EGF induced the formation of invadopodia, cellular structures that aid cancer cell invasion.

262 re we report that RNase II is organized into cellular structures that appear to coil around the Esche

263 Tight junctions (TJs) are dynamic cellular structures that are critical for compartmentali

264 ences as well as an organizing principle for cellular structures that are not membrane bound.

265 Invadopodia are Src-induced cellular structures that are thought to mediate tumor in

266 Soft cellular structures that comprise a solid matrix with a

267 Kinetochores are dynamic cellular structures that connect chromosomes to microtub

268 Centrioles are vital cellular structures that form centrosomes and cilia.

269 Cilia are important cellular structures that have been implicated in a varie

270 etween virus factories and viroplasm and the cellular structures that house them.

271 ammalian oocyte is nurtured by its own multi-cellular structure, the ovarian follicle.

272 Little attention has been given to another cellular structure, the perineurium, which ensheaths the

273 a(V)1.3a in regulating the architecture of a cellular structure, the ribbon synapse, in developing ze

274 om the tracheids or vessels that make up its cellular structure, through to the microfibrils within t

275 t how differentiating cells reorganize their cellular structure to perform specialized physiological

276 ir gene-expression programs, metabolism, and cellular structures to induce a common cellular state is

277 requires the coordinated action of multiple cellular structures to nucleate and organize microtubule

278 iral receptor and coreceptor, CD4/CXCR4, and cellular structures toward the virus contact area, and t

279 We developed a method to measure binding to cellular structures using fission yeast cells as reactio

280 tion of subdiffraction-resolution imaging of cellular structures using intrinsic contrast from unmodi

281 o method to infer protein composition within cellular structures using proximity labeling approaches

282 Investigation of heterogeneous cellular structures using single-molecule localization m

283 e growth rate of a cell in a two-dimensional cellular structure (using the relation between wall velo

284 cell stalk lengths (a sub-diffraction-sized cellular structure) was quantified for a mixed populatio

285 comprising keratinocyte immune function and cellular structure, was found to be disrupted.

286 se was markedly diminished when the RNase II cellular structures were lost due to changes in the amph

287 nditions, indicating that host co-factors or cellular structures were not required for rodlet formati

288 geny RNA2, prevents recruitment of RNA2 into cellular structures, where it is translationally silence

289 Mutant chloronemal filaments contained large cellular structures which excluded all other cellular or

290 l functional significance of this unique sub-cellular structure, which might provide an additional vi

291 ptically transparent, thereby exposing their cellular structure with intact connectivity.

292 to stable fibers may be regulated to produce cellular structures with diverse physiochemical properti

293 This technique allows us to create cellular structures with engineered cuts and folds that

294 uper-resolution microscopy allows imaging of cellular structures with high throughput and detail.

295 copy (EM) is the standard method for imaging cellular structures with nanometer resolution, but exist

296 on microscopy now makes it possible to image cellular structures with near molecular-scale resolution

297 e the diffraction limit to observe nanoscale cellular structures with unprecedented detail, and singl

298 scopy (STORM) have allowed investigations of cellular structures with unprecedented optical resolutio

299 The bio-inspired metallic cellular structure (with an internal grid of large ceram

300 ormation of reproducible, high-resolution 3D cellular structures within a photopolymerizable hydrogel