ライフサイエンスコーパス: three-dimensional structure

1 by the Grad-Shafranov reconstruction of its three dimensional structure.

2 and-regulated molecular chaperone of unknown three-dimensional structure.

3 targets in virtue of both their sequence and three-dimensional structure.

4 cally disordered domains lack a well-defined three-dimensional structure.

5 gical role without possessing a well-defined three-dimensional structure.

6 m different directions are used to infer its three-dimensional structure.

7 functional proteins that lack a well-defined three-dimensional structure.

8 proximately 3 A thick) stacked in a vertical three-dimensional structure.

9 ne transmembrane unit; and ultimately, their three-dimensional structure.

10 in large destabilization and loss of unique three-dimensional structure.

11 e spatiotemporally controlled formation of a three-dimensional structure.

12 at exist and function without a well-defined three-dimensional structure.

13 ing another molecule, fold to a well-defined three-dimensional structure.

14 oles, and this can be conferred by a complex three-dimensional structure.

15 diction of functional residues given a known three-dimensional structure.

16 tes genome accessibility, functionality, and three-dimensional structure.

17 oth in terms of its primary sequence and its three-dimensional structure.

18 at the JCSG center, show strikingly similar three-dimensional structures.

19 al GxGD proteases (PSH and FlaK), with known three-dimensional structures.

20 e sheets, and which assemble into monolithic three-dimensional structures.

21 d sheets of paper into beautiful and complex three-dimensional structures.

22 ly plastic and do not appear to adopt single three-dimensional structures.

23 led navigational charts in the form of their three-dimensional structures.

24 ly of enzymes has been hampered by a lack of three-dimensional structures.

25 tudying how cell sheets give rise to complex three-dimensional structures.

26 on-corrected DFT methods in predicting their three-dimensional structures.

27 ogical function only after folding to unique three-dimensional structures.

28 es requires chromosomes to fold into complex three-dimensional structures.

29 y designed to self-assemble into predictable three-dimensional structures.

30 hmark of large protein complexes with solved three-dimensional structures.

31 tive proteins, FliC and FlgE, have different three-dimensional structures.

32 les carry out a function by forming specific three-dimensional structures.

33 arrangement of actin filaments into diverse three-dimensional structures.

34 lightly smaller than that estimated from the three-dimensional structure (20 A).

35 A three-dimensional structure (3D) model of Ss-RIOK-2 was

36 The three-dimensional structures adopted by proteins are pre

37 conformations, and it is not clear how this three-dimensional structure affects the UVPD fragmentati

38 X-ray free electron laser, we determine the three-dimensional structure and conformational landscape

39 A detailed picture of the three-dimensional structure and coordination modes of ci

40 third explores the relationship between the three-dimensional structure and dynamics of inteins and

41 The relationship between protein three-dimensional structure and function is essential fo

42 We combine the estimation of the unknown three-dimensional structure and image orientations in a

43 main of CsPABPN1 displays virtually the same three-dimensional structure and poly(A)-binding mode of

44 ive Suzuki cross-coupling reactions, and the three-dimensional structure and racemization kinetics we

45 Here we report on characterization of the three-dimensional structure and receptor specificity of

46 Although the two homologs share the same three-dimensional structure and recognize simple ligands

47 well-studied proteins, the biological role, three-dimensional structure and RNA-binding mode of plan

48 In prior studies, we described the three-dimensional structure and the extensive remodeling

49 The three-dimensional structure and the peptide-binding repe

50 also demonstrates the capacity to fold into three-dimensional structures and form catalysts in vitro

51 omputational techniques that compare protein three-dimensional structures and generate structural ali

52 To investigate the three-dimensional structures and macromolecular composit

53 mary sequence and function while maintaining three-dimensional structures and protein interactions.

54 ndary (helices, sheets and turns), tertiary (three-dimensional structure) and quaternary (specific pr

55 number of parameters needed to represent the three-dimensional structure, and a simplified way of com

56 Thermothelomyces thermophila, determined its three-dimensional structure, and demonstrated its use as

57 asive imaging due to its small size, complex three-dimensional structure, and embedded location withi

58 convert a two-dimensional primordium into a three-dimensional structure, and provide new directions

59 e MEP pathway, along with their discoveries, three-dimensional structures, and mechanisms.

60 biological macromolecules fold into complex three-dimensional structures, and ultimately to design n

61 are 104 interactions between proteins whose three dimensional structures are experimentally identifi

62 First-generation bricks used to create three-dimensional structures are 32 nucleotides long, co

63 m of action in TRP channels, high-resolution three-dimensional structures are indispensable, because

64 d biology are noncrystalline, and thus their three-dimensional structures are not accessible by tradi

65 ge protein families in prokaryotes for which three-dimensional structures are not available.

66 t known due to a lack of data concerning its three-dimensional structure as well as its mode of inter

67 Molecular modeling of the mIHF three-dimensional structure, based on the cocrystal stru

68 concerted motions in larger portions of the three-dimensional structure; both kinds of motions can b

69 The compounds have three-dimensional structures built up from corner-shared

70 d protein regions (IDRs) lack a well defined three-dimensional structure but often facilitate key pro

71 ly coaxed into a highly crystalline, porous, three-dimensional structure by coordination chemistry.

72 We then determined three-dimensional structures by cryo-EM and enhanced the

73 emical reactions make determination of their three-dimensional structures by diffraction methods a ch

74 Finally, through three-dimensional structure characterization, we reveale

75 f this material suggest that a new family of three-dimensional structures could exist, the 'harmonic

76 may be limited by masking of epitopes within three-dimensional structures (cryptotopes).

77 sine tRNA (tRNA(Pyl)) fold to near-canonical three-dimensional structures despite having noncanonical

78 ng method has potential applications for the three-dimensional structure determination of a range of

79 rimental demonstration of the combination of three-dimensional structure determination through PCDI w

80 The three-dimensional structure, determined at 2.30 A resolu

81 Although the three-dimensional structure did not form, their soluble

82 Protein three-dimensional structure dynamically changes in solut

83 To date, there is no three-dimensional structure for GLUT4.

84 Ebola virus-like particles, we determined a three-dimensional structure for the full-length glycopro

85 Three-dimensional structures for almost all H. jecorina

86 ilable together with experimentally resolved three-dimensional structures for most viral proteins.

87 ble this two-dimensional building block into three-dimensional structures for practical devices.

88 lants root systems are highly organized into three-dimensional structures for successful anchoring an

89 based affinity molecules that utilize unique three-dimensional structures for their affinity and spec

90 distances between labels, we reconstruct the three-dimensional structure formed by the target chemica

91 is a critical step toward understanding the three-dimensional structure-function relationship of the

92 The Pfs25 three-dimensional structure has remained elusive, hamper

93 milar to the two bacterial orthologues whose three-dimensional structures have been determined.

94 Three-dimensional structured illumination microscopy (3D

95 Here we use wide-field time-lapse and three-dimensional structured illumination microscopy (3D

96 Using three-dimensional structured illumination microscopy and

97 Three-dimensional structured illumination microscopy ind

98 pectral confocal fluorescence microscopy and three-dimensional structured illumination microscopy of

99 We used three-dimensional structured illumination microscopy to

100 mosaic virus, while superresolution imaging (three-dimensional structured illumination microscopy) of

101 oth apoptotic cells and tumour tissues using three-dimensional structured illumination microscopy.

102 adopt a higher-order structure, as shown by three-dimensional structured illumination microscopy.

103 En2HD loses its native three-dimensional structure in micellar environments but

104 in solution and in crystals and describe its three-dimensional structure in several ligand-free and l

105 active full-length CDNF and to determine its three-dimensional structure in solution.

106 d synthesis of nanocrystals with controlled, three-dimensional structures in a desired direction, and

107 Upon heating, the LCE films form various three-dimensional structures in agreement with theoretic

108 ctions to the target proteins with available three-dimensional structures in the PDB.

109 Here we report a hierarchical three-dimensional structure, in which all of PANI nanofi

110 r interpenetrating flexible electronics with three-dimensional structures, including (1) monitoring i

111 trometry (MS) is powerful to provide protein three-dimensional structure information but difficulties

112 CRs and provide, to our knowledge, the first three-dimensional structure information for a CCR from a

113 nformation required to determine a proteins' three dimensional structure is contained within its amin

114 P044 and mGlu7's Venus flytrap domain, whose three-dimensional structure is already known, will facil

115 have been biochemically characterized and no three-dimensional structure is available.

116 However, its three-dimensional structure is unavailable and the molec

117 ructure-function relationships; however, the three-dimensional structure is unknown.

118 sed by the limitations of low-resolution RNA three-dimensional structures, it becomes a critical chal

119 with multiple tissue-specific cell types and three-dimensional structure mimicking native organs.

120 broad eastward equatorial jet with a complex three-dimensional structure mixed with time variability.

121 We determine a three-dimensional structure model through electron tomog

122 We prepared synthetic data that represent three-dimensional structures modeled after biological co

123 Three-dimensional structure modeling analysis found that

124 Three dimensional structure models of LaCADS and Ocimum

125 As a result, RNA aptamers can fold into three-dimensional structures more complex than those of

126 and in vivo investigations to rationalize a three-dimensional structure obtained in non-native condi

127 tional simulation revealed alteration in the three dimensional structure of the pri-miR-497 195 that

128 noparticles uniformly distributed within the three dimensional structure of the wood.

129 ome from the primary sequences, secondary or three dimensional structures of macromolecules.

130 trate the ability of PFClust to classify the three dimensional structures of protein domains, using a

131 The first three-dimensional structure of a DP ((+)-pinoresinol-for

132 Here we present the first three-dimensional structure of a GABAAR, the human beta3

133 Here we report the first three-dimensional structure of a Gram-positive Type IV p

134 Here we report for the first time the three-dimensional structure of a mannose 6-phosphate rec

135 d-protein assembly at 8 A resolution and the three-dimensional structure of a native HIV-1 core by cr

136 Electron cryo-microscopy has revealed the three-dimensional structure of a potassium channel that

137 function, it is generally accepted that the three-dimensional structure of a protein determines its

138 The three-dimensional structure of a protein-protein complex

139 Determining the three-dimensional structure of a small molecule-protein

140 e report here the activity, spectroscopy and three-dimensional structure of a starch-active LPMO, a r

141 The elucidation of the three-dimensional structure of an alphaGal-containing N-

142 Here we report the three-dimensional structure of an intact human gamma-sec

143 Here we determine the three-dimensional structure of an organometallic complex

144 on microscopy to unambiguously determine the three-dimensional structure of APBs in magnetite.

145 However, the inherently three-dimensional structure of block copolymer microdoma

146 The three-dimensional structure of BtGH115A reveals that BtG

147 s for these diseases, we have determined the three-dimensional structure of CAP-Gly (cytoskeleton-ass

148 However, the three-dimensional structure of chromatin and its reprogr

149 beta-Rb2 Al2 B2 O7 has a three-dimensional structure of corner-shared Al(BO3 )3 O

150 RbMgCO3F possesses a three-dimensional structure of corner-shared Mg(CO3)2F2

151 While a nearly complete three-dimensional structure of cpSRP43 has been determin

152 a tandem mass spectrometer to determine the three-dimensional structure of cryogenically cooled prot

153 pends crucially on a better understanding of three-dimensional structure of DNA-nanocrystal-hybridize

154 Here we report the three-dimensional structure of F-actin at a resolution o

155 rks on the one-dimensional genome encode the three-dimensional structure of fine-scale regulatory int

156 wo Cys-containing metal binding sites in the three-dimensional structure of full-length MerF provides

157 The three-dimensional structure of gallin, which is the firs

158 We constructed a new model for the predicted three-dimensional structure of gK, revealing that the gK

159 Using a three-dimensional structure of gonococcal TbpA, we inves

160 lved in DNA coordination, our results on the three-dimensional structure of HOP2 provide key informat

161 We report the three-dimensional structure of human interferon alpha-2A

162 We report the three-dimensional structure of human neonatal Fc recepto

163 We report herein the three-dimensional structure of LBQ657 in complex with hu

164 Here, we have explored the three-dimensional structure of Listeria actin tails in X

165 ve implications for efforts to determine the three-dimensional structure of mammalian NAGS.

166 The three-dimensional structure of MbdR has been solved reve

167 In this study, we determined the three-dimensional structure of MfVIA, examined its membr

168 l and kidney slice two-photon imaging of the three-dimensional structure of mouse podocytes, we found

169 Determining the three-dimensional structure of myoglobin, the first solv

170 Work towards controlling the three-dimensional structure of peptoids, from the confor

171 The three-dimensional structure of Phl p 3 was solved by X-r

172 ccurately, and reproducibly characterize the three-dimensional structure of protein therapeutics.

173 Predicting the three-dimensional structure of proteins from their amino

174 ile being expanded to explicitly include the three-dimensional structure of proteins.

175 gle particle image analysis to determine the three-dimensional structure of recombinant full-length C

176 Here, we report the three-dimensional structure of Rv0315 at 1.70 A resoluti

177 he square-shaped cytoplasmic assembly of the three-dimensional structure of RyR2.

178 to the site of the original mutation in the three-dimensional structure of the 30S ribosomal subunit

179 To obtain insight into the three-dimensional structure of the alpha4-alpha4 binding

180 The experimentally determined three-dimensional structure of the BT_1012 protein confi

181 Moreover, it was found that the intrinsic three-dimensional structure of the BTH6 thionin domain p

182 ere, by high-resolution cryo-EM, we show the three-dimensional structure of the capsid-associated teg

183 hesized polysaccharides and establishing the three-dimensional structure of the cell wall.

184 Disruption of the three-dimensional structure of the CFTR gene by depletio

185 We first define the boundary and the three-dimensional structure of the claustrum based on a

186 b-cellular element method to account for the three-dimensional structure of the crypt, external regul

187 Unexpectedly, the three-dimensional structure of the DeltaL1 TEAD DBD reve

188 s that these flanking nucleotides change the three-dimensional structure of the DNA-binding site, the

189 The three-dimensional structure of the dynein-Lis1 complex s

190 The three-dimensional structure of the enzyme and two enzyme

191 We present here the three-dimensional structure of the full-length Xyn30D at

192 Unraveling the fine-scale three-dimensional structure of the genome and its impact

193 The three-dimensional structure of the genome is an importan

194 Whereas our earlier work established the three-dimensional structure of the highly conserved DNA-

195 econstruct with unprecedented resolution the three-dimensional structure of the huge compound eye of

196 1, predicted to be KIR contacts based on the three-dimensional structure of the human KIR3DL1-HLA-Bw4

197 sues we generated a theoretical model of the three-dimensional structure of the LA loop as per the re

198 The three-dimensional structure of the LytA/PG complex provi

199 orm disulfide bonds that are crucial for the three-dimensional structure of the MD-2-related lipid re

200 f DRC3 and the C terminus of DRC4 within the three-dimensional structure of the N-DRC in Chlamydomona

201 We describe the unusual three-dimensional structure of the N-terminal Q domain o

202 The three-dimensional structure of the NH2-terminal region h

203 including AD)-Cdk5 complex, we simulated the three-dimensional structure of the p39 AD-Cdk5 complex a

204 Here we solved by NMR the three-dimensional structure of the p75-TM-WT and the fun

205 tyrosine nitrosylation leading to an altered three-dimensional structure of the PDI due to a decrease

206 The three-dimensional structure of the PMCA pump has not bee

207 mode allows for a better utilization of the three-dimensional structure of the porous material.

208 Here we report characterization of the three-dimensional structure of the PPARgamma2 locus afte

209 ce with sufficient accuracy to determine the three-dimensional structure of the protein complexes.

210 The recently solved three-dimensional structure of the protein lpg2210 from

211 We determined the three-dimensional structure of the protein that showed a

212 The three-dimensional structure of the protein was solved by

213 The three-dimensional structure of the Sar1 lattice was reco

214 , we mapped many of these mutations onto the three-dimensional structure of the SET domain and notice

215 We report here a detailed three-dimensional structure of the SGQs formed by lipoph

216 inter-residue interaction network within the three-dimensional structure of the trimeric GP.

217 The three-dimensional structure of the TsdB-TsdA fusion prot

218 The three-dimensional structure of the vanilloid receptor 1

219 We report here the three-dimensional structure of the Xyn10C N-terminal reg

220 Significant changes in the three-dimensional structure of these toxins are necessar

221 Although the three-dimensional structure of Tom40 has not been determ

222 The three-dimensional structure of TRPM1 dimers is character

223 tic analyses indicate that Mst resembles the three-dimensional structure of Tubulin monomers and migh

224 ll grow in vitro if we replicate the complex three-dimensional structure of turtle skin.

225 The overall three-dimensional structure of UmAbf62A and PaAbf62A rev

226 g reactions with milk proteins stabilize the three-dimensional structure of yogurt.

227 Thirteen three-dimensional structures of animal, plant, and proka

228 However, a lack of three-dimensional structures of bile acid transporters h

229 The large majority of three-dimensional structures of biological macromolecule

230 The three-dimensional structures of both enzymes were determ

231 bChem3D, a resource derived from theoretical three-dimensional structures of compounds in PubChem, as

232 Our integrated approach reveals the three-dimensional structures of DNA that are essential f

233 micin in atomic detail, and neither have any three-dimensional structures of domains from the human m

234 elationships through hit expansion guided by three-dimensional structures of enzyme-inhibitor complex

235 microscopy and tomography, and reconstructed three-dimensional structures of fifty of sixty sensory c

236 is of these mutations based on the available three-dimensional structures of gp120/gp41 or their comp

237 Mapping of cleavage sites onto three-dimensional structures of HEPEX cis-dimer predicte

238 putational fitting approaches, we determined three-dimensional structures of human integrin alphaIIbb

239 The three-dimensional structures of large biomolecules impor

240 The three-dimensional structures of macromolecules and their

241 excellent tool for resolving high-resolution three-dimensional structures of membrane proteins in a l

242 egy in structural biology for characterizing three-dimensional structures of protein assemblies and f

243 our updated (PS)(2) web server predicts the three-dimensional structures of protein complexes based

244 ntal information on changes in affinity with three-dimensional structures of protein-ligand complexes

245 Knowledge of the three-dimensional structures of proteins and other biolo

246 Three-dimensional structures of ribosomal particles from

247 cing may offer a faster way to determine the three-dimensional structures of RNA molecules.

248 first approach to predict from sequence the three-dimensional structures of single stranded (ss) DNA

249 pot) assays were analyzed in relation to the three-dimensional structures of the capsid (C) and E pro

250 s with cryo-electron tomography, we acquired three-dimensional structures of the chloroplast in its n

251 ting anti-arrhythmic drugs requires detailed three-dimensional structures of the KCNQ1/KCNE1 complex,

252 The three-dimensional structures of the separate domains of

253 However, the three-dimensional structures of the stages between unint

254 First, the three-dimensional structures of the two T. castaneum SKR

255 Therefore, information about the three-dimensional structures of TMA-producing enzymes is

256 For these, a number of three-dimensional structures of transpososomes (transpos

257 Mapping of these fitness values onto three-dimensional structures of viral proteins offers a

258 The three-dimensional structure ofSdGluc5_26A adopts a stabl

259 tion, and its ability to produce fine-scale, three-dimensional structure over large areas quickly str

260 ganize individual nanoscopic components into three-dimensional structures over a large scale.

261 fter a comprehensive comparison of available three-dimensional structures, particularly of FDPs with

262 double helix embodies the central role that three-dimensional structures play in understanding biolo

263 neering can be used to modify nanowires into three dimensional structures, relevant to a range of app

264 on between the sequence of a protein and its three-dimensional structure remains largely unknown.

265 al cellular processes, but determining their three-dimensional structures remains challenging.

266 , synthesis of nanocrystals with controlled, three-dimensional structures remains challenging.

267 phocholine, MIR-WaaG was observed to adopt a three-dimensional structure remarkably similar to the se

268 Three-dimensional structures showed that this domain in

269 We show that LGN, which adopts a three-dimensional structure similar to cadherin-bound ca

270 Eukaryotic genomes are folded into three-dimensional structures, such as self-associating t

271 Mg534 is a 4,6-dehydratase 5-epimerase; its three-dimensional structure suggests that it belongs to

272 Computer modeling of urotoxin's three-dimensional structure suggests the presence of the

273 f an internal void bounded by a well-defined three-dimensional structured surface.

274 ubstitutions by this strategy and describe a three-dimensional structure that accounts for the accomm

275 thin the membrane gives rise to an intricate three-dimensional structure that is nonetheless extremel

276 teractions are required for the formation of three-dimensional structures that are the building block

277 Consistent with its highly-conserved three-dimensional structure, the SH2 domain of M. brevic

278 al cues (say, converging lines) and the real three-dimensional structures they represent (a surface r

279 microenvironment conducive to the growth of three-dimensional structured tissue.

280 er vinelandii FeS II and have determined its three-dimensional structure to 2.1 A resolution by X-ray

281 onarily unrelated in amino acid sequence and three-dimensional structure to the TopoI-CTD found in th

282 of protein molecules must fold into defined three-dimensional structures to acquire functional activ

283 d for the development and maintenance of the three-dimensional structures under continuous-flow condi

284 6 amino-acid polypeptide, presents a compact three-dimensional structure, utilising a fold that recur

285 The three-dimensional structure was determined by NMR and MS

286 inantly produced in Pichia pastoris, and the three-dimensional structure was solved by NMR.

287 er is a simple molecular object with defined three-dimensional structure, where a ferric ion and four

288 on is inextricably linked to a well defined, three-dimensional structure, which is determined by the

289 e function of a protein is determined by its three-dimensional structure, which is formed by regular

290 We present here its three-dimensional structure, which shows the expected bi

291 otein and peptide assemblies with predefined three-dimensional structures, which can serve as scaffol

292 Proteins fold into three-dimensional structures, which determine their dive

293 However, the devices are reliant on three-dimensional structures, which limits further chara

294 Enzymes fold into unique three-dimensional structures, which underlie their remar

295 tially diverse side chains provides a unique three-dimensional structure with a high degree of functi

296 these issues in the context of the genome's three-dimensional structure with an emphasis on events o

297 nd catalysis relates to the determination of three-dimensional structures with atomic-level precision

298 of superlattices, yielding access to complex three-dimensional structures with more than 30 different

299 atomic model to represent the low-resolution three-dimensional structure, with isotropic Gaussian com

300 otropic two-dimensional layered network to a three-dimensional structure without a structural transit