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1 nal methods to describe non-native states at atomic resolution.
2 he molecular basis of Alzheimer's disease at atomic resolution.
3 n only if the protein structure is solved to atomic resolution.
4 mplex DNA origami object to be determined to atomic resolution.
5 neous pore assembly for the AMP maculatin at atomic resolution.
6 spectroscopic tool to explore molecules with atomic resolution.
7 eraction site of ligand-protein complexes at atomic resolution.
8 ic details of the two-metal-ion catalysis at atomic resolution.
9 peptide-activated GLP-1R-Gs complex at near atomic resolution.
10 filament formation of mouse ASC in vitro at atomic resolution.
11 on diffraction to determine the structure at atomic resolution.
12 onconducting states need to be determined at atomic resolution.
13 ligand, and solvent are described with full atomic resolution.
14 aracterize dynamics in diverse RNA motifs at atomic resolution.
15 strain fields in three dimensions with near-atomic resolution.
16 olipin/cytochrome c interaction interface at atomic resolution.
17 d on polymeric microtubules are not known at atomic resolution.
18 s of cryo-electron microscopy maps with near-atomic resolution.
19 of individual platinum nanocrystals at near-atomic resolution.
20 with an anti MUC-1 antibody are reported at atomic resolution.
21 rded and structures to be determined at near-atomic resolution.
22 the one-dimensional boundary states down to atomic resolution.
23 2-gold atom NP (Au102NP)] has been solved to atomic resolution.
24 etermine the 3D structure of nanocrystals at atomic resolution.
25 ed RNAs and solved their X-ray structures at atomic resolution.
26 the translocating peptide inside the pore at atomic resolution.
27 show the consequences of dehydration at near-atomic resolution.
28 ture determination of macromolecules at near-atomic resolution.
29 ated and its crystal structure determined at atomic resolution.
30 1 and an open complex with product fucose at atomic resolution.
31 full-tilt series in electron diffraction to atomic resolution.
32 terization of both structure and dynamics at atomic resolution.
33 ty filter gating in Kv11.1 channels, at near atomic resolution.
34 structure of edge and screw dislocations at atomic resolution.
35 on of the "on" and "off" switching of Ras at atomic resolution.
36 ned from atomic force microscopy images with atomic resolution.
37 not been tested in controlled experiments at atomic resolution.
38 pre-catalytic B complex spliceosome at near-atomic resolution.
39 an antibodies have not been characterized at atomic resolution.
40 ecular interface remain poorly understood at atomic resolution.
41 FIN219-FIP1 while binding with substrates at atomic resolution.
42 termined by cryo-electron microscopy at near-atomic resolution.
43 r structure, kinetics, and thermodynamics at atomic resolution.
44 ponding spectra, which can be interpreted at atomic resolution.
45 systems with back action can be studied with atomic resolution.
46 se dimer by electron cryo-microscopy at near-atomic resolution.
47 eikastus rhodopsin 2 (KR2), was resolved at atomic resolution.
48 ture and surface termination of the NCs with atomic resolution.
49 mer --> dimer --> membrane pore formation at atomic resolution.
50 ctural and dynamic description of CBP-ID4 at atomic resolution.
51 cleotide-driven structural changes in p97 at atomic resolution.
52 , and atomic force microscopy--we report the atomic-resolution (0.5 A) structures of three amyloid po
53 t exciting macromolecular assemblies at near-atomic resolution (3-4.5A), providing biological phenome
56 U1 sub-structures, which together reveal at atomic resolution an almost complete network of protein-
57 hodology established here can be applied for atomic resolution analysis of dynamics in other microtub
58 However, using a combination of advanced atomic-resolution analytical techniques, our data for th
59 diffraction from aligned molecules provides atomic resolution and allows for the retrieval of struct
60 broad approach provided detailed insights at atomic resolution and allows now to identify key residue
62 w being used to determine structures at near-atomic resolution and have great promise in molecular ph
63 n by cryo-electron microscopy has approached atomic resolution and helped solve structures of large m
64 the cryo-EM structure of mature JEV at near-atomic resolution and identify structural elements that
65 nformational landscapes of Abeta monomers at atomic resolution and provide insight into the early sta
66 as played a major role given its unique near-atomic resolution and sensitivity to the dynamics that u
67 characterize internal motions in proteins at atomic resolution and with time scale sensitivity rangin
68 tion of ICP27 with Aly/REF was elucidated at atomic resolution, and it was shown that three ICP27 res
69 e focused on structural models determined at atomic resolution, and may miss out interesting patterns
70 how many of the SRP-ribosome interactions at atomic resolution, and suggest how the polypeptide-bindi
71 d 7- member rings are directly observed with atomic resolution, and their energy landscape is investi
72 ependency of the intensities associated with atomic-resolution annular dark field imaging line scans
76 uctures of overlapping ECD fragments at near atomic resolution, built a model of the full ECD, and di
78 as multi-component ribosomal assemblies with atomic resolution, but is inadequate for disordered syst
79 tructural and compositional information with atomic resolution, but its use is restricted to thin, so
80 t the structure determination of a Au68NP at atomic resolution by aberration-corrected transmission e
81 of the 80alpha and SaPI1 procapsids to near-atomic resolution by cryo-electron microscopy, and show
83 ion, we mapped the HSA-Abeta interactions at atomic resolution by examining the effects of HSA on Abe
84 This isomerization has been characterized at atomic resolution by quantitatively interconverting the
85 roscope (STEM) has emerged as a key tool for atomic resolution characterization of materials, allowin
86 reported here establishes the foundation for atomic-resolution characterization of a broad range of a
88 , we report the structure determined by near-atomic resolution cryo-EM of Frh with and without bound
92 le protein structure determination from near-atomic-resolution cryo-electron microscopy (cryo-EM) map
94 efficiency-key bottlenecks in applying near-atomic-resolution cryo-EM to a broad range of protein sa
103 terize these dynamic structures by combining atomic-resolution crystal structures with lower-resoluti
108 iterative refinement promises to provide an atomic resolution description of the alternate conformat
109 etermined at 2.2-A resolution and provide an atomic-resolution description of the architecture of its
111 mples are heterogeneous, which has prevented atomic-resolution determination of their structures and
112 sh an approach, for the first time, to probe atomic resolution dynamic profiles of a microtubule-asso
115 al approach to obtain a rigorously validated atomic resolution electron cryo-microscopy structure.
116 d scanning transmission electron microscopy, atomic resolution electron energy loss spectrum-mapping
117 We determined the STIV structure using near-atomic resolution electron microscopy and X-ray crystall
118 e the reactors during the meltdowns based on atomic-resolution electron microscopy of CsMPs discovere
119 While electron microscopes can now provide atomic resolution, electron beam induced specimen damage
120 nformers by cryo electron microscopy to near-atomic resolution, elucidating the molecular basis of he
121 ty to image light elements in soft matter at atomic resolution enables unprecedented insight into the
124 n, we successfully construct and validate an atomic resolution ensemble of human immunodeficiency vir
126 ational molecular dynamics (MD) to determine atomic resolution ensembles of biomolecules require the
127 -defined hydrocarbon binding pocket provides atomic resolution evidence for the extended lipid anchor
128 en previously observed in Raman spectra, but atomic-resolution evidence for this interaction remains
130 tunnelling maps of spin-resolved states with atomic resolution, finding interference processes from w
134 f directly obtaining structural data at near-atomic resolution, for many molecules the attainable res
136 mics simulations of biomolecular crystals at atomic resolution have the potential to recover informat
137 nts in vitro and in cells, revealing at near-atomic resolution how subunits and filaments come togeth
141 ssion electron microscopy (STEM) has enabled atomic resolution imaging at significantly reduced beam
146 on with bicrystal experiments and systematic atomic-resolution imaging, we are now able to pinpoint i
147 ty in the subunit-subunit interface, seen at atomic resolution in crystals, can explain the large var
149 While NMR provides structural information at atomic resolution, increased spectral complexity, chemic
150 Despite these advances, however, obtaining atomic resolution information describing the higher leve
152 exemplify the uniqueness of NMR in providing atomic resolution information into key dynamic processes
155 discovery benefits immensely from access to atomic-resolution information, structure-based virtual s
157 se molecular dynamics simulations to provide atomic-resolution insight into the influence of choleste
158 These data provide long sought after near-atomic resolution insights into how MACPF/CDC proteins a
160 -state NMR is a powerful technique to obtain atomic-resolution insights into the structure and dynami
161 a three-dimensional interaction network with atomic-resolution interaction interfaces, we find that d
162 nsional protein interactome network with the atomic-resolution interface resolved for each interactio
164 isordered structures such as dislocations at atomic resolution is expected to find applications in ma
165 ing the process of oxygen ion migration with atomic resolution is highly desirable for designing nove
167 t NCP has been studied by crystallography at atomic resolution, little is known about the structures
168 ters whose computational investigation at an atomic resolution may not be currently feasible using co
169 ent strategy to inactivate TNFalpha, but the atomic-resolution mechanism of its inactivation remains
170 lly exfoliated samples, as confirmed by both atomic resolution microscopic imaging and electrical tra
171 olecular dynamics simulations, we present an atomic resolution model of human RNF169 binding to a ubi
172 ectron microscopy (cryo-EM), we establish an atomic resolution model of the RSV CA tubular assembly u
176 enic analysis, guided by homology mapping in atomic resolution models of Kir2.1, Kir2.3, and Kir4.1/5
178 vances in molecular simulations provide near-atomic-resolution models of the dynamics of the organiza
180 can be tuned by protein engineering to allow atomic-resolution NMR studies of specific protein struct
181 otosystem II (PSII) from cyanobacteria at an atomic resolution, no corresponding structure of the euk
183 rystal structure of the material, as well as atomic-resolution observation of the carbon atom positio
185 structure for the apo form of AgmNAT with an atomic resolution of 2.3 A, which points towards specifi
186 cryo-electron microscopy structures at near-atomic resolution of Hsp104 in different translocation s
188 methods to determine the structures at near-atomic resolution of the influenza hemagglutinin trimer,
189 of the HK signal transduction mechanism with atomic resolution on a full-length construct lacking onl
193 scopy structure of ASC(PYD) filament at near-atomic resolution provides a template for homo- and hete
194 ructure of an RING-between-RING E3 ligase at atomic resolution, providing insight into this disease-r
196 nnelling microscopy (STM) investigation with atomic resolution revealed previously unknown surface fe
197 we describe the urea transport mechanism at atomic resolution, revealed by unrestrained microsecond
200 y ex-situ investigations, allowing the first atomic resolution scanning transmission electron microsc
201 ly weak superstructure phenomena revealed by atomic-resolution scanning TEM (STEM) and single-crystal
203 and is corroborated by aberration-corrected atomic-resolution scanning transmission electron microsc
208 he thermodynamic contributions to binding at atomic resolution showing significant differences in the
209 rful tool for studying molecular dynamics at atomic resolution simultaneously for a large number of n
213 our knowledge, our study presents the first atomic resolution structural characterization of a clien
214 e, adequate methodologies reliably providing atomic resolution structural details are still lacking.
218 ein interaction data with the specificity of atomic-resolution structural information derived from co
219 approach uses multiple-sequence alignments, atomic-resolution structural information, and riboswitch
221 ctron microscopy, here we determine the near-atomic resolution structure of a human APC/C-MCC complex
224 DNA to 2.3 A resolution providing the first atomic resolution structure of any TIA protein RRM in co
231 We expect the technique to pave the way for atomic-resolution structure analysis applicable to a wid
233 our knowledge, this study reports the first atomic-resolution structure of a microtubule-associated
235 divided into three main types, and the first atomic-resolution structure of a type III RNA-guided imm
239 ving Cys367 in keratin 14 (K14) occurs in an atomic-resolution structure of the interacting K5/K14 2B
240 ay/neutron (XN) crystallography to obtain an atomic-resolution structure of the protease triple mutan
241 tering and microscopy data, to determine the atomic-resolution structure of the recently discovered p
242 idal pores under certain conditions, but the atomic-resolution structure of these pores is unknown.
243 an X-ray free-electron laser, leading to an atomic-resolution structure with accurate rotamer assign
244 EM) are enabling generation of numerous near-atomic resolution structures for well-ordered protein co
245 systems, new methods are required to obtain atomic resolution structures from biological material un
246 ge datasets are required for achieving quasi-atomic resolution structures of biological complexes.
249 e we review recent atomic-resolution or near-atomic resolution structures of NSF and of the 20S super
250 is feasible to use cryo-EM to determine near-atomic resolution structures of protein complexes (<500
254 tron microscropy (cryo-EM) to determine near-atomic resolution structures of the human PIC in a close
255 uence-dependent nuclear factors require near-atomic resolution structures of the nucleosome core cont
256 chanism of cycloaddition, we have determined atomic resolution structures of the pyridine synthases i
259 odeling of actin-tropomyosin, and docking of atomic resolution structures of tropomyosin to actin fil
263 copy is a prime technique for characterizing atomic-resolution structures and dynamics of biomolecula
264 o-EM) has achieved the determination of near-atomic-resolution structures by allowing direct fitting
272 ents in solution NMR spectroscopy facilitate atomic resolution studies of sparsely populated, transie
273 antly reduced this size limitation, enabling atomic-resolution studies of molecular machines in the 1
274 We have characterized these interactions at atomic resolution suggesting that these compounds steric
275 of GroEL-bound substrates and to describe at atomic resolution the events between substrate binding a
276 The full-length structure visualizes at atomic resolution the N-terminal HerA-ATP synthase domai
277 nd out, we use here in-cell NMR to follow at atomic resolution the thermal unfolding of a beta-barrel
278 ur results are instrumental in explaining at atomic resolution the weakened ability of dexamethasone
279 ron microscopy to measure with nanoscale and atomic resolution the widths, motion, and topological st
281 ive state (C/O), this work recapitulates, at atomic resolution, the key conformational changes of a p
284 lizes an antibiotic bound to any ribosome at atomic resolution, this establishes cryo-EM as a powerfu
285 ex situ and in situ electron microscopy with atomic resolution to show that the modular palladium-cer
286 t the X-ray crystal structure of ProTx-II to atomic resolution; to our knowledge this is the first cr
289 quent strain relaxation, which we show using atomic-resolution transmission electron microscopy to oc
291 nanoparticles has been limited by less than atomic resolution typically achieved by environmental tr
292 icroscopy (cryoEM) and led to a wave of near-atomic resolution (typically approximately 3.3 A) recons
293 ral major capsid protein, elucidated at near-atomic resolution using cryo-electron microscopy, is str
294 materials physics that can now be studied at atomic-resolution via transmission electron microscopy o
297 f mature Japanese encephalitis virus at near-atomic resolution, which reveals an unusual "hole" on th
298 enforcing symmetry facilitates reaching near-atomic resolution with fewer particle images, it unfortu
299 (STEM) provides structure and composition at atomic resolution, with the sensitivity to directly reve
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