コーパス検索結果 (1語後でソート)
通し番号をクリックするとPubMedの該当ページを表示します
1 e proteins and are indispensable reagents in structural biology.
2 copists to break into the world of molecular structural biology.
3 equilibrium through rapid kinetics and X-ray structural biology.
4 pt, and this remains an immense challenge in structural biology.
5 ocalization in the cell is central to modern structural biology.
6 als chemistry, geochemistry, biophysics, and structural biology.
7 ts in a complex interact is a cornerstone of structural biology.
8 ctrometry (HDX-MS) is now common practice in structural biology.
9 data from diverse experimental approaches in structural biology.
10 highlight emerging challenges in nucleosome structural biology.
11 e field of G protein-coupled receptor (GPCR) structural biology.
12 rane-spanning proteins is a key challenge in structural biology.
13 es to bridge knowledge gaps between cell and structural biology.
14 to describe with the established concepts of structural biology.
15 emistry, nanoscale physics, nanomedicine and structural biology.
16 eering research in molecular recognition and structural biology.
17 by advances in computational, molecular and structural biology.
18 res of proteins remains a major challenge in structural biology.
19 , which have resulted in amazing progress in structural biology.
20 is an outstanding challenge in the field of structural biology.
21 to characterize with existing techniques in structural biology.
22 o-EM structure determination is transforming structural biology.
23 ding an exceptionally challenging target for structural biology.
24 s to advances in biochemistry, genetics, and structural biology.
25 me fashion, greatly enabling applications in structural biology.
26 multidomain proteins is still a challenge in structural biology.
27 s to be used to address problems relevant to structural biology.
28 osomes is still one of the key challenges in structural biology.
29 such as UCSF Chimera, are a standard tool in structural biology.
30 dvances in G protein-coupled receptor (GPCR) structural biology.
31 X-ray lasers for advancing the frontiers of structural biology.
32 esolution EM maps should prove invaluable in structural biology.
33 ns in atomic detail is a major challenge for structural biology.
34 tance constraints is an important problem in structural biology.
35 r complexes are an important new approach to structural biology.
36 ir native environment is the ultimate aim of structural biology.
37 plant Striga hermonthica using chemical and structural biology.
38 of activity in computational biophysics and structural biology.
39 epresents a grand challenge in chemistry and structural biology.
40 s, which opens perspectives as a new tool in structural biology.
41 l tool in the advancement of high-resolution structural biology.
42 heir properties for specific applications in structural biology.
43 topology needed for biological activity and structural biology.
44 fficult to apply to them standard methods of structural biology.
45 recent advances in 7 transmembrane receptor structural biology.
46 implementation and application of MicroED in structural biology.
47 one of the major challenges in computational structural biology.
48 ontribute to benchmarking smFRET for dynamic structural biology.
49 ding their utility for different problems in structural biology.
50 eported here may enable many applications in structural biology.
51 ensively pursued, facilitated by advances in structural biology.
52 used together to tackle complex problems in structural biology.
53 mains a major bottleneck in membrane protein structural biology.
54 cular complexes has changed the landscape of structural biology.
55 ein-protein and protein-DNA networks and for structural biology.
56 zole substituents, their exact binding mode, structural biology, 3D conformations, and in general the
57 e twentieth anniversary of terpenoid cyclase structural biology: a trio of terpenoid cyclase structur
58 that employs methodologies transplanted from structural biology, adapted to giant supramolecular asse
59 use in all areas of cell research, including structural biology, advanced microscopy, and intracellul
62 ed protein profiling, yeast mutagenesis, and structural biology allowed us to decipher significant di
63 s of proteins could make a powerful tool for structural biology and be useful for proteomics and imag
71 ome a powerful technique at the interface of structural biology and cell biology, due to its unique a
72 nding their pharmacology through the lens of structural biology and describe how this knowledge sugge
73 ques that have led to these advances in GPCR structural biology and discuss how they may influence th
74 ing application of gas-phase measurements in structural biology and drug discovery, the factors that
76 on of datastores, e.g. SBGrid Consortium for structural biology and Gene Expression Omnibus (GEO) for
77 As such, this work combines knowledge from structural biology and genomics, and suggests a new path
78 ing biochemical reconstitution combined with structural biology and high-resolution cellular imaging.
80 Here, we review the recent advances in TRPM8 structural biology and investigate the molecular princip
82 can look forward to complementary data from structural biology and molecular simulations combining t
83 in optical and electron microscopic imaging, structural biology and molecular techniques have facilit
84 ral anesthetics, coincident with progress in structural biology and molecular, cellular, and systems
86 ntral question to G protein coupled receptor structural biology and pharmacology: What chemical featu
89 on of biological, pharmacological, chemical, structural biology and protein network data, it provides
90 ocused on enabling a deeper understanding of structural biology and providing new structural views of
91 the power of cellular tomography for in situ structural biology and sheds light on a very abundant cl
92 iders recent advances in glycosyltransferase structural biology and site-directed mutagenesis, pathwa
96 strategy will help advance insights into the structural biology and systems biology of cell signaling
97 ew, we provide a brief introduction into RNA structural biology and then describe how RNA structures
100 ing: functional assays, biophysical studies, structural biology, and biochemical high throughput scre
102 Experimental information from microscopy, structural biology, and bioinformatics may be integrated
103 used a combination of immunological assays, structural biology, and cheminformatics to construct a r
104 rvesting and nanoscale energy transport, RNA structural biology, and immune receptor signaling, with
105 ances in genetics, microscopy, biochemistry, structural biology, and physical characterization method
107 cell fractionation to immunoprecipitation to structural biology, and the multidisciplinary approaches
108 dge of the evolutionary biology, immunology, structural biology, and virology of influenza virus is i
110 aluable complementary method in the field of structural biology, applications concerning membrane pro
111 model for the TSHR we applied an integrated structural biology approach combining computational tech
112 an integrated transcriptomic, proteomic, and structural biology approach to demonstrate that the leth
113 the power and versatility of this synthetic structural biology approach to probing molecular and cel
115 we analyze PMT-MIR domains by an integrated structural biology approach using X-ray crystallography
127 , an organism that has resisted conventional structural-biology approaches, to obtain atomic models o
129 is review describes how advances in cell and structural biology are uncovering in growing detail how
130 e follows the broader, 50-year trajectory of structural biology, as I could rarely resist opportuniti
131 nd straightforward tool for biochemistry and structural biology, as it does not recur to nitrogen-15
133 owing opportunities for integrative, dynamic structural biology at the atomic scale, contending there
134 acterization of 17 recombinant proteins with structural biology-based investigations in the context o
135 oteins have been one of the 'blind spots' in structural biology because they are generally very hydro
136 ections, such as directed material assembly, structural biology, biocatalysis, DNA computing, nanorob
137 ative program combining medicinal chemistry, structural biology, biochemical testing, and microbiolog
139 l enable future applications in the areas of structural biology, biophysics, and biopharmaceutical ch
140 s fields in natural science, as for instance structural biology, biophysics, and molecular nanotechno
141 with possible application in fields such as structural biology, biophysics, synthetic biology and ph
142 has important applications in the fields of structural biology, biotechnology, and biopharmaceutics.
143 of workflows for applications in comparative structural biology, biotherapeutic analysis, and high th
144 perties not only in the traditional field of structural biology but also in the growing research area
145 lar couplings (RDCs) are important probes in structural biology, but their analysis is often complica
146 likely accelerate the development of dynamic structural biology by identifying transient conformation
147 the saccharide detergents widely employed in structural biology can cause unfolding of membrane prote
148 ombination of phylogenetics, bioinformatics, structural biology, cell biology, and biochemistry, we h
149 merging tools in a variety of fields such as structural biology, cell imaging, and drug discovery.
150 rse research fields including, synthetic and structural biology, cellular reprogramming and functiona
151 of scientists including those interested in structural biology, cloning, glycobiology and chemical b
154 exibilities provide a unique resource to the structural biology community that can be computationally
155 unique opportunities to a rapidly developing structural biology community where there is increasing i
158 ng based on recent insights into immunology, structural biology, computational biology, and immunoeng
160 d signals, which are problematic for in situ structural biology, contribute specifically to the inter
161 al efforts in the area of chemokine receptor structural biology could dramatically increase the outco
162 arative biology, experimental evolution, and structural biology, could thoroughly determine how viral
163 proteins function was resolved, in part, by structural biology coupled with immunological and biolog
164 e (super)families, exploiting both available structural biology data and conformational similarities
165 n data publication and dissemination system, Structural Biology Data Grid (SBDG; data.sbgrid.org), to
171 Action on Native MS and Related Methods for Structural Biology (EU COST Action BM1403) as an introdu
172 ve Mass Spectrometry and Related Methods for Structural Biology (EU COST Action BM1403), which involv
175 DEM) has become a key experimental method in structural biology for a broad spectrum of biological sp
176 esis, experimental evaluation, modeling, and structural biology for a novel series of sulfonamide hyd
177 S) has evolved as an alternative strategy in structural biology for characterizing three-dimensional
178 The limitations of conventional methods of structural biology for fibril characterization have led
179 e X-ray crystallography has been a staple of structural biology for more than half a century and will
183 ing use of mass spectrometry in the field of structural biology has catalyzed the development of many
184 l such therapeutics target beta-tubulin, and structural biology has explained the basis of their acti
187 ified tens of thousands of interactions, and structural biology has provided detailed functional insi
188 ess of cryo-electron microscopy (cryo-EM) in structural biology has raised an urgent need for robust
196 t knowledge from genetics, biochemistry, and structural biology into detailed molecular descriptions
201 A primary reason for the intense interest in structural biology is the fact that knowledge of structu
208 e is a long history of muscle biophysics and structural biology, many of the mechanistic details that
210 s spectrometry (XL-MS) to make systems-level structural biology measurements in complex biological sa
217 we describe the recent progress made in the structural biology of both the relaxosome and the T4SS.
219 ant achievement, a full understanding of the structural biology of facilitative glucose transport rem
220 blot analysis to elucidate the function and structural biology of glycoprotein E-selectin ligands ex
227 discuss both the biology and the underlying structural biology of RORc, and summarize the RORc modul
230 arried out with the determination of further structural biology on the lead series, affording derivat
232 and algorithms for common tasks in genomics, structural biology, ontologies, phylogenetics, and more.
233 s a resource for researchers studying kinase structural biology or developing conformation-specific k
234 s emerged as a critical and flexible tool in structural biology, particularly in the study of highly
235 roved understanding of FGF signalling from a structural biology perspective, and of its roles in skel
236 beta2m aggregates are challenging targets in structural biology, primarily due to their inherent tran
238 pharmacological, drug and chemical data with structural biology, protein networks and druggability da
239 pharmacological, drug and chemical data with structural biology, protein networks and unique, compreh
240 in complexes with potential implications for structural biology, proteomics, biomarker detection and
241 opments in G protein-coupled receptor (GPCR) structural biology provide insights into GPCR-ligand bin
242 optimization of a second Bicycle, guided by structural biology, provided a high affinity, metabolica
243 S) is a technology of growing importance for structural biology, providing complementary 3D structure
245 -CoV, and might become an important tool for structural biology, serology, vaccine design and immunol
246 the growing utilization of CIU as a tool for structural biology, significant challenges have emerged
250 ctivity relationship (SAR) efforts driven by structural biology studies led to the discovery of pyrid
251 itors have been identified, but only limited structural biology studies of IDO1 inhibitors are availa
252 cture-activity relationship, UV spectra, and structural biology studies of several analogues of 24 de
253 te plasticity seen here is expected to drive structural biology studies on CaADH, while the exception
255 roadens the pool of possible biochemical and structural biology studies, as well as greatly enhances
259 We report here the results of an integrated structural biology study designed to distinguish between
260 the best of our knowledge, this is the first structural biology study to directly observe how changes
261 aches play an increasingly important role in structural biology, taking advantage of the complementar
262 lectron microscopy (cryo-EM) is an expanding structural biology technique that has recently undergone
265 al changes is notoriously difficult, as many structural biology techniques are also affected by these
268 l overcomes hurdles typically encountered by structural biology techniques such as X-ray crystallogra
269 en-deuterium exchange MS (HDX-MS) with other structural biology techniques to probe the mechanistic b
273 ving systems is now ushering in a new era of structural biology that is leading to fundamentally new
274 trated using phylogenetics, biochemistry and structural biology that this cysteine-thiol lyase (C-T l
275 can improve our fundamental understanding of structural biology, the molecular basis of diseases, and
276 rotein crystallography" began to morph into "structural biology." The course of the research recounte
277 to cloning and sequencing to biochemistry to structural biology to an understanding of how proteins e
279 tocol that exploits the power of integrative structural biology to characterize conformational ensemb
281 importance for future PELDOR applications in structural biology to develop suitable approaches that c
282 e complementary approaches that combine with structural biology to explore the binding capabilities o
284 ) adapted molecular visualization tools from structural biology to render and analyze complex cell su
285 ged from innovations in basic immunology and structural biology to treatments for immune-mediated dis
286 ccessful immune response has been to utilize structural biology to uncover the molecular details of a
288 -MS) has become an important addition to the structural biology toolbox, but separating closely relat
292 spectra in NMR have empowered proteomics and structural biology, we envisage that hyperdimensional im
293 seeligeri Using genetics, biochemistry, and structural biology, we found that AcrVIA1 interacts with
294 lar assemblies remains a challenging task in structural biology when using integrative modeling appro
295 s) used to be the most difficult targets for structural biology when X-ray crystallography was the ma
296 en difficult in the core subjects of current structural biology, which include multidomain and intrin
297 The concurrent evolution of experimental structural biology with biomolecular computer modelling
299 t yet available, rapid progress in combining structural biology with other techniques is revealing th
300 tive site should provide important tools for structural biology, yielding insight into substrate gati