1 terminus of Robo1 that is disordered in the
x-ray crystal structure.
2 [CF3NH3][Sb2F11] were characterized by their
X-ray crystal structure.
3 and features a shape consistent with recent
x-ray crystal structures.
4 is a curved extended alpha-helix, alpha1, in
X-ray crystal structures.
5 rized by their vibrational spectra and their
X-ray crystal structures.
6 N3 )3 ], and [PPh4 ]2 [MoO(N3 )5 ], by their
X-ray crystal structures.
7 4]2[WO2(N3)4], and [(bipy)MoO2N3]2O by their
X-ray crystal structures.
8 ledge, these represent the first Rgg protein
X-ray crystal structures.
9 unctional theory computations and conform to
X-ray crystal structures.
10 2 NNO2 H][SbF6 ] were characterized by their
X-ray crystal structures.
11 structures and compared them with available
X-ray crystal structures.
12 structure-based drug design and ligand bound
X-ray crystal structures.
13 omparing LDM-refined binding pockets to GPCR
X-ray crystal structures across seven different GPCRs bo
14 X-ray crystal structures also revealed "pre-bound" molec
15 X-ray crystal structure analysis of both Rh complexes fo
16 iastereocontrol in complex settings allowing
X-ray crystal structure analysis of natural and unnatura
17 X-ray crystal structure analysis of the selenoamide, thi
18 This product is deep blue in color, and an
X-ray crystal structure analysis reveals it to be the S4
19 NMR and
X-ray crystal structure analysis reveals that ynamides d
20 surements (by stopped-flow IR spectroscopy),
X-ray crystal structure analysis, quantum chemical calcu
21 nd characterized via UV/vis spectroscopy and
X-ray crystal structure analysis.
22 Along with
X-ray crystal-structure analysis and thermodynamic profi
23 Here, we present
x-ray crystal structures and biochemical characterizatio
24 Here, we present
X-ray crystal structures and biochemical characterizatio
25 Analysis of the
X-ray crystal structures and computed energy-minimized s
26 Four
X-ray crystal structures and docking studies explained t
27 Here we show, using
X-ray crystal structures and functional analyses, that a
28 1 receptor associated kinase 4 (IRAK4) using
X-ray crystal structures and structure based design to i
29 Using enzyme assays,
X-ray crystal structures,
and simulations of the reactio
30 utes, and their NMR spectra, UV-vis spectra,
X-ray crystal structures,
and stability toward light and
31 Whilst a number of binary DNA-complex
X-ray crystal structures are available, most include the
32 Using the
X-ray crystal structure as a starting point, we have mod
33 The approach is validated by the use of
X-ray crystal structures as internal controls and by con
34 these rate differences involved analysis of
X-ray crystal structures as well as quantum chemical cal
35 The
X-ray crystal structure at 1.6 A resolution confirms tha
36 ate to be used for solving the corresponding
X-ray crystal structures by molecular replacement.
37 The
X-ray crystal structure confirms that a tetra-nickel clu
38 Molecular modeling based on the
x-ray crystal structure coordinates of CYP2D6 and CYP2C8
39 X-ray crystal structures,
cyclic voltammetry, and spectr
40 X-ray crystal structures demonstrate a planar structure
41 s to narrow, the use of EM maps to help with
X-ray crystal structure determination, as described in t
42 d the interaction between TNKS1 and USP25 by
X-ray crystal structure determination.
43 by (31)P NMR spectroscopy in solution and by
X-ray crystal-structure determination of (Bu4N)2P16 in t
44 Using 40 pairs of NMR and
X-ray crystal structures determined by the Northeast Str
45 In this study, we present five
X-ray crystal structures,
determined to a resolution of
46 hese two proteins, although similar in their
X-ray crystal structure,
display a significant differenc
47 The
x-ray crystal structures displayed high overall similari
48 Here, we present a high-resolution
x-ray crystal structure displaying two tetrameric LBD ar
49 ned by the SN(F) synthetic strategy includes
X-ray crystal structures,
electron spin resonance data,
50 tein conformations that were observed in the
X-ray crystal structures exist as conformational substat
51 ein, we present, to our knowledge, the first
X-ray crystal structure for a full-length mammalian (rat
52 X-ray crystal structures for 3a and 3b bound to MIF are
53 X-ray crystal structures for BuBA and PBA complexed to P
54 X-ray crystal structures for two of the most potent comp
55 The first
x-ray crystal structure has been solved for an activated
56 Although
X-ray crystal structures have greatly enhanced our under
57 ses and related prenyltransferases for which
X-ray crystal structures have informed and advanced our
58 X-ray crystal structures have played an important role i
59 X-ray crystal structures have since confirmed multiple b
60 with an endogenous phenazine, we report its
X-ray crystal structure in the apo-form (refined to 1.35
61 ed improvement in VS performance over origin
X-ray crystal structures in 21 out of 24 cases.
62 properties of this series was achieved using
X-ray crystal structures in conjunction with careful ana
63 parable to that of <SASA> data obtained from
X-ray crystal structures,
indicating the accuracy and ut
64 The
X-ray crystal structure of 4c is reported.
65 nd 6 is described and rationalized using the
X-ray crystal structure of 6 bound to human IDO-1, which
66 The
X-ray crystal structure of 6-hydroxy-2-thioxocoumarin bo
67 The
X-ray crystal structure of a bovine antibody (BLV1H12) r
68 Herein we report the
X-ray crystal structure of a charge-neutral [Au18(SC6H11
69 An
X-ray crystal structure of a closely related analogue in
70 The
X-ray crystal structure of a conformationally constraine
71 Here, we present the
X-ray crystal structure of a Crl homolog from Proteus mi
72 Here, we present the first
X-ray crystal structure of a Delta enantiomer bound to w
73 med by 2D-NMR spectroscopic analysis and the
X-ray crystal structure of a derivative.
74 We previously reported an
x-ray crystal structure of a dimeric truncation mutant o
75 Here we describe the
X-ray crystal structure of a double-Trp mutant (Gly46-->
76 ic C-F...H-C interaction was observed in the
X-ray crystal structure of a fluorinated triterpenoid.
77 The
x-ray crystal structure of a hMOF K274P mutant suggests
78 The synthesis and
X-ray crystal structure of a novel Au(I)-precatalyst app
79 Finally, we report an
X-ray crystal structure of a palladium complex resulting
80 We have solved at 1.07: A resolution the
X-ray crystal structure of a polyriboadenylic acid (poly
81 We report a 3.4-A resolution
X-ray crystal structure of a sigma(N) fragment in comple
82 The
X-ray crystal structure of a single Lar_0958 repeat, det
83 We report the
X-ray crystal structure of a site-selective peptide cata
84 Here we have solved the first
X-ray crystal structure of a Ti(IV)-bound sTf.
85 An
X-ray crystal structure of a tKSI general base mutant sh
86 The high-resolution
X-ray crystal structure of a trimeric porin-LPS complex
87 Here, we have solved the
X-ray crystal structure of an EBNA1 DNA-binding domain (
88 An
X-ray crystal structure of an example of the latter is p
89 Here, we report a 2.5 A resolution
X-ray crystal structure of an FcRn-DX-2507 Fab complex,
90 Here we present an
x-ray crystal structure of an HAI-1 fragment covering th
91 ClPh-Thio-DADMe-ImmA) as well as one neutron/
X-ray crystal structure of an inactive variant (HpMTAN-D
92 Here, we present a high-resolution
x-ray crystal structure of an interaction surface betwee
93 The
X-ray crystal structure of an Ns1tbe pentamer revealed a
94 Simple molecular modeling based on an
X-ray crystal structure of an unlabeled protein led to a
95 this energetically unfavorable reaction, the
x-ray crystal structure of ATP sulfurylase isoform 1 fro
96 The
X-ray crystal structure of BhCBM56 and NMR-derived chemi
97 Starting from the
X-ray crystal structure of c-Src in complex with 3, Mont
98 We solved an
x-ray crystal structure of CagL that revealed conformati
99 Here we determine a 3.2 A
x-ray crystal structure of Cascade in a new crystal form
100 Here we present the 3.24 angstrom resolution
x-ray crystal structure of Cascade.
101 An
X-ray crystal structure of caspase-7 bound to a fragment
102 The 1.2 A resolution
x-ray crystal structure of CBM70 revealed it to have a b
103 me inhibition profile as well as the protein
X-ray crystal structure of compound 3, comprising one hy
104 The
X-ray crystal structure of compound 31 in human Vps34 il
105 In addition, an
X-ray crystal structure of CpIMPDH.IMP.8k is also presen
106 X-ray crystal structure of cycloruthenated complex 2cr a
107 Here, we report the
X-ray crystal structure of EndoS and provide a model of
108 We report the first
X-ray crystal structure of ent-kaur-16-ene synthase from
109 The
X-ray crystal structure of epitope II on the E2 protein
110 Here, we report the 2.2 A resolution
X-ray crystal structure of FliD from Pseudomonas aerugin
111 We report a high-resolution
X-ray crystal structure of G12C K-Ras bound to SML, reve
112 To investigate, we solved the
X-ray crystal structure of GSTP1 bound to PL and GSH at
113 The
X-ray crystal structure of huBuChE in complex with 16 re
114 In this work, we have determined the
x-ray crystal structure of human CD14.
115 We report the
X-ray crystal structure of long form PDE4B containing UC
116 Here we report the 2.7-A
X-ray crystal structure of MazF-mt6.
117 l 5'- and 3'-phosphate group, as seen in the
X-ray crystal structure of modified RNA.
118 Here we describe the
x-ray crystal structure of Nef in complex with the Hck S
119 The
X-ray crystal structure of NosK, solved to 2.3 A resolut
120 We solved the
X-ray crystal structure of one site VIII mAb, hRSV90, in
121 Here, we determined the
x-ray crystal structure of Pf-Avr4 from the tomato patho
122 Here we present the
X-ray crystal structure of Pput2725 from the biodegrader
123 Finally, we report the
X-ray crystal structure of ProTx-II to atomic resolution
124 We have determined the
X-ray crystal structure of SalBIII, and structure-guided
125 sing compounds 11a and 11h overlaid onto the
X-ray crystal structure of tetrahydroquinoline 3 complex
126 n apical ligand for the rhodium catalyst: an
X-ray crystal structure of the (DMAP)2.[Rh2{(S)-nttl}4]
127 This mechanism is supported by the
X-ray crystal structure of the [Zn(ZMC1)2] complex, whic
128 Surprisingly, the
x-ray crystal structure of the active Meta-II state has
129 We report the
x-ray crystal structure of the Ad type 4 (Ad4) E3-19K of
130 We present here the
X-ray crystal structure of the ADAM10 ectodomain, which,
131 We have solved the
x-ray crystal structure of the AUM cap fused to the cata
132 Using the
X-ray crystal structure of the C-terminal domain of p100
133 The
X-ray crystal structure of the catalytic domain was dete
134 Our recent
x-ray crystal structure of the central domain of apoA-IV
135 Here, we report the 3.0 A resolution
X-ray crystal structure of the complex formed by ipilimu
136 The
X-ray crystal structure of the CPV-2a capsid shows that
137 The
X-ray crystal structure of the CRABP2-4 conjugate, when
138 Here, the
X-ray crystal structure of the Cronobacter sakazakii Rec
139 The
x-ray crystal structure of the CtFabI.NADH.AFN-1252 tern
140 The 1.8 A
x-ray crystal structure of the decaheme MtrC revealed a
141 ment of the heterocycles was deduced from an
X-ray crystal structure of the dimer, which also suggest
142 r the activity of AtGH3.5, we determined the
X-ray crystal structure of the enzyme in complex with IA
143 The
x-ray crystal structure of the enzyme was solved at 1.44
144 In this study we report the
X-ray crystal structure of the extracellular domain (ECD
145 cations derived from careful analysis of the
X-ray crystal structure of the FXIa/11h complex.
146 The
X-ray crystal structure of the GC di-PNA showed the occu
147 Our goal was to obtain the
X-ray crystal structure of the glycosylated chemokine Se
148 Here, we report the
X-ray crystal structure of the highly conserved zinc fin
149 To this end, we determined the
X-ray crystal structure of the HLA-DQ2.5.
150 The availability of a high-resolution
X-ray crystal structure of the human adenosine A2A recep
151 homology model based on the newly determined
X-ray crystal structure of the human serotonin transport
152 The
X-ray crystal structure of the intermediate at pH 6.5 re
153 We describe a 2.5-A resolution
X-ray crystal structure of the membrane-proximal three T
154 The
X-ray crystal structure of the monoprotonated species [R
155 for muOR activation, here we report a 2.1 A
X-ray crystal structure of the murine muOR bound to the
156 An
X-ray crystal structure of the neutralizing mAb 14N4 in
157 We have determined the 3D
X-ray crystal structure of the nucleoprotein (N)-RNA com
158 In this study, we determined the
X-ray crystal structure of the PEAK1 pseudokinase domain
159 Using the
X-ray crystal structure of the prototype foamy virus IN
160 An
X-ray crystal structure of the trisubstituted alkyl-pall
161 The
X-ray crystal structure of the VVH lectin domain solved
162 Here, we solved an
X-ray crystal structure of the wild-type, ribosome-depen
163 We solved the first
X-ray crystal structure of Thermatoga maritima (Tm) ThyX
164 We have also determined the
X-ray crystal structure of this enzyme in complex with C
165 An
X-ray crystal structure of this fragile marine natural p
166 The
x-ray crystal structure of this peptide bound to M11 rev
167 ooperatively within well-defined pockets; an
X-ray crystal structure of three fullerenes inside the t
168 The
X-ray crystal structure of TIP bound to PCNA reveals tha
169 xynyl)amido-1,3-propanediamine)Cl2] (1), the
X-ray crystal structure of which exhibits a combination
170 Here we determined the
X-ray crystal structure of yeast elongating RNA polymera
171 X-ray crystal structures of 408-acetylated SAHH and dual
172 Here we present the NMR solution and
X-ray crystal structures of a left-handed DNA G-quadrupl
173 e heterogeneity, we obtained high-resolution
X-ray crystal structures of a native 10-mer RNA duplex (
174 Here we present
X-ray crystal structures of a Streptococcus Rgg protein
175 X-ray crystal structures of Acapital ES, CyrillichBP in
176 X-ray crystal structures of AChBP complexes with example
177 standing of this process, we have solved the
x-ray crystal structures of Ag85C covalently modified wi
178 We also describe
x-ray crystal structures of Ag85C single mutants within
179 We have determined high-resolution
X-ray crystal structures of an enzyme from Neurospora cr
180 Here, we report the
X-ray crystal structures of an MthRnl*ATP complex as wel
181 X-ray crystal structures of apo- and NADP(+)-bound selec
182 Here, we present the
x-ray crystal structures of Arabidopsis thaliana IPMDH2
183 mutase isoforms (AtCM1-3) and determined the
x-ray crystal structures of AtCM1 in complex with phenyl
184 thaliana PMTs (AtPMT1-3) and determined the
X-ray crystal structures of AtPMT1 and AtPMT2.
185 X-ray crystal structures of both dC and dT paired with O
186 amino acid-based AMPA receptor antagonists,
X-ray crystal structures of both eutomers in complex wit
187 We present several new
X-ray crystal structures of both human Miro1 and Miro2 t
188 in other Pezizomycotina fungi, we determined
x-ray crystal structures of C-terminally truncated Asper
189 Although
X-ray crystal structures of CEACAM IgV domain homodimers
190 Herein, we report three ultrahigh resolution
X-ray crystal structures of CTX-M beta-lactamase, direct
191 X-ray crystal structures of dehaloperoxidase-hemoglobin
192 Although
X-ray crystal structures of DNA polymerase I with substr
193 Here we report the
X-ray crystal structures of DprE1 and the DprE1 resistan
194 w analogues are reported here along with the
X-ray crystal structures of each homologue bound to the
195 We solved the
X-ray crystal structures of each of the three VHHs (E1,
196 Here we report 11
X-ray crystal structures of EFE that provide insight int
197 We report the
X-ray crystal structures of ELIC in complex with chlorpr
198 This questions whether the available
x-ray crystal structures of EPOR truly represent active
199 Previously, we determined
X-ray crystal structures of ESCRT-III subunit Snf7, the
200 X-ray crystal structures of example compounds from this
201 Recently,
X-ray crystal structures of Fe(2+)-loaded ferritins prov
202 nique chemical transformation, we report the
X-ray crystal structures of FtmOx1 and the binary comple
203 nd PhoD enzymatic activities, in addition to
X-ray crystal structures of GlpQ, revealed distinct mech
204 X-ray crystal structures of HigB bound to two different
205 Five
x-ray crystal structures of hpol eta ternary complexes w
206 We then obtained
X-ray crystal structures of HsFPPS with taxodione+zoledr
207 Here we present the
X-ray crystal structures of human protocadherin-15 EC8-E
208 X-ray crystal structures of IDH1(R132H) in complex with
209 Herein, we disclose the first
X-ray crystal structures of inhibitors bound to STEP and
210 site of human SERT, in agreement with recent
X-ray crystal structures of LeuBAT, an engineered monoam
211 Based on differences between the
x-ray crystal structures of ligand-bound and unbound for
212 etails of binding were revealed by the first
X-ray crystal structures of ligand-bound ASGPR.
213 Herein, we report
X-ray crystal structures of ligand-free Tdp2 and Tdp2-DN
214 X-ray crystal structures of MTAN cocrystallized with sev
215 We solved five
X-ray crystal structures of murine uPA (muPA) in the abs
216 Previous
X-ray crystal structures of Nef in complex with key host
217 Here, we present the
X-ray crystal structures of NolR in the unliganded form
218 Using the known
x-ray crystal structures of PRODH and P5CDH from T. ther
219 Majority of novel
X-ray crystal structures of proteins are currently solve
220 recognition, we have analyzed quantitatively
X-ray crystal structures of proteins with noncovalently
221 X-ray crystal structures of prototypical RRNPP members h
222 We present the first reported protein
X-ray crystal structures of psammaplin C in complex with
223 The
X-ray crystal structures of selected pore mutants contai
224 f this destabilization is illuminated by the
X-ray crystal structures of several PFN1 proteins, revea
225 The analysis was based on the
x-ray crystal structures of the allergens in complex wit
226 The
x-ray crystal structures of the beta-mannose-bound prote
227 The
X-ray crystal structures of the catalytic domain of the
228 Here, we present
X-ray crystal structures of the catalytic engine of a eu
229 X-ray crystal structures of the central globular domain
230 Here we determine
X-ray crystal structures of the Drosophila melanogaster
231 The
X-ray crystal structures of the E- and Z-rotaxanes show
232 In this study, we determined
X-ray crystal structures of the enzymatic subunit of ric
233 Here we present
X-ray crystal structures of the Escherichia coli Cas1-Ca
234 In this study, we determined the
X-ray crystal structures of the Escherichia coli RNAPs c
235 We determined multiple
x-ray crystal structures of the GluA2 AMPA receptor in c
236 We have determined
x-ray crystal structures of the glycyl radical enzyme th
237 X-ray crystal structures of the Helicobacter pylori prot
238 tion during tissue injury, we determined the
X-ray crystal structures of the human Cx26 gap junction
239 Here we report
X-ray crystal structures of the human P2X3 receptor in a
240 In the obtained
X-ray crystal structures of the LD-sAB complexes, the LD
241 To address the BET selectivity issue,
X-ray crystal structures of the lead compound bound to t
242 is for this enhanced activity, we solved the
X-ray crystal structures of the ligand-free mutant enzym
243 Here we report
X-ray crystal structures of the Mep2 orthologues from Sa
244 Here, we determine
X-ray crystal structures of the most abundant ESCRT-III
245 The
x-ray crystal structures of the mutants provided details
246 X-ray crystal structures of the PfPMT-D128A mutant in co
247 We solved two
x-ray crystal structures of the Proteus vulgaris tetrame
248 X-ray crystal structures of the resulting designs match
249 Comparison of high-resolution
X-ray crystal structures of the substrate complex, an Fe
250 cry of host proteins, we have determined the
X-ray crystal structures of the TIR domains from the Bru
251 Recent
X-ray crystal structures of the two-pore domain (K2P) fa
252 X-ray crystal structures of the unusual beta-subunit of
253 Here we present
X-ray crystal structures of the Xenopus laevis GluN1-Glu
254 The
X-ray crystal structures of their protonated derivatives
255 On the basis of the
X-ray crystal structures of these new rexinoids and bexa
256 The
X-ray crystal structures of three different bromodomains
257 The
X-ray crystal structures of two active complexes are rep
258 fect on mRNA cleavage in vitro Comparison of
X-ray crystal structures of two catalytically inactive H
259 Here we present
X-ray crystal structures of two functionally distinct Su
260 We determined
X-ray crystal structures of two GrpU orthologs, providin
261 We also report the
X-ray crystal structures of two KdgF proteins and propos
262 X-ray crystal structures of two new sulfonamides bound t
263 We have determined the
X-ray crystal structures of two related constructs to 3.
264 X-ray crystal structures of various inhibitors in comple
265 his study we present three corefined neutron/
X-ray crystal structures of wild-type HpMTAN cocrystalli
266 X-ray crystal structures of zebrafish P450 17A1 and 17A2
267 eport the design and optimization, guided by
X-ray crystal structures,
of a ligand series with nanomo
268 ferent concentrations (1 mM and 10 muM), and
X-ray crystal structures provide clues of possible inter
269 High resolution
x-ray crystal structures reveal conformational changes a
270 X-ray crystal structures reveal insights into diverse BT
271 X-ray crystal structures revealed tether-specific torsio
272 X-ray crystal structures revealed two distinct binding m
273 riochlorins is also described, including its
X-ray crystal structure,
revealing some details of the m
274 The
X-ray crystal structure reveals a pi-pi stacking and hyd
275 A 2.4-A
x-ray crystal structure reveals that CgT has a unique bi
276 The
X-ray crystal structure reveals that MciZ binds to the C
277 The
X-ray crystal structure reveals the construction of heli
278 NMR mapping experiments and high-resolution
x-ray crystal structures show that select small molecule
279 X-ray crystal structures show that the hpol eta scaffold
280 X-ray crystal structures showed that the stabilizing int
281 CetZ
X-ray crystal structures showed the FtsZ/tubulin superfa
282 The
X-ray crystal structure shows an octahedral complex that
283 ared by a templated clipping reaction and an
X-ray crystal structure shows that the squaraine gem-dim
284 The
X-ray crystal structure shows the important role of the
285 Analysis of the
X-ray crystal structures shows clearly that the cyclizat
286 we present the first M. tuberculosis Rv3802
X-ray crystal structure,
solved to 1.7 A resolution.
287 in reference to the known "closed" apo-PBP2a
X-ray crystal structure state.
288 An
X-ray crystal structure suggests that proton transfer to
289 Here, we report five
X-ray crystal structures that illustrate the pathway by
290 In
X-ray crystal structures,
the Calpha atoms of helical re
291 An
X-ray crystal structure was obtained for the thienyl com
292 An
X-ray crystal structure was solved for one of the design
293 Using published
x-ray crystal structures,
we show that the changes in th
294 Select
X-ray crystal structures were compared to the correspond
295 X-ray crystal structures were determined for GH20C in a
296 X-ray crystal structures were obtained for five of the d
297 the highly organized capsules is shown by an
X-ray crystal structure which features the assembly of t
298 These findings were not anticipated by
x-ray crystal structures,
which show identical interacti
299 Here, we compared two Rgg2Sd(C45S)
X-ray crystal structures with that of wild-type Rgg2Sd a
300 1,10- and 1,11-synthases and comparisons of
X-ray crystal structures with the homology model of GAS;