ライフサイエンスコーパス: crystal structure analysis

1 oblot, complement factor 3b degradation, and crystal structure analysis.

2 the catalytic cysteine residue, confirmed by crystal structure analysis.

3 the mutated protein to be non-functional by crystal structure analysis.

4 racterized via UV/vis spectroscopy and X-ray crystal structure analysis.

5 was also accomplished and confirmed by X-ray crystal structure analysis.

6 face with the DUX4 protein, as determined by crystal structure analysis.

7 ed by means of DFT calculations and an X-ray crystal structure analysis.

8 mutant that lacks HAUSP binding based on the crystal structure analysis.

9 he solid state have been determined by X-ray crystal structure analysis.

10 ntact surfaces on both proteins according to crystal structure analysis.

11 ehavior in the solid state as shown by X-ray crystal structure analysis.

12 microanalysis, mass spectrometry, and X-ray crystal structure analysis.

13 53 with DNA that complements and extends the crystal structure analysis.

14 via multinuclear NMR spectroscopy and X-ray crystal structure analysis.

15 iterative medicinal chemistry aided by X-ray crystal structure analysis, a new series of inhibitors h

16 The crystal structure analysis allows us to propose a detail

17 ino-6-chloro-benzimidazole) was subjected to crystal structure analysis and a high resolution crystal

18 The crystal structure analysis and computational modeling ar

19 Single-crystal structure analysis and density functional theory

20 Through single crystal structure analysis and density functional theory

21 On the basis of crystal structure analysis and differing rates of C5 [do

22 While our crystal structure analysis and in vitro binding data ini

23 Unexpectedly, protein crystal structure analysis and molecular dynamics simula

24 conformational aspects were studied by X-ray crystal structure analysis and molecular mechanics calcu

25 Crystal structure analysis and saturation transfer diffe

26 r (o-1)(2) was characterized by X-ray single crystal structure analysis and temperature-dependent inf

27 X-ray co-crystal structure analysis and ultracentrifugation exper

28 Along with X-ray crystal-structure analysis and thermodynamic profiling,

29 ative process of synthesis, crystallography, crystal structure analysis, and computational methods.

30 Limited proteolysis, crystal structure analysis, and functional assays showed

31 crocycles were characterized by X-ray single-crystal structure analysis, and, in all cases, NMR spect

32 inactive and active states, as determined by crystal structure analysis, are described.

33 tion mechanisms were investigated via single-crystal structure analysis as well as density functional

34 Moreover, crystal structure analysis at 1.63 angstrom resolution c

35 Crystal structure analysis at 1.7 A resolution suggests

36 High-resolution crystal structure analysis confirmed that the HX RNA is

37 X-ray single-crystal structure analysis confirmed the molecular scaff

38 Through crystal structure analysis, density functional theory ca

39 ar dynamics simulations together with single-crystal structure analysis emphasize the critical role o

40 Crystal structure analysis further shows that the stalk

41 An X-ray crystal structure analysis has been performed on one of

42 Previous X-ray crystal structure analysis has demonstrated that the mon

43 Crystal structure analysis has led to the hypothesis tha

44 Previous crystal structure analysis has revealed that a small bet

45 rotein-DNA contact sites obtained from X-ray crystal structure analysis impacted their DNA-binding an

46 hich is similar to a motif recently shown by crystal structure analysis in BtuC and previously shown

47 sotherms, adsorption kinetics and gas-loaded crystal structure analysis indicated that the coordinati

48 The crystal structure analysis indicates highly distorted Zn

49 From their crystal structure analysis is concluded that both nanogr

50 Crystal structure analysis, molecular mechanics simulati

51 X-ray crystal structure analysis, molecular modelling, and pro

52 prodil stereoisomers was determined by X-ray crystal structure analysis of (1R,2S)-1a and (1S,2S)-1d.

53 The crystal structure analysis of (l)-2.4H(2)O, reveals that

54 Crystal structure analysis of 1 shows a strong pai...pai

55 An X-ray crystal structure analysis of a isoxazolin-5-one glucosi

56 tes peptide conformational data derived from crystal structure analysis of an MN-isolate peptide (RP1

57 X-ray crystal structure analysis of both Rh complexes formed f

58 importance of these waters directly by X-ray crystal structure analysis of complexes with four mutant

59 Recent x-ray crystal structure analysis of CtpA from the eukaryotic a

60 Crystal structure analysis of four of these compounds in

61 Interestingly, crystal structure analysis of MAT2B protein (MATbeta) pr

62 eocontrol in complex settings allowing X-ray crystal structure analysis of natural and unnatural dias

63 Crystal structure analysis of one of the mutants showed

64 X-ray crystal structure analysis of rabbit and bacterial PGI h

65 number of biophysical techniques, including crystal structure analysis of receptor-stapled peptide c

66 Amino acid alignments and crystal structure analysis of retinoic acid (RA)-binding

67 Crystal structure analysis of SPOUT1/CENP-32 reveals tha

68 ylbutyric acid was established as R by X-ray crystal structure analysis of the (R)-(+)-alpha-methylbe

69 Detailed crystal structure analysis of the [(alpha1)(2)alpha2](2)

70 X-ray crystal structure analysis of the dimer (DDQT-2) showed

71 lly calculated explosive properties, and the crystal structure analysis of the ETN derivatives are re

72 Our crystal structure analysis of the full-length GGTase3-FB

73 ransferase activity, we have carried out the crystal structure analysis of the Gal-T1.LA complex with

74 The crystal structure analysis of the NarL protein provides

75 X-ray single-crystal structure analysis of the Ni(II) complex of stra

76 X-ray crystal structure analysis of the selenoamide, thioamide

77 e correlated with contacts implicated by the crystal structure analysis of the trp repressor-operator

78 Crystal structure analysis of the two most potent inhibi

79 The crystal structure analysis of the VosA velvet domain rev

80 Although there is no zinc in the crystal structure, analysis of a mercuric acetate deriva

81 e ORAI1 gene, modeling of mutations on ORAI1 crystal structure, analysis of ORAI1 mRNA and protein ex

82 Crystal-structure analysis of the V6(54/84) variant boun

83 Building on high-resolution crystal-structure analysis, pore vestibule modeling, and

84 tantly, the XANES and related electronic and crystal structure analysis, quantitative electrocatalysi

85 nts (by stopped-flow IR spectroscopy), X-ray crystal structure analysis, quantum chemical calculation

86 attering measurements, TEM imaging and X-ray crystal structure analysis reveal that the tetra-substit

87 Co-crystal structure analysis revealed a dual active site-d

88 X-ray crystal structure analysis revealed a putative sorting m

89 The crystal structure analysis revealed complex inter- and i

90 Co-crystal structure analysis revealed different molecular

91 Co-crystal structure analysis revealed dual steric pressure

92 Crystal structure analysis revealed that a DNA base cont

93 Crystal structure analysis revealed that FePYR1 recogniz

94 Crystal structure analysis revealed that JM4 forms a hai

95 Crystal structure analysis revealed that the 2p orbital

96 Crystal structure analysis revealed that the complementa

97 Crystal structure analysis revealed that the straight BT

98 Crystal structure analysis revealed the coordination of

99 Crystal structure analysis revealed the interplay betwee

100 Moreover, crystal structure analysis revealed the unique binding m

101 Crystal structure analysis reveals a unique zinc-finger

102 High-pressure X-ray crystal structure analysis reveals concurrent pressure-d

103 product is deep blue in color, and an X-ray crystal structure analysis reveals it to be the S4 symme

104 Crystal structure analysis reveals that Ag(15) possesses

105 X-ray crystal structure analysis reveals that the polycyclic l

106 NMR and X-ray crystal structure analysis reveals that ynamides derived

107 Single-crystal structure analysis reveals the C(2v) symmetry of

108 Crystal structure analysis reveals the donor (D) and acc

109 Crystal structure analysis reveals the donor (D) and acc

110 Crystal structure analysis showed a native trimer of rig

111 Crystal structure analysis showed that a combination of

112 Crystal structure analysis showed that the FOXA DNA bind

113 The X-ray crystal structure analysis showed that the potassium com

114 Crystal structure analysis shows that DarA is highly hom

115 Crystal structure analysis shows that paral-[FeOMTPP(1-M

116 Crystal structure analysis shows that the portion of the

117 hese results, combined with a computer-aided crystal structure analysis, suggest a model in which p53

118 Detailed crystal structure analysis suggested that intermolecular

119 X-ray crystal structure analysis suggests that some of the sui

120 We further show through co-crystal structure analysis that the ligand binds PAD4 at

121 Using quantum computation and crystal structure analysis, the effect of the introducti

122 point extraction of NPs and their subsequent crystal structure analysis via SAED is another valuable

123 e X-ray analysis (EDX) elemental mapping and crystal structure analysis via SAED.

124 Crystal structure analysis was conducted on a number of

125 Building on our crystal structure analysis, we designed compounds to spe

126 Based on crystal structure analysis, we propose that IgG2 disulfi

127 tical properties are characterized by single-crystal structure analysis, X-ray powder diffraction, ch