ライフサイエンスコーパス: temperature factor

1 mly in place as indicated by a lower average temperature factor.

2 ssure perturbations and are accelerated by a temperature factor.

3 hown to correlate well with crystallographic temperature factors.

4 e I and II regulatory subunits, based on the temperature factors.

5 3 as indicated by decreased crystallographic temperature factors.

6 .15 A resolution with individual anisotropic temperature factors.

7 rom the picture provided by crystallographic temperature factors.

8 arisons between experimental and theoretical temperature factors.

9 d by significantly elevated crystallographic temperature factors.

10 These water molecules have low temperature factors and make several hydrogen bonds with

11 atic ribonuclease A, and through analysis of temperature factors and molecular dynamics simulations o

12 of resolution, alternate conformations, and temperature factor (B), leading to the decision that pac

13 ay be the major contributor to the effective temperature factor (B-factor) describing contrast loss a

14 ht is derived and used in conjunction with a temperature factor (B=-1000A(2)) to restore high-resolut

15 ectron density in crystals with high overall temperature factors (B-factors).

16 NMR order parameters and x-ray Debye-Waller temperature factors; both quantities show good agreement

17 es of complexed Fab HyHEL-63 exhibit reduced temperature factors compared with those of the free Fab,

18 oduce fluctuations derived from experimental temperature factors (correlation coefficient of 0.88, om

19 t was not found in wt-hGH or apparent in the temperature factor data from the X-ray analysis of the u

20 d overlapping an area of higher than average temperature factors derived from the x-ray crystal struc

21 ions for isolated proteins with experimental temperature factors determined in the crystalline state,

22 egions of the structure are described by the temperature factor distribution.

23 gonal least-squares methods with anisotropic temperature factors for all non-hydrogen atoms and with

24 nd-dependent conformational change and large temperature factors for the IIAGlc-binding site on E. co

25 elix appears as a long alpha-helix with high temperature factors for the main-chain atoms in the inne

26 The crystallographic temperature factors for the two complexes indicate that

27 e to an increase/decrease in thermal motion (temperature factor) for the entire population, but a red

28 The high temperature factors (from X-ray crystal structures) asso

29 The interaction time-temperature factor had significant effects on pH, TS, FA

30 ich has some of the highest crystallographic temperature factors in all of the cyt f structures) on t

31 ts to the CORE domain, has strikingly higher temperature factors in GK.GMP than in apo-GK, indicating

32 CO binding increases the temperature factors in the FG loop of the protein and di

33 The cytoplasmic loops have the highest temperature factors in the structure, indicative of thei

34 ions to binding energy generally exhibit low temperature factors in the structures of complexes.

35 In this case, we found that the average temperature factor of the protein is reduced and more wa

36 data to 1.1 A resolution by the anisotropic temperature factor refinement procedure of the SHELX97 p

37 cohesin module and the X module has elevated temperature factors, reflecting an inherent flexibility

38 or of two, while the isotropic disorder (the temperature factor) remains approximately unchanged.

39 The data are compared with the temperature factors reported for the X-ray structure of

40 s a single static model with a single set of temperature factors representing a simple approximation

41 Conformational variations and high temperature factors seen for the six chains of the asymm

42 of the disulfide bond, the crystallographic temperature factors show no evidence of increased flexib

43 analysis of the coiled coils with regard to temperature factor shows a strong correlation between mo

44 analysis of variance to delineate main-chain temperature factors that represent significant departure

45 obial and detritivore community responses to temperature, factors that can influence the apparent tem

46 used: the water molecule's crystallographic temperature factor, the number of hydrogen bonds between

47 tic network models developed to best predict temperature factors without regard for the crystal envir