ライフサイエンスコーパス: lipid bilayer membrane

1 general destabilization and leakiness of the lipid bilayer membrane.

2 istoyl group, enabling it to interact with a lipid bilayer membrane.

3 s through a 2.6-nm diameter ion channel in a lipid bilayer membrane.

4 from their different localization within the lipid bilayer membrane.

5 cells, with a size range of 40-150 nm and a lipid bilayer membrane.

6 biotin capture surface based on a supported lipid bilayer membrane.

7 ne triphosphatases in an integrated in vitro lipid bilayer membrane.

8 way when it is added to only one side of the lipid bilayer membrane.

9 f varying hydrophobicity as well a supported lipid bilayer membrane.

10 ut on both structures embedded in a solvated lipid bilayer membrane.

11 ges in the concentration of cations near the lipid bilayer membrane.

12 oxidase in the electrode-supported thiolipid/lipid bilayer membrane.

13 R/Ca2+ release channel incorporated into the lipid bilayer membrane.

14 ngle OmpF channels reconstituted into planar lipid bilayer membranes.

15 tide libraries for members that permeabilize lipid bilayer membranes.

16 dded, frozen-hydrated 2D crystals of AQP1 in lipid bilayer membranes.

17 ization by tPMP-1 by using artificial planar lipid bilayer membranes.

18 ubule membranes and incorporated into planar lipid bilayer membranes.

19 ptide forms ion-permeable channels in planar lipid bilayer membranes.

20 miting steps for transport of FA across pure lipid bilayer membranes.

21 tor (CFTR) chloride channel reconstituted in lipid bilayer membranes.

22 brane vesicles for reconstitution studies in lipid bilayer membranes.

23 pid-exposed His, Lys, and Arg side chains in lipid bilayer membranes.

24 exposed directly to lipid acyl chains within lipid bilayer membranes.

25 ctive Cl(-) ion binding and transport across lipid bilayer membranes.

26 troduced as ideal to transport anions across lipid bilayer membranes.

27 be functionally reconstituted into synthetic lipid bilayer membranes.

28 tments and separated from the environment by lipid bilayer membranes.

29 lt angles that span 5 degrees -35 degrees in lipid bilayer membranes.

30 hermore adopt a moderate average tilt within lipid bilayer membranes.

31 g purified receptors inserted into deposited lipid bilayer membranes.

32 measure stages of phase separation in model lipid bilayer membranes.

33 d to study the mechanical properties of soft lipid bilayer membranes.

34 mall peptide, penetratin, to solid-supported lipid bilayer membranes.

35 the barrel-stave model for pore formation in lipid bilayer membranes.

36 or metal ion coordination self-organize into lipid bilayer membranes.

37 protein secondary structure and topology in lipid bilayer membranes.

38 f-organizing physical dynamics of biological lipid-bilayer membranes.

39 The dipole potential of a lipid bilayer membrane accounts for its much larger perm

40 synthetic signal transducer embedded in the lipid bilayer membrane acts as a switchable catalyst, ca

41 nanopore from the cis to the trans side of a lipid bilayer membrane, allowed to refold and interact w

42 the transverse and lateral structures of the lipid bilayer membrane, along with a description of lipi

43 eter-sized magnetic crystals surrounded by a lipid bilayer membrane and organized into chains via a d

44 in water and a dipalmitoylphospatidylcholine lipid bilayer membrane and to the free energies of solut

45 verse structure and regulated deformation of lipid bilayer membranes are among a cell's most fascinat

46 (GNP) membrane as the support structure for lipid bilayer membranes are presented.

47 Artificial lipid-bilayer membranes are valuable tools for the study

48 s (SFV) were fused to voltage-clamped planar lipid bilayer membranes at low pH.

49 ence or absence of an envelope composed of a lipid-bilayer membrane, attributes that profoundly affec

50 rease the specific conductance of artificial lipid bilayer membranes by the formation of ion-permeabl

51 th a length comparable to the thickness of a lipid bilayer membrane can self-insert into the membrane

52 Supported lipid bilayer membranes can be assembled and patterned o

53 r self-association and enhanced affinity for lipid bilayer membranes, compared to the wild-type pepti

54 tions of cholesterol and alpha-tocopherol on lipid bilayer membranes composed of different phosphatid

55 Lipid bilayer membranes composed of DOPC, DPPC, and a se

56 sfer to proton translocation across a closed lipid bilayer membrane, conserving the free energy relea

57 molecular dynamics computer simulation of a lipid bilayer membrane consisting of cholesterol and 1-s

58 ing peptide, penetratin, and solid-supported lipid bilayer membranes consisting of either egg phospha

59 , molecular dynamics simulations of hydrated lipid bilayer membranes containing highly polyunsaturate

60 Multicomponent lipid bilayer membranes display rich phase transition an

61 Line tension at fluid lipid bilayer membrane domain boundaries controls the ki

62 Upon reconstitution into the lipid bilayer membrane, Drosophila RyR-C formed a large

63 These peptides are stabilised in a lipid bilayer membrane environment and they are preferen

64 ficult to decipher or assign directly in the lipid-bilayer membrane environment.

65 nted for samples of 1) oriented diI in model lipid bilayer membranes, erythrocytes, and macrophages;

66 len 1 to pyranine, its impermeability to the lipid bilayer membrane, fast kinetics of binding, and ab

67 ation constants of CPR/CYP2C9 complexes in a lipid bilayer membrane for the first time.

68 yringomycin E, when incorporated into planar lipid bilayer membranes, forms two types of channels (sm

69 Lipid bilayer membranes found in nature are heterogeneou

70 icin reconstituted into an artificial planar lipid bilayer membrane from the point of view of electri

71 beta-sheet aggregates upon partitioning into lipid bilayer membranes from the aqueous phase where the

72 ining the delta exon5 CFTR proteins into the lipid bilayer membrane, functional phosphorylation- and

73 spect to the membrane normal of DOPC or DPPC lipid bilayer membranes, GWALP23-R14 shows one major sta

74 o measure transmembrane-protein diffusion in lipid bilayer membranes have advanced in recent decades,

75 ugged channels in an ion-conducting state in lipid bilayer membranes have so far been unsuccessful.

76 raft hypothesis postulates the existence of lipid bilayer membrane heterogeneities, or domains, supp

77 The highly anisotropic environment of the lipid bilayer membrane imposes significant constraints o

78 re we include explicit H(2)O and an infinite lipid bilayer membrane in molecular dynamics (MD) simula

79 nt K-Ras interacts with a negatively charged lipid bilayer membrane in multiple orientations.

80 Stabilization of the lipid bilayer membrane in red blood cells by its associa

81 A method for simulating a two-component lipid bilayer membrane in the mesoscopic regime is prese

82 nd reproducible method to form free-standing lipid bilayer membranes in microdevices made with Norlan

83 naling proteins transduce information across lipid bilayer membranes in response to extra-cellular bi

84 mselves into, and at least partially across, lipid bilayer membranes in the absence of any auxiliary

85 of the skeleton attachment to the fluidlike lipid bilayer membrane, including a specific accounting

86 Platinum microelectrodes are modified with a lipid bilayer membrane incorporating cholesterol oxidase

87 Nanoscale structural reorganization of a lipid bilayer membrane induced by a chemical recognition

88 ine, lysine, tryptophan, and even glycine at lipid bilayer membrane interfaces.

89 The lipid bilayer membrane is 4.6 nm thick, with a low-elect

90 ng the nanoscale dynamic organization within lipid bilayer membranes is central to our understanding

91 and amplification of chemical signals across lipid bilayer membranes is of profound significance in m

92 donor and acceptor molecules in two apposing lipid bilayer membranes is used to resolve topographical

93 y its interactions with a rigid more ordered lipid bilayer membrane, is regulated in plasma membranes

94 rates that peptide 1a interacts with anionic lipid bilayer membranes, like oligomers of full-length a

95 enveloped virus particles (those that lack a lipid-bilayer membrane) must breach the membrane of a ta

96 solution and to cholesterol contained in the lipid bilayer membrane of vesicles.

97 el biophysical insight into the influence of lipid bilayer membranes on conformer preferences and con

98 f the bellflower model demonstrate that in a lipid bilayer membrane or a detergent micelle, the cytop

99 n of Ca2+-ATPase involves PLN monomers, in a lipid bilayer membrane, PLN monomers form stable pentame

100 Physical penetration of lipid bilayer membranes presents an alternative pathway

101 f transport of free fatty acids (FFA) across lipid bilayer membranes remains a subject of debate.

102 one of the most potent anion transporters in lipid bilayer membranes reported to date.

103 s isolated from these transfected cells into lipid bilayer membrane resulted in single Ca(2+) release

104 with structures determined experimentally in lipid bilayer membranes show that eefxPot affords signif

105 contact between the electrode and a vesicle lipid bilayer membrane shows a response that correlates

106 lecular dynamics simulation with an explicit lipid bilayer membrane, similar to the system used for t

107 terol labeled cages on spherically supported lipid bilayer membranes (SSLBM) formed on silica beads,

108 ribution within synthetic cells comprising a lipid bilayer membrane surrounding an aqueous polymer so

109 ly to microscropically unresolvable rafts in lipid bilayers, membrane tension led to the appearance o

110 ryotic counterparts, which are surrounded by lipid bilayer membranes, these microbial organelles are

111 Many proteins are anchored to lipid bilayer membranes through a combination of hydroph

112 lease cytochrome c and to destabilize planar lipid bilayer membranes through reduction of pore line t

113 The surfactant permeabilizes the lipid bilayer membrane to facilitate release of an encap

114 etic molecular transducer from one side of a lipid bilayer membrane to the other.

115 all mammalian cells is the adherence of the lipid bilayer membrane to the underlying membrane associ

116 lasmic reticulum, lowers the rigidity of the lipid bilayer membrane to which it binds.

117 The self-assembly of lipid bilayer membranes to enclose functional biomolecul

118 fication techniques to form myelin-mimicking lipid bilayer membranes to measure both the association

119 ence or absence of an envelope - an external lipid bilayer membrane typically carrying one or more vi

120 Lipid bilayer membranes--ubiquitous in biological system

121 sensitive (MS) channel gated by tension in a lipid bilayer membrane under stresses due to fluid flows

122 The behavior of freestanding lipid bilayer membranes under the influence of dielectri

123 droxyl groups within the hydrocarbon core of lipid bilayer membranes, we examined the structural and

124 iport mechanism and channel formation in the lipid bilayer membranes were confirmed for the most acti

125 cells is known to be supplied by both their lipid bilayer membranes, which resist bending and local

126 in dramatically increases the conductance of lipid bilayer membranes, while non-cytotoxic rat amylin

127 P(2) molecules within the inner leaflet of a lipid bilayer membrane with possible binding sites on Ki

128 alysis reveals the transport of water across lipid bilayer membranes with a relative water permeabili

129 t spontaneously translocate across synthetic lipid bilayer membranes without permeabilization.