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1 content (polar heads and a small fraction of hydrocarbon chains).
2 nd provides steric stabilization through the hydrocarbon chain.
3 um group be presented on a longer or shorter hydrocarbon chain.
4  shapes for the terminal methyl group of the hydrocarbon chain.
5  than in the 9 and 10 positions on the lipid hydrocarbon chain.
6 ydroxy group also was esterified with a long hydrocarbon chain.
7  phosphatidylcholines with 14-20 carbons per hydrocarbon chain.
8 hydrate group is nearly perpendicular to the hydrocarbon chain.
9  the position of the ethereal unit along the hydrocarbon chain.
10 he length and the unsaturation degree of the hydrocarbon chain.
11 nds significantly on the structure of the PE hydrocarbon chains.
12 the mass-resolved heterogeneity of component hydrocarbon chains.
13 with phospholipid headgroups, water, and the hydrocarbon chains.
14  headgroup region and the other two with the hydrocarbon chains.
15 ps was slowed along the entire length of the hydrocarbon chains.
16 mations can only occur for very long, linear hydrocarbon chains.
17 ckbone and upper methylene segments of lipid hydrocarbon chains.
18 onal modification of cysteines by isoprenoid hydrocarbon chains.
19 se previously obtained from PC bilayers with hydrocarbon chains.
20 t for determining the ultimate length of the hydrocarbon chains.
21 hain order, mostly in the lower third of the hydrocarbon chains.
22 at for anionic phospholipids with equivalent hydrocarbon chains.
23 holipids with the same head group but longer hydrocarbon chains.
24 ning phosphatidylcholine (PC) with different hydrocarbon chains.
25 s that have different lengths and numbers of hydrocarbon chains.
26 ebach alkylation reaction products with long hydrocarbon chains.
27 2), indicating differences in the packing of hydrocarbon chains.
28 ability to protrude between the phospholipid hydrocarbon chains.
29 dent on the position of the nitroxide on the hydrocarbon chain; 7-Doxyl PC reduced the percent peptid
30 ic acid 18:1, all with a monounsaturated C18 hydrocarbon chain activate TRPV1, whereas polyunsaturate
31 siderable differences between the two single hydrocarbon chain amino-alcohols.
32 a double bond into an unsaturated fatty-acid hydrocarbon chain and convert n-6 to n-3 fatty acids.
33  tails on both alkyl chains and PCs with one hydrocarbon chain and one fluoroalkylated chain.
34 e frequency of gauche-trans isomerization of hydrocarbon chains and concentration of vacant pockets (
35 ion rates between terminal methyl protons of hydrocarbon chains and ethanol are as much the result of
36 facial area of the bilayer by disrupting the hydrocarbon chains and extending the interfacial area to
37  affect the conformations and packing of the hydrocarbon chains and produces only a slight reduction
38 n hydrophobic regions of the monopolar lipid hydrocarbon chains and the membrane-spanning bolalipid c
39  chain region, determined by the tilt of the hydrocarbon chains and transmembrane domain with respect
40 of gauche conformations near the ends of the hydrocarbon chains and, in addition to verifying a previ
41 aturated 32:x (x = number of double bonds in hydrocarbon chain) and 34:x acyl chains increased.
42 ative-charged fatty acid ligands with a long hydrocarbon chain, and a proper temperature range (appro
43  in the interfacial region between water and hydrocarbon chain, and it doesn't penetrate deeply into
44 n, with introduction of polyunsaturated sn-2 hydrocarbon chains, and with replacement of the palmitic
45 he identification of chemical defects, where hydrocarbon chains are accessible to the solvent, and ge
46 ids like PIP(2) that contain polyunsaturated hydrocarbon chains are usually excluded from rafts, whic
47  outer membrane contains a similar number of hydrocarbon chains as the inner leaflet composed of myco
48  achieved by using fatty amines with a short hydrocarbon chain at a low ligand concentration in the s
49 near molecules (i.e., compounds with a short hydrocarbon chain at C-2 or C-3 and a long hydrocarbon c
50            Compounds with short (<5 carbons) hydrocarbon chains at both C-2 and C-3 were generally in
51 ulating the order parameter profiles for the hydrocarbon chains, atom distributions, average number o
52  poly(ethylene glycol), polymers with linear hydrocarbon chains; (b) bovine serum albumin, biopolymer
53 r mobility, polymers are functionalized with hydrocarbon chains by strategically manipulating the alk
54 er-and ester-containing phospholipids, whose hydrocarbon chains can be either linear or branched, usi
55 pid order of upper and lower sections of the hydrocarbon chains caused by changes of temperature, uns
56                            The saturation of hydrocarbon chains confers the ability to resist hydroly
57 ibomian gland dysfunction reflect changes in hydrocarbon chain conformation and lipid-lipid interacti
58                 No significant change in the hydrocarbon chain conformations is apparent.
59 g functional groups, which demonstrated that hydrocarbon chains could serve as molecular features in
60 rely hydrocarbon structures, indicating that hydrocarbon chains could serve as molecular features in
61 roadening can be interpreted in terms of the hydrocarbon chain crystallization and slow dynamics of t
62                     A series of long (11-15) hydrocarbon chain diols and diacids with various central
63                Increased lipid oxidation and hydrocarbon chain disorder correlate with increased lens
64 e (DiI) head groups and short or unsaturated hydrocarbon chains (e.g. DiIC(12) and FAST DiI) enter th
65                                         Long hydrocarbon chain ethers with bis-terminal hydroxyl or c
66 mbrane segments M1, M2, M4, and M6, with the hydrocarbon chains following passively, still in the mem
67 me of terpene biosynthesis that supplies the hydrocarbon chain for chlorophyll and tocopherol.
68 lcohol phosphates (FAP) containing saturated hydrocarbon chains from 4 to 22 carbons in length.
69    Electron density profiles showed that the hydrocarbon chains from apposing GalCer monolayers parti
70 ations of 7 phospholipids and 43 segments of hydrocarbon chains greater than 5 atoms in length have b
71 diacyl phosphatidylethanolamines (PEs) whose hydrocarbon chains have the same effective chain length
72 ormation of end-to-end contact in the linear hydrocarbon chain (HC) CH(3)(CH(2))(18)CH(3).
73 onformational flexibility of polyunsaturated hydrocarbon chains in membranes.
74  of 10 kHz the methylene proton resonance of hydrocarbon chains in the ld phase has a linewidth of 50
75 so locally modifies the hexagonal packing of hydrocarbon chains in the liquid-ordered phase of PSM mi
76 that the insertion of the lipopolysaccharide hydrocarbon chains in the target host cell membrane may
77 m-methanol-water, revealing that one-half of hydrocarbon chains in this membrane are contributed by a
78  of life and is nature's way of transporting hydrocarbon chains in vivo.
79  order of both saturated and polyunsaturated hydrocarbon chains increases.
80             Anionic phospholipids with short hydrocarbon chains induce only low alpha-helical content
81 s outside the binding tunnel and the exposed hydrocarbon chain interacts with hydrophobic amino acids
82 e plane of monolayer within the phospholipid hydrocarbon chain layer.
83 ion of genes enabled rational alterations to hydrocarbon chain length (Cn) and the production of bran
84 The inhibitory effect of FAP showed a strong hydrocarbon chain length dependence with C12 being optim
85 high-mass cluster formation as a function of hydrocarbon chain length of the alkanethiol SAM surfaces
86 -transmembrane ratio strongly depends on the hydrocarbon chain length of the monopolar lipid and the
87 M surfaces, which included both odd and even hydrocarbon chain length thiols.
88                                   Changes of hydrocarbon chain length were measured by (2)H NMR, and
89 ences in membrane thickness, area per lipid, hydrocarbon chain length, and bending fluctuation as dem
90 rtitioning into lipoprotein depending on the hydrocarbon chain length, and the symmetrical azo initia
91                     Owing to the increase in hydrocarbon chain length, DEG possesses a higher viscosi
92 eadgroup chemistry of the surfactant and the hydrocarbon chain length, which influence both the morph
93 imilar to phosphatidylcholines with the same hydrocarbon chain length.
94 ystem for large scale olefin production with hydrocarbon chains lengths equivalent to those of fossil
95  have been analyzed, specifically, the water-hydrocarbon chain, lipid-lipid and lipid-water interacti
96 istics of the C16:0-GalSulf bilayer occur on hydrocarbon chain melting and lead to major changes in l
97 such as phosphatidylcholine with unsaturated hydrocarbon chains, microdomains (rafts) form in these m
98 cursions of ethanol into the region of lipid hydrocarbon chains near the glycerol.
99 isphosphonates containing long (n = 9 or 10) hydrocarbon chains, not the nitrogen-containing species
100           Competitive incorporation into the hydrocarbon chain of nitrogen versus oxygen as a mode of
101 ning the ester-linked unsaturated (linoleic) hydrocarbon chain of skin ceramide 1.
102 of the newly formed C3-C4 double bond in the hydrocarbon chain of the inhibitor.
103  of bolalipids, as well as the length of the hydrocarbon chain of the monopolar lipids, was probed.
104 nhanced as the number of carbons (Cn) in the hydrocarbon chain of the phospholipids increased from 10
105 t for bilayers containing phospholipids with hydrocarbon chains of 18-22 carbon atoms.
106 cellular mouth of the channel blocked by the hydrocarbon chains of Arg+ residues.
107 in vitro by using small amounts of aliphatic hydrocarbon chains of detergents or fatty acids in prepa
108 fy the number of water dangling bonds around hydrocarbon chains of different length.
109 he average area of membrane becomes smaller, hydrocarbon chains of DPPC have higher order, and the pr
110 esonance experiments show that below Tm, the hydrocarbon chains of F-DPPC are more motionally restric
111                     The close packing of the hydrocarbon chains of fatty acids dictated the up temper
112     In mammals and now in Dictyostelium, the hydrocarbon chains of inositol phospholipids are a highl
113                            It was found that hydrocarbon chains of lipids adjacent to the channel had
114   Partitioned halothane molecules affect the hydrocarbon chains of the DOPC lipid, by lowering of the
115 he terminal methyl groups of the hydrophobic hydrocarbon chains of the lipid molecules, and that on a
116 rol tends to reduce the angle of tilt of the hydrocarbon chains of the phospholipid in the gel phase
117 diketopiperazine ring was inserted between a hydrocarbon chain (of variable length) and an anionic he
118 t hydrocarbon chain at C-2 or C-3 and a long hydrocarbon chain on C-3 or C-2, respectively) were more
119                                        Lipid hydrocarbon chain order (rigidity) increased from approx
120              The extent of normal lens lipid hydrocarbon chain order increased with age from the equa
121 y of G protein activation and an increase of hydrocarbon chain order induced by CHS or cholesterol.
122                                        Lipid hydrocarbon chain order parameters calculated from the L
123 evels with species, age, and cataract, lipid hydrocarbon chain order, or stiffness, increases.
124 stence (L(o)/L(d)) are composed of saturated hydrocarbon chains packed with local hexagonal order and
125 ns caused by BPL to the LPS membrane, in LPS hydrocarbon chain packing and in the formation of BPL-en
126 rovided by LPS is primarily due to its tight hydrocarbon chain packing rather than to its polysacchar
127 -angle reflection at 4.1 A, indicating tight hydrocarbon chain packing that would function as a water
128  approximately 12.6 nm spacing and hexagonal hydrocarbon chain packing with mainly all-trans configur
129 e of the PMF, finite size effects, and lipid hydrocarbon chain polarizability.
130    Reaction of M9 with a model compound of a hydrocarbon chain preferentially yields M2.
131 e tilt of the transmembrane helix within the hydrocarbon chain region in determining its tertiary str
132 e catalytic site, where they extend into the hydrocarbon chain region of the outer leaflet.
133 e hydrophobic transmembrane helix within the hydrocarbon chain region tilted with respect to the mono
134                         The thickness of the hydrocarbon chain region, determined by the tilt of the
135 orption band's magnitude was observed in the hydrocarbon chain region, suggesting suppressed bond vib
136 ids is accounted for by the expansion in the hydrocarbon chain region.
137 anism, contains two unusual trans-2-octenoyl hydrocarbon chains reminiscent of a phospholipid structu
138 h the silicon located at the terminus of the hydrocarbon chain, resulting in a highly selective base-
139  increase in sphingolipid was an increase in hydrocarbon chain saturation.
140 ea per lipid and the details of the in-plane hydrocarbon chain structure were in excellent agreement
141 ncreases of the order parameter of the lipid hydrocarbon chains, suggesting that the lipid bilayer be
142  energy of the latter on a radical site of a hydrocarbon chain suggests that mechanisms such as Langm
143 taining two tetrahydrofuran (THF) rings with hydrocarbon chains tethered to each ring; an alpha,beta-
144 loited to attach oligosaccharides to a C(14) hydrocarbon chain that noncovalently binds to the microt
145  there is partial rotational ordering in the hydrocarbon chains, that the two chains in a given molec
146 g provides evidence that, in contrast to the hydrocarbon chains, the headgroups of the phospholipid m
147 ed-phase interaction results from the bonded hydrocarbon chain; the ion-exchange interaction originat
148 se containing phenol residues or hydrophobic hydrocarbon chains, triggered rapid (<10 min) and robust
149                             The influence of hydrocarbon chain unsaturation on Ca(2+) binding is seco
150        However, depending on temperature and hydrocarbon chain unsaturation, the lipid with the highe
151 ng constraints that were calculated from the hydrocarbon-chain volume and effective headgroup area of
152                                 The area per hydrocarbon chain was approximately 26 A2 in liquid-crys
153 elf-sorting between peptide beta-strands and hydrocarbon chains, we have demonstrated the formation o
154 ameters of the peptide helices and the lipid hydrocarbon chains were determined from measurements of
155 nic phospholipid derivatives with asymmetric hydrocarbon chains were synthesized: ethyl esters of ole
156 ove and in the same plane as the sphingosine hydrocarbon chain, while in L-threo-LacCer the carbohydr
157 trol in the functionalization of unactivated hydrocarbon chains will greatly facilitate the developme

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