Ordering effects of cholesterol and its analogues

Róg, Tomasz; Pasenkiewicz-Gierula, Marta; Vattulainen, Ilpo; Karttunen, Mikko

doi:10.1016/j.bbamem.2008.08.022

Cited by 518 publications

(274 citation statements)

References 292 publications

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“…Although estimation of the bending modulus at the nanometer edge is a challenging problem (Nakamura and Shinoda, 2013), we suspect that the increase of the cholesterol concentration around the pore edge increases the bending modulus of the pore edge and the line tension (Genova et al, 2014). According to previous experimental (Mills and Toombes, 2008) and simulation studies (Róg et al, 2009), cholesterol molecules rectify the disordered orientations of hydrophobic tails of co-existing phospholipid molecules, which is one of the causes for the high bending moduli of cholesterol-containing bilayers. In our MD simulations, the cholesterol molecules are distributed around the pore edge (Fig.…”

Section: Cholesterol Effects On Line Tensionmentioning

confidence: 99%

Line tension of the pore edge in phospholipid/cholesterol bilayer from stretch molecular dynamics simulation

Shigematsu

Koshiyama

Wada

2015

JBSE

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The line tension of the pore in a phospholipid bilayer is important for pore-mediated molecular transport techniques. To understand the cholesterol effects on the line tension of the pore edge at the molecular level, we perform molecular dynamics simulations of phospholipid bilayers with a pore containing cholesterol in different concentrations (0, 20, and 40 mol%). The bilayer with a pore is prepared by using an equibiaxial stretching simulation. The stretched bilayer with a pore is subsequently compressed and the pore spontaneously closes when the applied areal strain of the bilayer is below a certain value. Using the pore closure areal strain and a free energy model of a stretched bilayer with a pore, the upper and lower limits of the line tensions for the bilayers containing cholesterol at 0, 20, and 40 mol% are estimated to be 17.0-48.2, 54.5-100, and 170-261 pN, respectively. The increasing tendency of the line tension qualitatively agrees with that observed experimentally. The pores in the cholesterol-containing bilayers are lined with several cholesterol molecules, which might increase the bending rigidity of the pore edge, and result in the higher line tension of the cholesterol-containing bilayer. The considerable dependency of the line tension on the bilayer compositions might be useful to explain the large variations of the transduction efficiency observed with sonoporation treatment.

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Section: Cholesterol Effects On Line Tensionmentioning

confidence: 99%

Line tension of the pore edge in phospholipid/cholesterol bilayer from stretch molecular dynamics simulation

Shigematsu

Koshiyama

Wada

2015

JBSE

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“…Cholesterol molecules happens to be incorporated into the phospholipid's bilayer thus causing increase separation between the choline head groups, reduces the hydrogen bonding strengths and electrostatic interaction. This makes the membrane more stable and lowers its permeability to water and other molecules (Ohvo-Rekilä et al 2002;Róg et al 2009). A special role plays calcium Ca ?2 cations causing modulation of the insertion of proteins.…”

Section: Introductionmentioning

confidence: 99%

Zeta potential and surface charge of DPPC and DOPC liposomes in the presence of PLC enzyme

2016

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Zeta potential of liposomes is often measured in studies of their properties and/or applications. However, there are not many papers published in which zeta potential was determined during enzymatic reaction of a lipid. Therefore in this paper size, polydispersity index, and zeta potentials of 1,2-dipalmitoylsn-glycero-3-phosphatidylcholine (DPPC) and 1,2-dioleoyl-sn-glycero-3-phosphatidylcholine (DOPC) liposomes were investigated in 1 mM NaCl (pH 6.2) and phosphate buffer (pH 8.1) during 60 min of phospholipase C action at 20 and 37°C. The hydrocarbon chains saturation differ these two phospholipids what appears in some differences in the zeta potential changes during the hydrolysis reaction run. The polydispersity index of the liposomes indicates that they are relatively stable and monodisperse, except for DPPC in phosphate buffer where up to 30 % of the initial amount forms larger size moieties, possibly aggregates of the liposomes, enzyme and the hydrolysis products. However, in this buffer zeta potential of the liposomes practically does not change during PLC action. Also the changes of zeta potential of DOPC liposomes are minor, although their negative values are much smaller than those of DPPC at both temperatures. These small changes of the potential may be due to compression of the diffuse double layer by present phosphate buffer. However, distinct changes of the zeta potentials in the presence of PLC take place in NaCl solution. The observed changes can be explained by reorientation of the phospholipid polar heads and their different density on DPPC and DOPC surface of the liposomes. Although it appeared that the zeta potential is not a very sensitive parameter for tracking the hydrolysis reaction in phosphate buffer, generally zeta potential enables the characterization of such reactions through determination of electrokinetic properties of liposomes as well as the polydispersity and size distribution of the liposomes do.

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“…Lipid chain ordering within the bilayers. The ordering was quantified via the deuterium order parameter, −S CD , which is defined as −S CD = (1/2) S z , where S z = (1/2) «3cos 2 (θ z ) − 1», and θ z stands for the angle between the C-H bond vector and the bilayer normal, and the double angle bracket denotes the ensemble average [16]. S z can vary between 1 (full order along the normal) and -0.5 (full order perpendicular to the normal).…”

Section: Resultsmentioning

confidence: 99%

Be straight to better coordinate two -- Head groups and extended acyl chains of raft-like bilayer lipids can localize in groove between dimerized transmembrane helical peptides and assist sequence-nonspecific stabilization of peptide dimers by cholesterol

Nishizawa¹,

Nishizawa²

2017

Biomed Res Clin Prac

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Ordering effects of cholesterol and its analogues

Cited by 518 publications

References 292 publications

Line tension of the pore edge in phospholipid/cholesterol bilayer from stretch molecular dynamics simulation

Line tension of the pore edge in phospholipid/cholesterol bilayer from stretch molecular dynamics simulation

Zeta potential and surface charge of DPPC and DOPC liposomes in the presence of PLC enzyme

Be straight to better coordinate two -- Head groups and extended acyl chains of raft-like bilayer lipids can localize in groove between dimerized transmembrane helical peptides and assist sequence-nonspecific stabilization of peptide dimers by cholesterol

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