Structural and functional properties of hydration and confined water in membrane interfaces

Disalvo, E.A.; Lairion, Fabiana; Martini, M. Florencia; Tymczyszyn, E. Elizabeth; Frías, María A.; Almaleck, H.; Gordillo, Gabriel Jorge

doi:10.1016/j.bbamem.2008.08.025

Cited by 202 publications

(216 citation statements)

References 136 publications

Supporting

Mentioning

197

Contrasting

Unclassified

Order By: Relevance

“…58,59 However, the two esters show different hydration and lipid-lipid interactions from one another, due to the different orientation and depth of these ester groups within the lipid bilayer. The regions of interaction around the second ester differ, depending on the nieghboring moiety in question.…”

Section: Discussionmentioning

confidence: 99%

Comparative atomic-scale hydration of the ceramide and phosphocholine headgroup in solution and bilayer environments

Gillams

Lorenz

McLain

2016

The Journal of Chemical Physics

View full text Add to dashboard Cite

Previous studies have used neutron diffraction to elucidate the hydration of the ceramide and the phosphatidylcholine headgroup in solution. These solution studies provide bond-length resolution information on the system, but are limited to liquid samples. The work presented here investigates how the hydration of ceramide and phosphatidylcholine headgroups in a solution compares with that found in a lipid bilayer. This work shows that the hydration patterns seen in the solution samples provide valuable insight into the preferential location of hydrating water molecules in the bilayer. There are certain subtle differences in the distribution, which result from a combination of the lipid conformation and the lipid-lipid interactions within the bilayer environment. The lipid-lipid interactions in the bilayer will be dependent on the composition of the bilayer, whereas the restricted exploration of conformational space is likely to be applicable in all membrane environments. The generalized description of hydration gathered from the neutron diffraction studies thus provides good initial estimation for the hydration pattern, but this can be further refined for specific systems. Published by AIP Publishing. [http://dx

show abstract

Section: Discussionmentioning

confidence: 99%

Comparative atomic-scale hydration of the ceramide and phosphocholine headgroup in solution and bilayer environments

Gillams

Lorenz

McLain

2016

The Journal of Chemical Physics

View full text Add to dashboard Cite

show abstract

“…[42][43][44] Water self-diffusion coefficients D w have been obtained from the analysis of the time-dependence of the mean square displacement (MSD) of oxygen molecules, displayed in Fig. 7.…”

Section: Water Diffusionmentioning

confidence: 99%

Diffusion and spectroscopy of water and lipids in fully hydrated dimyristoylphosphatidylcholine bilayer membranes

Yang

Calero

Martı́

2014

The Journal of Chemical Physics

View full text Add to dashboard Cite

Microscopic structure and dynamics of water and lipids in a fully hydrated dimyristoylphosphatidylcholine phospholipid lipid bilayer membrane in the liquid-crystalline phase have been analyzed with all-atom molecular dynamics simulations based on the recently parameterized CHARMM36 force field. The diffusive dynamics of the membrane lipids and of its hydration water, their reorientational motions as well as their corresponding spectral densities, related to the absorption of radiation, have been considered for the first time using the present force field. In addition, structural properties such as density and pressure profiles, a deuterium-order parameter, surface tension, and the extent of water penetration in the membrane have been analyzed. Molecular self-diffusion, reorientational motions, and spectral densities of atomic species reveal a variety of time scales playing a role in membrane dynamics. The mechanisms of lipid motion strongly depend on the time scale considered, from fast ballistic translation at the scale of picoseconds (effective diffusion coefficients of the order of 10 −5 cm 2 /s) to diffusive flow of a few lipids forming nanodomains at the scale of hundreds of nanoseconds (diffusion coefficients of the order of 10 −8 cm 2 /s). In the intermediate regime of subdiffusion, collisions with nearest neighbors prevent the lipids to achieve full diffusion. Lipid reorientations along selected directions agree well with reported nuclear magnetic resonance data and indicate two different time scales, one about 1 ns and a second one in the range of 2-8 ns. We associated the two time scales of reorientational motions with angular distributions of selected vectors. Calculated spectral densities corresponding to lipid and water reveal an overall good qualitative agreement with Fourier transform infrared spectroscopy experiments. Our simulations indicate a blue-shift of the low frequency spectral bands of hydration water as a result of its interaction with lipids. We have thoroughly analyzed the physical meaning of all spectral features from lipid atomic sites and correlated them with experimental data. Our findings include a "wagging of the tails" frequency around 30 cm −1 , which essentially corresponds to motions of the tail-group along the instantaneous plane formed by the two lipid tails, i.e., in-plane oscillations are clearly of bigger importance than those along the normal-to-the plane direction. © 2014 AIP Publishing LLC.

show abstract

“…Hydration, which describes the highly depth-dependent distribution and dynamics of water molecules in the lipid membranes [ 65 ], is connected with membrane electrostatics since the oriented water dipoles solvating both phosphate and carbonyl groups contribute to the electric fi elds in the bilayer [ 66 ]. Because water is the most important H-bonding contributor, membrane hydration is generally evaluated with fl uorescent probes presenting wavelength-shifts [ 67 ] or quenching [ 68 ] resulting from dipolar and H-bonding interactions with water.…”

Section: Information Extracted From Biomembrane Probesmentioning

confidence: 99%

Introduction to Fluorescence Probing of Biological Membranes

Demchenko

Duportail

Oncul³

et al. 2014

Methods in Molecular Biology

View full text Add to dashboard Cite

Fluorescence is one of the most powerful and commonly used tools in biophysical studies of biomembrane structure and dynamics that can be applied on different levels, from lipid monolayers and bilayers to living cells, tissues, and whole animals. Successful application of this method relies on proper design of fluorescence probes with optimized photophysical properties. These probes are efficient for studying the microscopic analogs of viscosity, polarity, and hydration, as well as the molecular order, environment relaxation, and electrostatic potentials at the sites of their location. Being smaller than the membrane width they can sense the gradients of these parameters across the membrane. We present examples of novel dyes that achieve increased spatial resolution and information content of the probe responses. In this respect, multiparametric environment-sensitive probes feature considerable promise.

show abstract

Structural and functional properties of hydration and confined water in membrane interfaces

Cited by 202 publications

References 136 publications

Comparative atomic-scale hydration of the ceramide and phosphocholine headgroup in solution and bilayer environments

Comparative atomic-scale hydration of the ceramide and phosphocholine headgroup in solution and bilayer environments

Diffusion and spectroscopy of water and lipids in fully hydrated dimyristoylphosphatidylcholine bilayer membranes

Introduction to Fluorescence Probing of Biological Membranes

Contact Info

Product

Resources

About