The Human Skin Barrier Is Organized as Stacked Bilayers of Fully Extended Ceramides with Cholesterol Molecules Associated with the Ceramide Sphingoid Moiety

Iwai, Ichiro; Hong-mei, Han; Hollander, Lianne den; Svensson, Stina; Öfverstedt, Lars-Göran; Anwar, Jamshed; Brewer, Jonathan R.; Bloksgaard, Maria; Laloeuf, Aurelie; Nosek, Daniel; Masich, Sergej; Bagatolli, Luís A.; Skoglund, Ulf; Norlén, Lars

doi:10.1038/jid.2012.43

Cited by 204 publications

(258 citation statements)

References 33 publications

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“…Simulations [48] show that galactosylceramides occupy an area/lipid similar to sphingomyelin in bilayers containing sphingomyelin and CHOL, which is much larger than the typical area/molecule in the SC membranes. The presence of this large sugar moiety will disfavour the extended tail arrangement seen in some CER crystal structures and hypothesized in some models of SC lipid arrangement [12], and make hydrated bilayers thermodynamically stable. Only once the unilamellar vesicles have been transported out of the cells is the sugar moiety removed, which then can lead to a gel-like membrane; at this point, the vesicles seem to lose internal water and fold into a stacked disc-like structure [7].…”

Section: (B) Summarymentioning

confidence: 94%

The physics of stratum corneum lipid membranes

Das

Olmsted

2016

Phil. Trans. R. Soc. A.

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The stratum corneum (SC), the outermost layer of skin, comprises rigid corneocytes (keratin-filled dead cells) in a specialized lipid matrix. The continuous lipid matrix provides the main barrier against uncontrolled water loss and invasion of external pathogens. Unlike all other biological lipid membranes (such as intracellular organelles and plasma membranes), molecules in the SC lipid matrix show small hydrophilic groups and large variability in the length of the alkyl tails and in the numbers and positions of groups that are capable of forming hydrogen bonds. Molecular simulations provide a route for systematically probing the effects of each of these differences separately. In this article, we present the results from atomistic molecular dynamics of selected lipid bilayers and multi-layers to probe the effect of these polydispersities. We address the nature of the tail packing in the gel-like phase, the hydrogen bond network among head groups, the bending moduli expected for leaflets comprising SC lipids and the conformation of very long ceramide lipids in multi-bilayer lipid assemblies.

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Section: (B) Summarymentioning

confidence: 94%

The physics of stratum corneum lipid membranes

Das

Olmsted

2016

Phil. Trans. R. Soc. A.

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“…The comparison between the images obtained using a conventional preparation and CEMOVIS showed differences in the organization of bacterial DNA and cell wall of Mycobacterium smegmatis [35] and Shigella flexneri [42] and presented new insights into the morphology of bacteria [32,[43][44][45]. This technique enabled to show details of the design of melanosomes [46], the human skin barrier [47] and the molecular architecture of cadherins in native epidermal desmosomes [34].…”

Section: Cryo-electron Microscopy Of Vitreous Sectionsmentioning

confidence: 96%

Closer to the native state. Critical evaluation of cryo-techniques for Transmission Electron Microscopy: preparation of biological samples

Mielańczyk

Matysiak

Michalski

et al. 2014

Folia Histochem Cytobiol.

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Abstract:Over the years Transmission Electron Microscopy (TEM) has evolved into a powerful technique for the structural analysis of cells and tissues at various levels of resolution. However, optimal sample preservation is required to achieve results consistent with reality. During the last few decades, conventional preparation methods have provided most of the knowledge about the ultrastructure of organelles, cells and tissues. Nevertheless, some artefacts can be introduced at all stagesofstandard electron microscopy preparation technique. Instead, rapid freezing techniques preserve biological specimens as close as possible to the native state. Our review focuses on different cryo-preparation approaches, starting from vitrification methods dependent on sample size. Afterwards, we discuss Cryo-Electron Microscopy Of VItreous Sections (CEMOVIS) and the main difficulties associated with this technique. Cryo-Focused Ion Beam (cryo-FIB) is described as a potential alternative for CEMOVIS. Another post-processing route for vitrified samples is freeze substitution and embedding in resin for structural analysis or immunolocalization analysis. Cryo-sectioning according to Tokuyasu is a technique dedicated to high efficiency immunogold labelling. Finally, we introduce hybrid techniques, which combine advantages of primary techniques originally dedicated to different approaches. Hybrid approaches permit to perform the study of difficult-to-fix samples and antigens or help optimize the sample preparation protocol for the integrated Laser and Electron Microscopy (iLEM) technique

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“…Previous studies described separation of cholesterol from the lamellar phases (Mojumdar et al, 2015b;Schreiner et al, 2000); however, the physiological relevance of this separation is not known. In contrast, recent study using very high resolution electron microscopy on vitreous skin sections found no cholesterol crystals (Iwai et al, 2012). Cholesteryl sulphate, that is, ester of sulphuric acid with cholesterol, is a minor component of the stratum corneum lipid matrix; it is present in approximately 5% of the barrier lipids (or approximately 2% of all lipids including surface lipids (Lampe et al, 1983)).…”

Section: Composition Of the Skin Lipid Barriermentioning

confidence: 96%

“…4). Although the extended conformation is not common in biological membranes, it could be advantageous for the stratum corneum barrier properties (Corkery, 2002;Iwai et al, 2012). First, it would reduce the packing strain of ceramide because they have a smaller cross-section of the polar head than of the chains and there are no lipids with bulky polar heads to compensate for such unfavourable packing ratio of hairpin ceramide.…”

Section: Molecular Arrangement Of the Skin Lipid Barriermentioning

confidence: 99%

Ceramides in the skin barrier

Vávrová

Kováčik

Opálka

2017

European Pharmaceutical Journal

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The skin barrier, which is essential for human survival on dry land, is located in the uppermost skin layer, the stratum corneum. The stratum corneum consists of corneocytes surrounded by multilamellar lipid membranes that prevent excessive water loss from the body and entrance of undesired substances from the environment. To ensure this protective function, the composition and organization of the lipid membranes is highly specialized. The major skin barrier lipids are ceramides, fatty acids and cholesterol in an approximately equimolar ratio. With hundreds of molecular species of ceramide, skin barrier lipids are a highly complex mixture that complicate the investigation of its behaviour. In this minireview, the structures of the major skin barrier lipids, formation of the stratum corneum lipid membranes and their molecular organization are described.

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The Human Skin Barrier Is Organized as Stacked Bilayers of Fully Extended Ceramides with Cholesterol Molecules Associated with the Ceramide Sphingoid Moiety

Cited by 204 publications

References 33 publications

The physics of stratum corneum lipid membranes

The physics of stratum corneum lipid membranes

Closer to the native state. Critical evaluation of cryo-techniques for Transmission Electron Microscopy: preparation of biological samples

Ceramides in the skin barrier

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