Sheeja V. Vasudevan scite author profile

We have carried out an atomic-level molecular dynamics simulation of a system of nanoscopic size containing a domain of 18:0 sphingomyelin and cholesterol embedded in a fully hydrated dioleylposphatidylcholine (DOPC) bilayer. To analyze the interaction between the domain and the surrounding phospholipid, we calculate order parameters and area per molecule as a function of molecule type and proximity to the domain. We propose an algorithm based on Voronoi tessellation for the calculation of the area per molecule of various constituents in this ternary mixture. The calculated areas per sphingomyelin and cholesterol are in agreement with previous simulations. The simulation reveals that the presence of the liquid-ordered domain changes the packing properties of DOPC bilayer at a distance as large as approximately 8 nm. We calculate electron density profiles and also calculate the difference in the thickness between the domain and the surrounding DOPC bilayer. The calculated difference in thickness is consistent with data obtained in atomic force microscopy experiments.

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Structure of Sphingomyelin Bilayers: A Simulation Study

Chiu

Vasudevan

Jakobsson

et al. 2003

Biophysical Journal

141

135

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We have carried out a molecular dynamics simulation of a hydrated 18:0 sphingomyelin lipid bilayer. The bilayer contained 1600 sphingomyelin (SM) molecules, and 50,592 water molecules. After construction and initial equilibration, the simulation was run for 3.8 ns at a constant temperature of 50 degrees C and a constant pressure of 1 atm. We present properties of the bilayer calculated from the simulation, and compare with experimental data and with properties of dipalmitoyl phosphatidylcholine (DPPC) bilayers. The SM bilayers are significantly more ordered and compact than DPPC bilayers at the same temperature. SM bilayers also exhibit significant intramolecular hydrogen bonding between phosphate ester oxygen and hydroxyl hydrogen atoms. This results in a decreased hydration in the polar region of the SM bilayer compared with DPPC. Since our simulation system is very large we have calculated the power spectrum of bilayer undulation and peristaltic modes, and we compare these data with similar calculations for DPPC bilayers. We find that the SM bilayer has significantly larger bending modulus and area compressibility compared to DPPC.

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A Monomeric, Biologically Active, Full-Length Human Apolipoprotein E

et al. 2007

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Apolipoprotein E (apoE) is an exchangeable apolipoprotein that plays an important role in lipid/lipoprotein metabolism and cardiovascular diseases. Recent evidence indicates that apoE is also critical in several other important biological processes, including Alzheimer's disease, cognitive function, immunoregulation, cell signaling, and infectious diseases. Although the X-ray crystal structure of the apoE N-terminal domain was solved in 1991, the structural study of full-length apoE is hindered by apoE's oligomerization property. Using protein-engineering techniques, we generated a monomeric, biologically active, full-length apoE. Cross-linking experiments indicate that this mutant is nearly 95-100% monomeric even at 20 mg/mL. CD spectroscopy and guanidine hydrochloride denaturation demonstrate that the structure and stability of the monomeric mutant are identical to wild-type apoE. Monomeric and wild-type apoE display similar lipid-binding activities in dimyristoylphosphatidylcholine clearance assays and formation of reconstituted high-density lipoproteins. Furthermore, the monomeric and wild-type apoE proteins display an identical LDL receptor binding activity. Availability of this monomeric, biologically active, full-length apoE allows us to collect high quality NMR data for structural determination. Our initial NMR data of lipid-free apoE demonstrates that the N-terminal domain in the full-length apoE adopts a nearly identical structure as the isolated N-terminal domain, whereas the C-terminal domain appears to become more structured than the isolated C-terminal domain fragment, suggesting a weak domain-domain interaction. This interaction is confirmed by NMR examination of a segmental labeled apoE, in which the N-terminal domain is deuterated and the C-terminal domain is double-labeled. NMR titration experiments further suggest that the hinge region (residues 192-215) that connects apoE's N- and C-terminal domains may play an important role in mediating this domain-domain interaction.

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Protein folding at the membrane interface, the structure of Nogo-66 requires interactions with a phosphocholine surface

Vasudevan

Schulz²,

Zhou³

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

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Repair of damage to the central nervous system (CNS) is inhibited by the presence of myelin proteins that prevent axonal regrowth. Consequently, growth inhibitors and their common receptor have been identified as targets in the treatment of injury to the CNS. Here we describe the structure of the extracellular domain of the neurite outgrowth inhibitor (Nogo) in a membrane-like environment. Isoforms of Nogo are expressed with a common C terminus containing two transmembrane (TM) helices. The ectodomain between the two TM helices, Nogo-66, is active in preventing axonal growth [GrandPre T, Nakamura F, Vartanian T, Strittmatter SM (2000) Nature 403:439-444]. We studied the structure of Nogo-66 alone and in the presence of 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC) vesicles and dodecylphosphocholine (DPC) micelles as membrane mimetics. We find that Nogo-66 is largely disordered when free in solution. However, when bound to a phosphocholine surface Nogo-66 adopts a unique, stable fold, even in the absence of TM anchors. Using paramagnetic probes and protein-DPC nuclear Overhauser effects (NOEs), we define portions of the growth inhibitor likely to be accessible on the cell surface. With these data we predict that residues (28-58) are available to bind the Nogo receptor, which is entirely consistent with functional assays. Moreover, the conformations and relative positions of side chains recognized by the receptor are now defined and provide a foundation for antagonist design.peripheral | lipid surface | CNS | membrane protein | nmr

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Dynamics of Ganglioside Headgroup in Lipid Environment: Molecular Dynamics Simulations of GM1 Embedded in Dodecylphosphocholine Micelle

Vasudevan

Balaji

2001

J. Phys. Chem. B

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Recognition of membrane-anchored glycosphingolipid receptors by various ligands is the key event in several biological phenomena. However, mere presence of these cell-surface receptors does not always ensure their recognition and binding by their respective ligands, a phenomenon termed "crypticity". Earlier studies have suggested that different glycan headgroup orientations exposing and/or masking different epitopes may explain the crypticity of glycolipids. The effect of lipid environment on the orientation and conformation of GM1 ganglioside has been investigated in the present study by MD simulation technique in an attempt to understand the structural basis of crypticity. In addition, the effect of the length of the ceramide hydrocarbon tails on the headgroup conformation has also been investigated. MD simulations for 1 ns were performed with explicit water molecules for both GM1 headgroup (GM1-Os) and GM1 embedded in dodecylphosphocholine micelle. The simulations show that the conformations of the hydrocarbon tails, ceramide-saccharide linkages, and the headgroup are inter-related and are affected by micellar packing considerations. The conformations of GalNAc-β1f4-Gal and Neu5Ac-R2f3-Gal linkages were found to be restricted when GM1 is embedded in the micelle compared to that in GM1-Os. The GalNAc-β1f4-Gal linkage being a branch point, affects the orientation/accessibility of all the residues linked to GalNAc. If such a disallowed glycan conformation is necessary for recognition by, and binding to, their ligands, then the glycans may become cryptic. The ceramide with 8-carbon hydrocarbon tails was found to adopt a "surface-bound" configuration. In contrast, ceramide with 12-or 16-carbon tails was found to adopt "micelle-inserted" configuration. The effect of lipid environment was found to be the least on the oligosaccharide linked to the ceramide with hexadecyl tails. Thus, the headgroup conformation in this case is essentially the same as that of the free headgroup. This probably explains the lesser crypticity of glycolipids with longer hydrocarbon tails.

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