The epidermal growth factor receptor (EGFR) regulates several critical cellular processes and is an important target for cancer therapy. In lieu of a crystallographic structure of the complete receptor, atomistic molecular dynamics (MD) simulations have recently shown that they can excel in studies of the full-length receptor. Here we present atomistic MD simulations of the monomeric N-glycosylated human EGFR in biomimetic lipid bilayers that are, in parallel, also used for the reconstitution of full-length receptors. This combination enabled us to experimentally validate our simulations, using ligand binding assays and antibodies to monitor the conformational properties of the receptor reconstituted into membranes. We find that N-glycosylation is a critical determinant of EGFR conformation, and specifically the orientation of the EGFR ectodomain relative to the membrane. In the absence of a structure for full-length, posttranslationally modified membrane receptors, our approach offers new means to structurally define and experimentally validate functional properties of cell surface receptors in biomimetic membrane environments.R eceptor tyrosine kinases (RTKs) are cell surface receptors that receive and transduce signals mediating a variety of critical cellular processes, including cell growth, migration, proliferation, differentiation, and apoptosis. Among the many RTKs, the most studied is the epidermal growth factor receptor (EGFR), not least because of its involvement in the development and progression of epidermoid cancers and its resulting importance as a target for antineoplastic therapies.Structurally, the EGFR consists of the ectodomain (ECD) (further subdivided into four subdomains, DI-IV), the transmembrane domain (TMD), and the intracellular tyrosine kinase domain (TKD). Ligand binding induces conformational transitions of the ECD that stabilize receptor dimerization, culminating in the activation of the intracellular TKD and subsequent propagation of the activation signal (1). To prevent receptor activation and signaling in the absence of ligand, the structurally tethered ECD of monomeric EGFR blocks the intrinsic capacity of the TMD and the intracellular TKD to dimerize (2). Ligand binding is believed to release the self-inhibitory tether and facilitate receptor oligomerization and activation (3-6). A detailed understanding of the structural regulation of the intact full-length receptors in their native membranes promises to reveal the molecular basis for receptor regulation (7); however, the methodological limitations associated with crystallizing transmembrane proteins, together with the high flexibility of the full-length receptor, have prevented high-resolution crystallographic analysis.To fill this gap, extensive atom-scale molecular dynamics (MD) simulations were recently performed to elucidate the structural dynamics of the EGFR in a two-component lipid bilayer (8). These studies suggest a large interfacial contact area between the membrane and the ecto-and intracellular domains of the unli...
We have combined Langmuir monolayer film experiments and all-atom molecular dynamics (MD) simulation of a bilayer to study the surface structure of a PEGylated liposome and its interaction with the ionic environment present under physiological conditions. Lipids that form both gel and liquid-crystalline membranes have been used in our study. By varying the salt concentration in the Langmuir film experiment and including salt at the physiological level in the simulation, we have studied the effect of salt ions present in the blood plasma on the structure of the poly(ethylene glycol) (PEG) layer. We have also studied the interaction between the PEG layer and the lipid bilayer in both the liquid-crystalline and gel states. The MD simulation shows two clear results: (a) The Na(+) ions form close interactions with the PEG oxygens, with the PEG chains forming loops around them and (b) PEG penetrates the lipid core of the membrane for the case of a liquid-crystalline membrane but is excluded from the tighter structure of the gel membrane. The Langmuir monolayer results indicate that the salt concentration affects the PEGylated lipid system, and these results can be interpreted in a fashion that is in agreement with the results of our MD simulation. We conclude that the currently accepted picture of the PEG surface layer acting as a generic neutral hydrophilic polymer entirely outside the membrane, with its effect explained through steric interactions, is not sufficient. The phenomena we have observed may affect both the interaction between the liposome and bloodstream proteins and the liquid-crystalline-gel transition and is thus relevant to nanotechnological drug delivery device design.
Carbohydrates constitute a structurally and functionally diverse group of biological molecules and macromolecules. In cells they are involved in, e.g., energy storage, signaling, and cell–cell recognition. All of these phenomena take place in atomistic scales, thus atomistic simulation would be the method of choice to explore how carbohydrates function. However, the progress in the field is limited by the lack of appropriate tools for preparing carbohydrate structures and related topology files for the simulation models. Here we present tools that fill this gap. Applications where the tools discussed in this paper are particularly useful include, among others, the preparation of structures for glycolipids, nanocellulose, and glycans linked to glycoproteins. The molecular structures and simulation files generated by the tools are compatible with GROMACS.
Proteins embedded in the plasma membrane mediate interactions with the cell environment and play decisive roles in many signaling events. For cell–cell recognition molecules, it is highly likely that their structures and behavior have been optimized in ways that overcome the limitations of membrane tethering. In particular, the ligand binding regions of these proteins likely need to be maximally exposed. Here we show by means of atomistic simulations of membrane-bound CD2, a small cell adhesion receptor expressed by human T-cells and natural killer cells, that the presentation of its ectodomain is highly dependent on membrane lipids and receptor glycosylation acting in apparent unison. Detailed analysis shows that the underlying mechanism is based on electrostatic interactions complemented by steric interactions between glycans in the protein and the membrane surface. The findings are significant for understanding the factors that render membrane receptors accessible for binding and signaling.
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