Efficient Exploration of Membrane-Associated Phenomena at Atomic Resolution

Vermaas, Josh V.; Baylon, Javier L.; Arcario, Mark J.; Müller, Mélanie; Wu, Zhe; Pogorelov, Taras V.; Tajkhorshid, Emad

doi:10.1007/s00232-015-9806-9

Cited by 36 publications

(55 citation statements)

References 155 publications

(272 reference statements)

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“…The particle count can be reduced even further by removing the explicit membrane atoms altogether, replacing them with an implicit membrane model in which the effect of the membrane is applied as a continuum with varying dielectric [69], again enabling longer simulations. Membrane representations that increase the diffusion constant of the lipids [70] by making them shorter and adding an organic solvent to fill the void have also been developed [71], which accelerates the kinetics of insertion processes [72] while preserving the energetics and specificity of a conventional membrane representation at the membrane periphery [73]. While each of these methods has their advantages, they make sacrifices in the accuracy of the molecular interactions; hence, the gold standard for MD simulation remains at the fully atomic scale.…”

Section: Membrane Activity Is a Critical Factor In The Biology Of Smamentioning

confidence: 99%

“…Embedding proteins into such complex membranes further exacerbates the sampling problem due to increased viscosity, yielding protein structures that exhibit dynamics very different from their solution form. These scenarios may be alleviated by alternative methods that enhance sampling, e.g., reduced representations of the membrane as done in the HMMM model [70, 71], coarse-grained membrane models [67], or implicit membrane models for protein complex formation [225–227], and will likely be required in future studies.…”

Section: Conclusion and Future Perspectivesmentioning

confidence: 99%

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The cellular membrane as a mediator for small molecule interaction with membrane proteins

Mayne

Arcario

Mahinthichaichan

et al. 2016

Biochimica et Biophysica Acta (BBA) - Biomembranes

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The cellular membrane constitutes the first element that encounters a wide variety of molecular species to which a cell might be exposed. Hosting a large number of structurally and functionally diverse proteins associated with this key metabolic compartment, the membrane not only directly controls the traffic of various molecules in and out of the cell, it also participates in such diverse and important processes as signal transduction and chemical processing of incoming molecular species. In this article, we present a number of cases where details of interaction of small molecular species such as drugs with the membrane, which are often experimentally inaccessible, have been studied using advanced molecular simulation techniques. We have selected systems in which partitioning of the small molecule with the membrane constitutes a key step for its final biological function, often binding to and interacting with a protein associated with the membrane. These examples demonstrate that membrane partitioning is not only important for the overall distribution of drugs and other small molecules into different compartments of the body, it may also play a key role in determining the efficiency and the mode of interaction of the drug with its target protein.

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Section: Membrane Activity Is a Critical Factor In The Biology Of Smamentioning

confidence: 99%

Section: Conclusion and Future Perspectivesmentioning

confidence: 99%

The cellular membrane as a mediator for small molecule interaction with membrane proteins

Mayne

Arcario

Mahinthichaichan

et al. 2016

Biochimica et Biophysica Acta (BBA) - Biomembranes

Self Cite

View full text Add to dashboard Cite

show abstract

“…1) [73, 74]. The short-tailed, yet fully atomistic lipids, placed at the organic solvent/water interface to capture the chemistry inherent in protein-lipid interactions, have a self-diffusion constant that is at least an order of magnitude higher than conventional lipids [45, 74]. As a result, insertion processes on the membrane interface will be significantly accelerated [75] while accurately reproducing the energetics of molecular interactions at the interface [76].…”

Section: Complementing Experiments With Simulation At the Membrane mentioning

confidence: 99%

Atomic-level description of protein–lipid interactions using an accelerated membrane model

Baylon

Vermaas

Müller

et al. 2016

Biochimica et Biophysica Acta (BBA) - Biomembranes

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Peripheral membrane proteins are structurally diverse proteins that are involved in fundamental cellular processes. Their activity of these proteins is frequently modulated through their interaction with cellular membranes, and as a result techniques to study the interfacial interaction between peripheral proteins and the membrane are in high demand. Due to the fluid nature of the membrane and the reversibility of protein–membrane interactions, the experimental study of these systems remains a challenging task. Molecular dynamics simulations offer a suitable approach to study protein–lipid interactions; however, the slow dynamics of the lipids often prevents sufficient sampling of specific membrane–protein interactions in atomistic simulations. To increase lipid dynamics while preserving the atomistic detail of protein–lipid interactions, in the highly mobile membrane-mimetic (HMMM) model the membrane core is replaced by an organic solvent, while short-tailed lipids provide a nearly complete representation of natural lipids at the organic solvent/water interface. Here, we present a brief introduction and a summary of recent applications of the HMMM to study different membrane proteins, complementing the experimental characterization of the presented systems, and we offer a perspective of future applications of the HMMM to study other classes of membrane proteins.

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“…Recently, Tajkhorshid and coworkers developed the highly mobile membrane-mimetic (HMMM) model with accelerated lipid motion by replacing the lipid tails with small organic molecules [187]. The HMMM model provides accelerated lipid diffusion by 1-2 orders of magnitude, and is particularly useful in studying membrane-protein associations [188, 189]. …”

Section: Modeling Cell Membranes and Membrane Proteinsmentioning

confidence: 99%

Challenges in structural approaches to cell modeling

Liang

Olson

et al. 2016

Journal of Molecular Biology

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Computational modeling is essential for structural characterization of biomolecular mechanisms across the broad spectrum of scales. Adequate understanding of biomolecular mechanisms inherently involves our ability to model them. Structural modeling of individual biomolecules and their interactions has been rapidly progressing. However, in terms of the broader picture, the focus is shifting toward larger systems, up to the level of a cell. Such modeling involves a more dynamic and realistic representation of the interactomes in vivo, in a crowded cellular environment, as well as membranes and membrane proteins, and other cellular components. Structural modeling of a cell complements computational approaches to cellular mechanisms based on differential equations, graph models, and other techniques to model biological networks, imaging data, etc. Structural modeling along with other computational and experimental approaches will provide a fundamental understanding of life at the molecular level and lead to important applications to biology and medicine. A cross section of diverse approaches presented in this review illustrates the developing shift from the structural modeling of individual molecules to that of cell biology. Studies in several related areas are covered: biological networks; automated construction of three-dimensional cell models using experimental data; modeling of protein complexes; prediction of non-specific and transient protein interactions; thermodynamic and kinetic effects of crowding; cellular membrane modeling; and modeling of chromosomes. The review presents an expert opinion on the current state-of-the-art in these various aspects of structural modeling in cellular biology, and the prospects of future developments in this emerging field.

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Efficient Exploration of Membrane-Associated Phenomena at Atomic Resolution

Cited by 36 publications

References 155 publications

The cellular membrane as a mediator for small molecule interaction with membrane proteins

The cellular membrane as a mediator for small molecule interaction with membrane proteins

Atomic-level description of protein–lipid interactions using an accelerated membrane model

Challenges in structural approaches to cell modeling

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