Curvature Forces in Membrane Lipid–Protein Interactions

Brown, Michael F.

doi:10.1021/bi301332v

Cited by 160 publications

(156 citation statements)

References 187 publications

(764 reference statements)

Supporting

Mentioning

153

Contrasting

Order By: Relevance

“…A possible mechanism is centered on change in membrane physical properties (such as viscosity, thickness and curvature) that would give rise to altered protein function (Brown, 2012;daCosta et al, 2013;Soubias et al, 2014). …”

Section: Resultsmentioning

confidence: 99%

Molecular rheology of neuronal membranes explored using a molecular rotor: Implications for receptor function

Pal

Chakraborty

Bandari

et al. 2016

Chemistry and Physics of Lipids

View full text Add to dashboard Cite

The role of membrane cholesterol as a crucial regulator in the structure and function of membrane proteins and receptors is well documented. However, there is a lack of consensus on the mechanism for such regulation. We have previously shown that the function of an important neuronal receptor, the serotonin1A receptor, is modulated by cholesterol in hippocampal membranes. With an overall objective of addressing the role of 3 membrane physical properties in receptor function, we measured the viscosity of hippocampal membranes of varying cholesterol content using a meso-substituted fluorophore (BODIPY-C12) based on the BODIPY probe. BODIPY-C12 acts as a fluorescent molecular rotor and allows measurement of hippocampal membrane viscosity through its characteristic viscosity-sensitive fluorescence depolarization. A striking feature of our results is that specific agonist binding by the serotonin1A receptor exhibits close correlation with hippocampal membrane viscosity, implying the importance of global membrane properties in receptor function. We envision that our results are important in understanding GPCR regulation by the membrane environment, and is relevant in the context of diseases in which GPCR signaling plays a major role and are characterized by altered membrane fluidity.Abbreviations: 2-AS, 2-(9-anthroyloxy)stearic acid; 12-AS, 12-(9-anthroyloxy)stearic acid; BODIPY, 4,4-difluoro-4-bora-3a,4a-diaza-s-indacene; GPCR, G protein-coupled receptor; 8-12-PC, 1-palmitoyl-2-(12-doxyl)stearoyl-sn-glycero-3-phosphocholine; DMPC, 1,2-dimyristoyl-sn-glycero-3-phosphocholine; DOPC, 1,2-dioleoylsn-glycero-3-phosphocholine; MβCD, methyl-β-cyclodextrin; Tempo-PC, 1,2-dioleoyl-snglycero-3-phosphotempocholine Keywords: Molecular rotor; hippocampal membrane; viscosity; cholesterol; neuronal receptor IntroductionBiological membranes are complex, highly organized, two-dimensional, supramolecular assemblies of a diverse variety of lipids and proteins. The function of membranes is to allow cellular compartmentalization, and impart an identity to individual cells and organelles, besides providing an appropriate environment for proper functioning of membrane proteins. Interestingly, cellular membranes in the nervous system are characterized by very high concentration and remarkable diversity of lipids, and these are correlated with increased complexity in the function of the nervous system (Sastry, 1985;Wenk, 2005). In this context, cholesterol represents an important lipid since brain cholesterol has been implicated in a number of neurological disorders (Chattopadhyay and Paila, 2007;Martín et al., 2014), some of which share a common etiology of defective cholesterol 4 metabolism in the brain (Porter and Herman, 2011). More importantly, the function of neuronal receptors depends on cholesterol (Pucadyil and Chattopadhyay, 2006;Allen et al., 2007;Paila and Chattopadhyay, 2010;Jafurulla and Chattopadhyay, 2013), which affects neurotransmission, resulting in mood and anxiety disorders (Papakostas et al., 2004). In spite of ...

show abstract

Section: Resultsmentioning

confidence: 99%

Molecular rheology of neuronal membranes explored using a molecular rotor: Implications for receptor function

Pal

Chakraborty

Bandari

et al. 2016

Chemistry and Physics of Lipids

View full text Add to dashboard Cite

show abstract

“…Indeed, protein membrane interaction 39 and membrane curvature sensing have received much attention. 3,26,45 So far, both theoretical modeling and numerical simulation in the field have been mostly phenomenological and qualitative, 9 partially due to the lack of more quantitative experimental data. Another class of models directly utilizes continuum elasticity for biomolecular flexibility analysis.…”

Section: Introductionmentioning

confidence: 99%

“…These methods combine elastic mechanics and molecular mechanics to significantly reduce the number of degrees of freedom of large biomolecular systems. 9 For example, the classical theory of elasticity for DNA loops is combined with the MD description of protein for protein-DNA interaction complexes. 60 Recently, the continuum elastic modeling of the Canham-Helfrich type of energy functional has been coupled with MD simulations to investigate the complex elastic behavior of Hepatitis B virus capsids.…”

Section: Introductionmentioning

confidence: 99%

Multiscale multiphysics and multidomain models—Flexibility and rigidity

Xia

Opron

Guo

2013

The Journal of Chemical Physics

221

View full text Add to dashboard Cite

The emerging complexity of large macromolecules has led to challenges in their full scale theoretical description and computer simulation. Multiscale multiphysics and multidomain models have been introduced to reduce the number of degrees of freedom while maintaining modeling accuracy and achieving computational efficiency. A total energy functional is constructed to put energies for polar and nonpolar solvation, chemical potential, fluid flow, molecular mechanics, and elastic dynamics on an equal footing. The variational principle is utilized to derive coupled governing equations for the above mentioned multiphysical descriptions. Among these governing equations is the PoissonBoltzmann equation which describes continuum electrostatics with atomic charges. The present work introduces the theory of continuum elasticity with atomic rigidity (CEWAR). The essence of CE-WAR is to formulate the shear modulus as a continuous function of atomic rigidity. As a result, the dynamics complexity of a macromolecular system is separated from its static complexity so that the more time-consuming dynamics is handled with continuum elasticity theory, while the less time-consuming static analysis is pursued with atomic approaches. We propose a simple method, flexibility-rigidity index (FRI), to analyze macromolecular flexibility and rigidity in atomic detail. The construction of FRI relies on the fundamental assumption that protein functions, such as flexibility, rigidity, and energy, are entirely determined by the structure of the protein and its environment, although the structure is in turn determined by all the interactions. As such, the FRI measures the topological connectivity of protein atoms or residues and characterizes the geometric compactness of the protein structure. As a consequence, the FRI does not resort to the interaction Hamiltonian and bypasses matrix diagonalization, which underpins most other flexibility analysis methods. FRI's computational complexity is of O(N 2 ) at most, where N is the number of atoms or residues, in contrast to O(N 3 ) for Hamiltonian based methods. We demonstrate that the proposed FRI gives rise to accurate prediction of protein B-Factor for a set of 263 proteins. We show that a parameter free FRI is able to achieve about 95% accuracy of the parameter optimized FRI. An interpolation algorithm is developed to construct continuous atomic flexibility functions for visualization and use with CEWAR.

show abstract

“…1 It is the essential component for maintaining the barrier function of the membrane and plays a crucial role in the lateral organization of the membrane lipids, the dynamic domain structure and the elasticity of the membrane that is required for membrane protein function. [2][3][4] These and other important membrane properties come about by specific interactions between cholesterol and other lipids or proteins in the membrane. 5,6 So far, little has been understood about these specific interactions, and exact interaction energies that would allow understanding the lateral organization of lipids and proteins in the membrane have only been estimated.…”

Section: Introductionmentioning

confidence: 99%

Influence of the sterol aliphatic side chain on membrane properties: a molecular dynamics study

Robalo

Ramalho

Huster

et al. 2015

Phys. Chem. Chem. Phys.

View full text Add to dashboard Cite

Following a recent experimental investigation of the effect of the length of the alkyl side chain in a series of cholesterol analogues (Angew. Chem., Int. Ed., 2013, 52, 12848-12851), we report here an atomistic molecular dynamics characterization of the behaviour of methyl-branched side chain sterols (iso series) in POPC bilayers. The studied sterols included androstenol (i-C0-sterol) and cholesterol (i-C8-sterol), as well as four other derivatives (i-C5, i-C10, i-C12 and i-C14-sterol). For each sterol, both subtle local effects and more substantial differential alterations of membrane properties along the iso series were investigated. The location and orientation of the tetracyclic ring system is almost identical in all compounds. Among all the studied sterols, cholesterol is the sterol that presents the best matching with the hydrophobic length of POPC acyl chains, whereas longer-chained sterols interdigitate into the opposing membrane leaflet. In accordance with the experimental observations, a maximal ordering effect is observed for intermediate sterol chain length (i-C5, cholesterol, i-C10). Only for these sterols a preferential interaction with the saturated sn-1 chain of POPC (compared to the unsaturated sn-2 chain) was observed, but not for either shorter or longer-chained derivatives. This work highlights the importance of the sterol alkyl chain in the modulation of membrane properties and lateral organization in biological membranes.

show abstract

Curvature Forces in Membrane Lipid–Protein Interactions

Cited by 160 publications

References 187 publications

Molecular rheology of neuronal membranes explored using a molecular rotor: Implications for receptor function

Molecular rheology of neuronal membranes explored using a molecular rotor: Implications for receptor function

Multiscale multiphysics and multidomain models—Flexibility and rigidity

Influence of the sterol aliphatic side chain on membrane properties: a molecular dynamics study

Contact Info

Product

Resources

About