A Highly Tilted Membrane Configuration for the Prefusion State of Synaptobrevin

Blanchard, Andrew E.; Arcario, Mark J.; Schulten, Klaus; Tajkhorshid, Emad

doi:10.1016/j.bpj.2014.09.013

Cited by 34 publications

(64 citation statements)

References 43 publications

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“…Theoretical studies of SNARE-mediated fusion suggest tilting Risselada et al, 2011) or outward translocation (Lindau et al, 2012) of the TMDs during fusion. Molecular dynamics simulations suggest that the linker and TMD N terminus tilt in the lipid bilayer and that the C terminus is flexible with a pivot at residue G100 (Blanchard et al, 2014). Our results suggest that the fusion pore contains a constriction from residues 99 -105, which contains the putative G100 kink (Fig.…”

Section: Discussionmentioning

confidence: 67%

A Structural Role for the Synaptobrevin 2 Transmembrane Domain in Dense-Core Vesicle Fusion Pores

et al. 2015

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Ca 2ϩ-triggered release of neurotransmitters and hormones depends on soluble N-ethylmaleimide-sensitive factor attachment protein receptors (SNAREs) to drive the fusion of the vesicle and plasma membranes. The formation of the SNARE complex by the vesicle SNARE synaptobrevin 2 (syb2) and the two plasma membrane SNAREs syntaxin (syx) and SNAP-25 draws the two membranes together, but the events that follow membrane juxtaposition, and the ways that SNAREs remodel lipid membranes remain poorly understood. The SNAREs syx and syb2 have transmembrane domains (TMDs) that can exert force directly on the lipid bilayers. The TMD of syx influences fusion pore flux in a manner that suggests it lines the nascent fusion pore through the plasma membrane. The TMD of syb2 traverses the vesicle membrane and is the most likely partner to syx in completing a proteinaceous fusion pore through the vesicle membrane, but the role of this vesicle SNARE in fusion pores has yet to be tested. Here amperometry and conductance measurements were performed to probe the function of the syb2 TMD in fusion pores formed during catecholamine exocytosis in mouse chromaffin cells. Fusion pore flux was sensitive to the size and charge of TMD residues near the N terminus; fusion pore conductance was altered by substitutions at these sites. Unlike syx, the syb2 residues that influence fusion pore permeation fell along two ␣-helical faces of its TMD, rather than one. These results indicate a role for the syb2 TMD in nascent fusion pores, but in a very different structural arrangement from that of the syx TMD.

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Section: Discussionmentioning

confidence: 67%

A Structural Role for the Synaptobrevin 2 Transmembrane Domain in Dense-Core Vesicle Fusion Pores

et al. 2015

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“…3). This result, combined with the favorable enhanced lipid lateral diffusion and headgroup atomic distributions (Ohkubo et al, 2012), began a push in the field to apply this methodology to proteins which are known or are thought to have substantial membrane interaction (Baylon et al, 2013; Wu and Schulten, 2014; Arcario and Tajkhorshid, 2014; Blanchard et al, 2014; Vermaas and Tajkhorshid, 2014a; Rhéault et al, 2015). …”

Section: Development Trajectory Of the Hmmmmentioning

confidence: 99%

“…The HMMM model has been successfully applied to simulation studies of several membrane-associated protein systems(Ohkubo et al, 2012; Baylon et al, 2013; Vermaas and Tajkhorshid, 2014a; Blanchard et al, 2014; Arcario and Tajkhorshid, 2014; Wu and Schulten, 2014; Rhéault et al, 2015). We begin this review by describing the development trajectory of the HMMM model, followed by a set of its recent applications to a wide variety of membrane-associated phenomena including: phospholipid insertion into membrane (Vermaas and Tajkhorshid, 2014b), binding and insertion of peripheral proteins such as cytochrome P450 (Baylon et al, 2013), hemoglobin N (Rhéault et al, 2015), talin (Arcario and Tajkhorshid, 2014), synaptotagmin I (Wu and Schulten, 2014), and α -synuclein (Vermaas and Tajkhorshid, 2014a), and studies of pre-fusion configuration of synaptobrevin transmembrane helix in a lipid bilayer (Blanchard et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

“…We begin this review by describing the development trajectory of the HMMM model, followed by a set of its recent applications to a wide variety of membrane-associated phenomena including: phospholipid insertion into membrane (Vermaas and Tajkhorshid, 2014b), binding and insertion of peripheral proteins such as cytochrome P450 (Baylon et al, 2013), hemoglobin N (Rhéault et al, 2015), talin (Arcario and Tajkhorshid, 2014), synaptotagmin I (Wu and Schulten, 2014), and α -synuclein (Vermaas and Tajkhorshid, 2014a), and studies of pre-fusion configuration of synaptobrevin transmembrane helix in a lipid bilayer (Blanchard et al, 2014). We conclude with outlining the best practices for utilizing the HMMM model and an outlook on its future developments.…”

Section: Introductionmentioning

confidence: 99%

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Efficient Exploration of Membrane-Associated Phenomena at Atomic Resolution

et al. 2015

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Biological membranes constitute a critical component in all living cells. In addition to providing a conducive environment to a wide range of cellular processes, including transport and signaling, mounting evidence has established active participation of specific lipids in modulating membrane protein function through various mechanisms. Understanding lipid-protein interactions underlying these mechanisms at a sufficiently high resolution has proven extremely challenging, partly due to the semi-fluid nature of the membrane. In order to address this challenge computationally, multiple methods have been developed, including an alternative membrane representation termed HMMM (highly mobile membrane mimetic) in which lateral lipid diffusion has been significantly enhanced without compromising atomic details. The model allows for efficient sampling of lipid-protein interactions at atomic resolution, thereby significantly enhancing the effectiveness of molecular dynamics simulations in capturing membrane-associated phenomena. In this review, after providing an overview of HMMM model development, we will describe briefly successful application of the model to study a variety of membrane processes, including lipid-dependent binding and insertion of peripheral proteins, the mechanism of phospholipid insertion into lipid bilayers, and characterization of optimal tilt angle of transmembrane helices. We conclude with practical recommendations for proper usage of the model in simulation studies of membrane processes.

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“…State-of-the-art examples are studies of membrane binding and the formation of pores by antimicrobial and cell-penetrating peptides (Berglund et al, 2015;Huang and García, 2013;Moiset et al, 2013;Ulmschneider et al, 2012), of the specific binding of lipids to membrane proteins (Aponte-Santamaria et al, 2012;Contreras et al, 2012;Lee and Lyman, 2012;Pöyry et al, 2013), of the cyclodextrin-mediated extraction of cholesterol from membranes (López et al, 2013a), of the dynamic organization of multi-component membranes (Martinez-Seara et al, 2010;Sodt et al, 2014;Wu et al, 2014b), of lipid-peptide interplay in membrane fusion (Blanchard et al, 2014;Larsson and Kasson, 2013) and of the functioning of membrane proteins (Dror et al, 2011;Kopfer et al, 2014;Maffeo et al, 2012;Marinelli et al, 2014;Moradi et al, 2015;Ostmeyer et al, 2013;Romo et al, 2010).…”

Section: Atomic Resolutionmentioning

confidence: 99%

Computational ‘microscopy’ of cellular membranes

Ingólfsson

Arnarez²,

Periole³

et al. 2016

Journal of Cell Science

133

120

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Computational 'microscopy' refers to the use of computational resources to simulate the dynamics of a molecular system. Tuned to cell membranes, this computational 'microscopy' technique is able to capture the interplay between lipids and proteins at a spatiotemporal resolution that is unmatched by other methods. Recent advances allow us to zoom out from individual atoms and molecules to supramolecular complexes and subcellular compartments that contain tens of millions of particles, and to capture the complexity of the crowded environment of real cell membranes. This Commentary gives an overview of the main concepts of computational 'microscopy' and describes the state-of-the-art methods used to model cell membrane processes. We illustrate the power of computational modelling approaches by providing a few in-depth examples of largescale simulations that move up from molecular descriptions into the subcellular arena. We end with an outlook towards modelling a complete cell in silico.

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A Highly Tilted Membrane Configuration for the Prefusion State of Synaptobrevin

Cited by 34 publications

References 43 publications

A Structural Role for the Synaptobrevin 2 Transmembrane Domain in Dense-Core Vesicle Fusion Pores

A Structural Role for the Synaptobrevin 2 Transmembrane Domain in Dense-Core Vesicle Fusion Pores

Efficient Exploration of Membrane-Associated Phenomena at Atomic Resolution

Computational ‘microscopy’ of cellular membranes

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