Structural and Functional Characterization of the Integral Membrane Protein VDAC-1 in Lipid Bilayer Nanodiscs

Raschle, Thomas; Hiller, Sebastian; Yu, Tsyr‐Yan; Rice, Amanda J.; Walz, Thomas; Wagner, Gerhard

doi:10.1021/ja907918r

Cited by 164 publications

(141 citation statements)

References 36 publications

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“…Application of solution NMR methods to study the structure of membrane proteins reconstituted into phosphoplipid vesicles is hindered by the very large size of the vesicles, which effectively ranges from tens of megadaltons to gigadaltons depending on their radii and leads to broadening beyond detection of resonances from structured parts of the proteins. This problem can be alleviated by incorporation of membrane proteins into nanodiscs (30)(31)(32), which leads to effective molecular weights in the 150-400 kDa range but still requires protein perdeuteration to obtain high-quality NMR data for structured regions. In the current study, we made no attempt to observe resonances from structured regions of reconstituted synaptobrevin and focused on determining which regions of its sequence remain flexible upon anchoring to a phospholipid bilayer.…”

Section: Resultsmentioning

confidence: 99%

“…Conversely, our data show that synaptobrevin behaves very similarly on nanodiscs and on phospholipid vesicles, confirming the notion that nanodiscs provide a faithful membrane model. Although our NMR experiments of synaptobrevin in nanodiscs focused on analyzing flexible regions, recent studies have shown that good-quality NMR data can also be obtained for structured regions of membrane proteins inserted into nanodiscs (30)(31)(32). Hence, the nanodisc approach provides a promising avenue for structural studies of membrane proteins in their actual bilayer environment.…”

Section: Soluble Synaptobrevin Snare Motif Binds To Dpc Micelles But mentioning

confidence: 99%

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Reluctance to membrane binding enables accessibility of the synaptobrevin SNARE motif for SNARE complex formation

Brewer

Horne

et al. 2011

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

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SNARE proteins play a critical role in intracellular membrane fusion by forming tight complexes that bring two membranes together and involve sequences called SNARE motifs. These motifs have a high tendency to form amphipathic coiled-coils that assemble into four-helix bundles, and often precede transmembrane regions. NMR studies in dodecylphosphocholine (DPC) micelles suggested that the N-terminal half of the SNARE motif from the neuronal SNARE synaptobrevin binds to membranes, which appeared to contradict previous biophysical studies of synaptobrevin in liposomes. NMR analyses of synaptobrevin reconstituted into nanodiscs and into liposomes now show that most of its SNARE motif, except for the basic C terminus, is highly flexible, exhibiting crosspeak patterns and transverse relaxation rates that are very similar to those observed in solution. Considering the proximity to the bilayer imposed by membrane anchoring, our data show that most of the synaptobrevin SNARE motif has a remarkable reluctance to bind membranes. This conclusion is further supported by NMR experiments showing that the soluble synaptobrevin SNARE motif does not bind to liposomes, even though it does bind to DPC micelles. These results show that nanodiscs provide a much better membrane model than DPC micelles in this system, and that most of the SNARE motif of membrane-anchored synaptobrevin is accessible for SNARE complex formation. We propose that the charge and hydrophobicity of SNARE motifs is optimized to enable formation of highly stable SNARE complexes while at the same time avoiding membrane binding, which could hinder SNARE complex assembly.neurotransmitter release | membrane proteins | membrane traffic T raffic at most eukaryotic membrane compartments is governed by members of conserved protein families that underlie a universal mechanism of intracellular membrane fusion (1). Particularly important among these proteins are the members of the SNARE family, which are characterized by sequences of about 60-70 amino acid residues that are known as SNARE motifs and often precede C-terminal transmembrane (TM) regions (2-5). Through these motifs, SNAREs from two apposed membranes form a tight four-helix bundle called the SNARE complex (6, 7), which brings the two membranes together and was proposed to provide the energy for membrane fusion (8). Although the exact fusion mechanism is still unclear (9), and fusion depends critically on other universal factors such as Sec1/Munc18 proteins (10-12) and sometimes on specialized proteins such as synaptotagmin-1 in the case of synaptic vesicle exocytosis (13-15), there is little doubt that the SNAREs play a central role in membrane fusion.Crystal structures of the SNARE four-helix bundle that represents the postfusion state have been determined without or with the adjacent TM regions (e.g., refs. 7 and 16), but detailed structural information on the isolated SNARE motifs attached to their adjacent TM regions is more limited. Early studies of synaptobrevin, syntaxin-1, and SNAP-25, the SNAREs that ...

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Section: Resultsmentioning

confidence: 99%

Section: Soluble Synaptobrevin Snare Motif Binds To Dpc Micelles But mentioning

confidence: 99%

Reluctance to membrane binding enables accessibility of the synaptobrevin SNARE motif for SNARE complex formation

Brewer

Horne

et al. 2011

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

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“…Because the N-terminal segment of VDAC is involved in voltage gating, it may adopt different conformations depending on the factors external to the protein (Ujwal et al, 2008). Using electron microscopy and NMR studies with a nanodisc technology, it has been demonstrated that the presence of phospholipid membrane facilitates this targeting to or interaction with different proteins (Raschle et al, 2009). Because VDAC1 knockout mice are viable (Anflous et al, 2001), it is likely that additional mechanisms promote cholesterol transport, possibly through the interaction of the -1 receptor associated with VDAC2 at the MAM region.…”

Section: Discussionmentioning

confidence: 99%

σ-1 Receptor at the Mitochondrial-Associated Endoplasmic Reticulum Membrane Is Responsible for Mitochondrial Metabolic Regulation

Marriott

Prasad

Thapliyal

et al. 2012

J Pharmacol Exp Ther

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The mitochondria-associated endoplasmic reticulum (ER) membrane (MAM) is a small section of the outer mitochondrial membrane tethered to the ER by lipid and protein filaments. One such MAM protein is the -1 receptor, which contributes to multiple signaling pathways. We found that short interfering RNA-mediated knockdown of -1 reduced pregnenolone synthesis by 95% without affecting expression of the inner mitochondrial membrane resident enzyme, 3-␤-hydroxysteroid dehydrogenase 2. To explore the underlying mechanism of this effect, we generated a series of -receptor ligands: 5,6-dimethoxy-3-methyl-N-phenyl-N-(3-(piperidin-1-yl)propyl)benzofuran-2-carboxamide (KSCM-1), 3-methyl-N-phenyl-N-(3-(piperidin-1-yl)propyl)benzofuran-2-carboxamide (KSCM-5), and 6-methoxy-3-methyl-Nphenyl-N-(3-(piperidin-1-yl) propyl)benzofuran-2-carboxamide (KSCM-11) specifically bound to -1 in the nanomolar range, whereas KSCM-5 and KSCM-11 also bound to -2. Treatment of cells with the KSCM ligands led to decreased cell viability, with KSCM-5 having the most potent effect followed by KSCM-11. KSCM-1 increased -1 expression by 4-fold and progesterone synthesis, whereas the other compounds decreased progesterone synthesis. These differences probably are caused by ligand molecular structure. For example, KSCM-1 has two methoxy substituents at C-5 and C-6 of the benzofuran ring, whereas KSCM-11 has one at C-6. KSCM ligands or -1 knockdown did not alter the expression of ER resident enzymes that synthesize steroids. However, coimmunoprecipitation of the -1 receptor pulled down voltage-dependent anion channel 2 (VDAC2), whose expression was enhanced by KSCM-1. VDAC2 plays a key role in cholesterol transport into the mitochondria, suggesting that the -1 receptor at the MAM coordinates with steroidogenic acute regulatory protein for cholesterol trafficking into the mitochondria for metabolic regulation.

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“…A number of membrane proteins, including cytochrome P450 monooxygenase [35,44], bacteriorhodopsin [45], rhodopsin [46,47], β2-adrenergic receptor [48,49], and the human mitochondrial voltage-dependent anion channel (VDAC1) have been studied using nanodisc technology [50].…”

Section: Artificial Discs a Nanodiscsmentioning

confidence: 99%

Artificial membranes for membrane protein purification, functionality and structure studies

Parmar

Lousa

Muench

et al. 2016

Biochemical Society Transactions

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Membrane proteins represent one of the most important targets for pharmaceutical companies. Unfortunately, technical limitations have long been a major hindrance in our understanding of the function and structure of such proteins. Recent years have seen the refinement of classical approaches and the emergence of new technologies that have resulted in a significant step forward in the field of membrane protein research. This review summarises some of the current techniques used for studying membrane proteins, with overall advantages and drawbacks for each method. Micelles and classical detergent techniquesMembrane proteins account for~30% of both prokaryotic and eukaryotic proteins [1]. Integral proteins such as transporters or ion channels, as well as peripheral membrane proteins such as G-proteins, all perform essential tasks in signal transduction, cell metabolism and transport of small molecules [2][3][4]. Integral and peripheral membrane proteins are respectively embedded in or closely associated with the phospholipid bilayer of cell membranes. Therefore, their function often relies on their precise lipid environment [5,6]. For instance, cardiolipin, which constitutes about 20% of the inner mitochondrial membrane, is essential to the function of many mitochondrial transporters such as the ADP/ATP carriers, the enzymes of the respiratory chain, and bacterial proteins [7][8][9]. This is because cardiolipin offers polar and electrostatic interactions that increase protein stability[10]; similar interactions have been observed for other lipids [11,12]. Unfortunately, classical techniques to study membrane proteins involve the use of detergents that solubilise the protein but also destabilise its interaction with membrane lipids. In many cases, membrane proteins may be stable in only a few detergents, limiting the range of conditions that can be used for crystallization trials [13]. Consequently, much time is spent testing various detergents in different ratios and concentrations in the hope of finding conditions that will mimic the essential interactions of the protein with its natural lipidic environment -and this way stabilise the protein and preserve its functional state. These problems have hindered membrane protein research for many years: both biophysical characterisation and structure solution have suffered due to difficulties of extracting proteins from membranes and keeping them stable away from their native environment. The past few years have seen the emergence of new techniques aimed at providing a membrane-like natural environment. These novel techniques include liposomes, bicelles, discs, polymer and lipids based strategies.

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Structural and Functional Characterization of the Integral Membrane Protein VDAC-1 in Lipid Bilayer Nanodiscs

Cited by 164 publications

References 36 publications

Reluctance to membrane binding enables accessibility of the synaptobrevin SNARE motif for SNARE complex formation

Reluctance to membrane binding enables accessibility of the synaptobrevin SNARE motif for SNARE complex formation

σ-1 Receptor at the Mitochondrial-Associated Endoplasmic Reticulum Membrane Is Responsible for Mitochondrial Metabolic Regulation

Artificial membranes for membrane protein purification, functionality and structure studies

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