Interaction of SNARE Mimetic Peptides with Lipid bilayers: Effects of Secondary Structure, Bilayer Composition and Lipid Anchoring

Wagle, Swapnil; Georgiev, Vasil N.; Robinson, Tom; Dimova, Rumiana; Lipowsky, Reinhard; Grafmüller, Andrea

doi:10.1038/s41598-019-43418-w

Cited by 10 publications

(9 citation statements)

References 78 publications

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“…The presence of such hysteresis was also observed for several wellreported pore-forming RCs 34 and even for other peptides with the same choice of RC (i.e., DIST-Z) as used in this investigation. 50,51 Similarly, in the present report, the trend obtained from the backward PMFs is in reasonable agreement with the trends from the forward PMFs, yet the limitations of this report regarding the suboptimal choice of RC cannot be ruled out. However, the concern of insufficient sampling around the transition states has been carefully noted and taken care of by inclusion of a second RC that provided a decent account of the relevant energy landscapes.…”

Section: ■ Discussionsupporting

confidence: 88%

“…It is worth mentioning that it is a fairly common concern for the suboptimal RCs; though the end-state populations can be efficiently distinguished along these RCs, the relevant transition states are often inadequately captured at an affordable computational cost due to the involvement of a slower degrees of freedom orthogonal to the chosen RC. The presence of such hysteresis was also observed for several well-reported pore-forming RCs and even for other peptides with the same choice of RC (i.e., DIST-Z) as used in this investigation. , Similarly, in the present report, the trend obtained from the backward PMFs is in reasonable agreement with the trends from the forward PMFs, yet the limitations of this report regarding the suboptimal choice of RC cannot be ruled out. However, the concern of insufficient sampling around the transition states has been carefully noted and taken care of by inclusion of a second RC that provided a decent account of the relevant energy landscapes.…”

Section: Discussionsupporting

confidence: 86%

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Shifting Polar Residues Across Primary Sequence Frames of Transmembrane Domains Calibrates Membrane Permeation Thermodynamics

Sinha

Dastidar

2020

Biochemistry

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Permeation of the mitochondrial outer membrane (MOM) using the transmembrane domains (TMDs) is the key step of the Bcl-2 family of proteins to control apoptosis. The primary sequences of the TMDs of the family members like Bcl-xL, Bcl-2, Bak, etc. indicate the presence of charged residues at the C-terminal tip to be essential for drilling the membrane. However, Bax, a variant of the same family, is an exception, as the charged residues are shifted away from the tip by two positional frames in the primary sequence, but does it matter really? The free energy landscapes of membrane permeation, computed from a total of ∼13.3 μs of conformational sampling, show how such shifting of the amino acid frames in the primary sequence is correlated with the energy landscape that ensures the balance between membrane permeation and cytosolic population. Shifting the charged residues back to the terminal, in suitable mutants of Bax, proves the necessity of terminal charged residues by improving the insertion free energy but adds a high energy barrier unless some other polar residues are adjusted further. The difference in the TMDs of Bcl-xL and Bax is also reflected in their mechanism to drill the MOM-like anionic membrane; only Bax-TMD requires surface crowding to favorably shape the permeation landscape by weakening the bilayer integrity. So, this investigation suggests that such proteins can calibrate the free energy landscape of membrane permeation by adjusting the positions of the charged or polar residues in the primary sequence frames, a strategy analogous to the game of the “sliding tile puzzle” but played with primary sequence frames.

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Section: ■ Discussionsupporting

confidence: 88%

Section: Discussionsupporting

confidence: 86%

Shifting Polar Residues Across Primary Sequence Frames of Transmembrane Domains Calibrates Membrane Permeation Thermodynamics

Sinha

Dastidar

2020

Biochemistry

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“…The pre‐synaptic plasma membrane is also characterized by ‘islands’ of high and low fluidity (i.e. lipid rafts (Sonnino et al, ; Sonnino and Prinetti, )) and lipid membrane anchors (Wagle et al, ), likely reflecting lipid involvement in the nanoscale protein organization required for neuroexocytosis (Figure b). In agreement, a recent study demonstrated that the size of the fatty acyl side chain of specific phosphatidylserine molecules controls the protein cluster organization of the outer hemi‐membrane (Raghupathy et al, ).…”

Section: Fusogenic Lipids and Membrane Topologymentioning

confidence: 99%

Phospholipases in neuronal function: A role in learning and memory?

Joensuu

Wallis

Saber

et al. 2020

Journal of Neurochemistry

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| LIPIDS AND THE B R AINUnderstanding how the over 80 billion neurons in the human brain communicate with each other to generate a self-aware mind remains one of the great challenges of modern neurobiology. Despite decades of ever more sophisticated study and progress, the molecular mechanisms underpinning the exquisitely regulated neuronal communication at the heart of cognition, learning and memory remain incompletely understood. The discovery that neurotransmission is quantal (Del Castillo and Katz, 1954) led to the development of the vesicle hypothesis in which neurotransmitters are released following fusion of synaptic vesicles with the pre-synaptic membrane in a process known as neuroexocytosis. Decades of subsequent research validated this fundamental finding, and demonstrated the involvement of sophisticated protein machinery (e.g. SNAREs, N-ethylmaleimide-sensitive factor attachment receptors) in all aspects of vesicle trafficking. Most recently, the analysis of brain lipids and lipid metabolites has started to shift this somewhat 'proteocentric' view of neurotransmission to a more holistic view involving tightly regulated protein-protein, protein-lipid (Wenk and De Camilli, 2004) and lipid-lipid interactions, all of which are essential for neuronal communication.Indeed, the healthy human brain is composed of approximately 60% lipid by dry weight, higher than in any other tissue. Seminal chromatography experiments (O'Brien and Sampson, 1965) AbstractDespite the human brain being made of nearly 60% fat, the vast majority of studies on the mechanisms of neuronal communication which underpin cognition, memory and learning, primarily focus on proteins and/or (epi)genetic mechanisms. Phospholipids are the main component of all cellular membranes and function as substrates for numerous phospholipid-modifying enzymes, including phospholipases, which release free fatty acids (FFAs) and other lipid metabolites that can alter the intrinsic properties of the membranes, recruit and activate critical proteins, and act as lipid signalling molecules. Here, we will review brain specific phospholipases, their roles in membrane remodelling, neuronal function, learning and memory, as well as their disease implications. In particular, we will highlight key roles of unsaturated FFAs, particularly arachidonic acid, in neurotransmitter release, neuroinflammation and memory.In light of recent findings, we will also discuss the emerging role of phospholipase A 1 and the creation of saturated FFAs in the brain. K E Y W O R D S exocytosis, free fatty acids, learning, memory, phospholipases, phospholipids, synaptic plasticity | 301 JOENSUU Et al.

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“…We had anticipated that it would be necessary to use palmitoylated SNAP25 in this experiment, but instead observed that even nonpalmitoylated SNAP25, added at low (150 n m ) concentrations in solution, bound to the bilayer. This is likely due to the amphipathic nature of two SNARE motifs of SNAP25 [7] as it is well established that amphipathic peptides associate strongly with phospholipid surfaces as their hydrophobic side chains could insert into the lipid bilayers [58,59]. On its own, freely diffusing Alexa Fluor 555‐labeled SNAP25 molecules thus bound were monomeric and uniformly distributed on the lipid bilayer surface (Fig.…”

Section: Resultsmentioning

confidence: 98%

Munc13 binds and recruits SNAP25 to chaperone SNARE complex assembly

Sundaram

Jin

et al. 2020

FEBS Letters

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Synaptic vesicle fusion is mediated by SNARE proteins—VAMP2 on the vesicle and Syntaxin‐1/SNAP25 on the presynaptic membrane. Chaperones Munc18‐1 and Munc13‐1 cooperatively catalyze SNARE assembly via an intermediate ‘template’ complex containing Syntaxin‐1 and VAMP2. How SNAP25 enters this reaction remains a mystery. Here, we report that Munc13‐1 recruits SNAP25 to initiate the ternary SNARE complex assembly by direct binding, as judged by bulk FRET spectroscopy and single‐molecule optical tweezer studies. Detailed structure–function analyses show that the binding is mediated by the Munc13‐1 MUN domain and is specific for the SNAP25 ‘linker’ region that connects the two SNARE motifs. Consequently, freely diffusing SNAP25 molecules on phospholipid bilayers are concentrated and bound in ~ 1 : 1 stoichiometry by the self‐assembled Munc13‐1 nanoclusters.

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Interaction of SNARE Mimetic Peptides with Lipid bilayers: Effects of Secondary Structure, Bilayer Composition and Lipid Anchoring

Cited by 10 publications

References 78 publications

Shifting Polar Residues Across Primary Sequence Frames of Transmembrane Domains Calibrates Membrane Permeation Thermodynamics

Shifting Polar Residues Across Primary Sequence Frames of Transmembrane Domains Calibrates Membrane Permeation Thermodynamics

Phospholipases in neuronal function: A role in learning and memory?

Munc13 binds and recruits SNAP25 to chaperone SNARE complex assembly

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