Cations induce shape remodeling of negatively charged phospholipid membranes

Graber, Zachary T.; Shi, Zheng; Baumgart, Tobias

doi:10.1039/c7cp00718c

Cited by 86 publications

(92 citation statements)

References 68 publications

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“…These invaginations continued to increase in size over time upon injection of calcium ions filling the interior of the bulge, Figure A‐2–A‐7. Both membrane invaginations and tubular protrusions were previously reported in GUVs exposed to external stimuli, such as polymers, calcium ions, pH gradient, osmotic stress, proteins, and polypeptides . The observed invaginations presented herein, are reminiscent to those reported in our previous work on the tubulation within GUVs upon binding of calcium ions .…”

supporting

confidence: 87%

Contactless Stimulation and Control of Biomimetic Nanotubes by Calcium Ion Gradients

Kirejev

Doosti

Shaali

et al. 2018

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Membrane tubular structures are important communication pathways between cells and cellular compartments. Studying these structures in their native environment is challenging, due to the complexity of membranes and varying chemical conditions within and outside of the cells. This work demonstrates that a calcium ion gradient, applied to a synthetic lipid nanotube, triggers lipid flow directed toward the application site, resulting in the formation of a bulge aggregate. This bulge can be translated in a contactless manner by moving a calcium ion source along the lipid nanotube. Furthermore, entrapment of polystyrene nanobeads within the bulge does not tamper the bulge movement and allows transporting of the nanoparticle cargo along the lipid nanotube. In addition to the synthetic lipid nanotubes, the response of cell plasma membrane tethers to local calcium ion stimulation is investigated. The directed membrane transport in these tethers is observed, but with slower kinetics in comparison to the synthetic lipid nanotubes. The findings of this work demonstrate a novel and contactless mode of transport in lipid nanotubes, guided by local exposure to calcium ions. The observed lipid nanotube behavior can advance the current understanding of the cell membrane tubular structures, which are constantly reshaped during dynamic cellular processes.

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supporting

confidence: 87%

Contactless Stimulation and Control of Biomimetic Nanotubes by Calcium Ion Gradients

Kirejev

Doosti

Shaali

et al. 2018

Small

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“…73) and the A2A GPCR (74)). Calcium is known to bind to some small GTPases (75) but also causes a clustering of PIP2 (76,77).…”

Section: K-ras Binding To Pip2mentioning

confidence: 99%

K-Ras G-domain binding with signaling lipid phosphatidylinositol (4,5)-phosphate (PIP2): membrane association, protein orientation, and function

Cao

Chung

Kim

et al. 2019

Journal of Biological Chemistry

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Edited by Henrik G. DohlmanRas genes potently drive human cancers, with mutated protooncogene GTPase KRAS4B (K-Ras4B) being the most abundant isoform. Targeted inhibition of oncogenic gene products is considered the "holy grail" of present-day cancer therapy, and recent discoveries of small-molecule KRas4B inhibitors were made thanks to a deeper understanding of the structure and dynamics of this GTPase. Because interactions with biological membranes are key for Ras function, Ras-lipid interactions have become a major focus, especially because such interactions evidently involve both the Ras C terminus for lipid anchoring and its G-protein domain. Here, using NMR spectroscopy and molecular dynamics simulations complemented by biophysicaland cell-biology assays, we investigated the interaction between K-Ras4B with the signaling lipid phosphatidylinositol (4,5)phosphate (PIP2). We discovered that the ␤2 and ␤3 strands as well as helices 4 and 5 of the GTPase G-domain bind to PIP2 and identified the specific residues in these structural elements employed in these interactions, likely occurring in two K-Ras4B orientation states relative to the membrane. Importantly, we found that some of these residues known to be oncogenic when mutated (D47K, D92N, K104M, and D126N) are critical for K-Ras-mediated transformation of fibroblast cells, but do not substantially affect basal and assisted nucleotide hydrolysis and exchange. Moreover, the K104M substitution abolished localization of K-Ras to the plasma membrane. The findings suggest that specific G-domain residues can critically regulate Ras function by mediating interactions with membrane-associated PIP2 lipids; these insights that may inform the future design of therapeutic reagents targeting Ras activity.

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“…In particular, we have identified two types of lipid structures that allosterically regulate the enzyme activity and acyl-chain specificity: the cubic phase and membrane fusion intermediates. Cubic phases in zwitterionic membranes and membrane fusion intermediates in PS-Ca 2ϩ mixtures have little in common with each other, except that they both form similar kinds of highly bent structures (47,48). These bent structures correspond to regions of certain cubic phases that allow the joining of one unit cell with another or, in the case of PS-Ca 2ϩ , that forms the fusion pore between bilayers.…”

Section: Membrane Sites Of High Gaussian Curvature Regulate Dgk⑀mentioning

confidence: 99%

Membrane curvature allosterically regulates the phosphatidylinositol cycle, controlling its rate and acyl-chain composition of its lipid intermediates

Bozelli

Jennings

Black

et al. 2018

Journal of Biological Chemistry

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Edited by Paul E. FraserSignaling events at membranes are often mediated by membrane lipid composition or membrane physical properties. These membrane properties could act either by favoring the membrane binding of downstream effectors or by modulating their activity. Several proteins can sense/generate membrane physical curvature (i.e. shape). However, the modulation of the activity of enzymes by a membrane's shape has not yet been reported. Here, using a cell-free assay with purified diacylglycerol kinase ⑀ (DGK⑀) and liposomes, we studied the activity and acyl-chain specificity of an enzyme of the phosphatidylinositol (PI) cycle, DGK⑀. By systematically varying the model membrane lipid composition and physical properties, we found that DGK⑀ has low activity and lacks acyl-chain specificity in locally flat membranes, regardless of the lipid composition. On the other hand, these enzyme properties were greatly enhanced in membrane structures with a negative Gaussian curvature. We also found that this is not a consequence of preferential binding of the enzyme to those structures, but rather is due to a curvature-mediated allosteric regulation of DGK⑀ activity and acylchain specificity. Moreover, in a fine-tuned interplay between the enzyme and the membrane, DGK⑀ favored the formation of structures with greater Gaussian curvature. DGK⑀ does not bear a regulatory domain, and these findings reveal the importance of membrane curvature in regulating DGK⑀ activity and acyl-chain specificity. Hence, this study highlights that a hierarchic coupling of membrane physical property and lipid composition synergistically regulates membrane signaling events. We propose that this regulatory mechanism of membrane-associated enzyme activity is likely more common than is currently appreciated.

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Cations induce shape remodeling of negatively charged phospholipid membranes

Cited by 86 publications

References 68 publications

Contactless Stimulation and Control of Biomimetic Nanotubes by Calcium Ion Gradients

Contactless Stimulation and Control of Biomimetic Nanotubes by Calcium Ion Gradients

K-Ras G-domain binding with signaling lipid phosphatidylinositol (4,5)-phosphate (PIP2): membrane association, protein orientation, and function

Membrane curvature allosterically regulates the phosphatidylinositol cycle, controlling its rate and acyl-chain composition of its lipid intermediates

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