Insights into Membrane Curvature Sensing and Membrane Remodeling by Intrinsically Disordered Proteins and Protein Regions

Has, Chandra; Sivadas, P; Das, Sovan Lal

doi:10.1007/s00232-022-00237-x

Cited by 25 publications

(15 citation statements)

References 236 publications

(344 reference statements)

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“…Experiments to verify these aspects of DOL will be required to delineate the conditions under which DOL can be modeled as simple nanoreactors in which the membrane is homogeneous and its biophysical properties (e.g., receptor diffusion constant) are independent of DOL size. For proteins whose oligomerization behavior depends on membrane curvature, 85,86 the assumption of DOL size-independent behavior will likely fail, making modeling more challenging. On the positive side, wherever membrane biophysics does turn out to be DOL size-dependent, development of a series of DOL having a range of diameters could enable new opportunities—e.g., protein sensors of membrane curvature could be studied and engineered.…”

Section: Discussionmentioning

confidence: 99%

Digital nanoreactors for control over absolute stoichiometry and spatiotemporal behavior of receptors within lipid bilayers

Maingi

Zhang

Thachuk

et al. 2022

Preprint

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Interactions between membrane proteins are essential for cell survival and proper function, but the structural and mechanistic details of these interactions are often poorly understood. Even the biologically functional ratio of protein components within a multi-subunit membrane complex—the native stoichiometry—is difficult to establish. We have demonstrated digital nanoreactors that can control interactions between lipid-bound molecular receptors along three key dimensions: stoichiometric, spatial, and temporal. Each nanoreactor is based on a DNA origami ring, which both templates the synthesis of a liposome and provides tethering sites for DNA-based receptors. Receptors are released into the liposomal membrane using strand displacement and a DNA logic gate measures receptor heterodimer formation. High-efficiency tethering of receptors enables the kinetics of receptors in 1:1 and 2:2 absolute stoichiometries to be observed by bulk fluorescence in a plate reader. Similar ′single molecule in bulk′ experiments using DNA-linked membrane proteins could determine native stoichiometry and the kinetics of membrane protein interactions for applications ranging from signalling research to drug discovery.

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Section: Discussionmentioning

confidence: 99%

Digital nanoreactors for control over absolute stoichiometry and spatiotemporal behavior of receptors within lipid bilayers

Maingi

Zhang

Thachuk

et al. 2022

Preprint

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“…Recently, new efforts have been made to improve computational modeling of intrinsically disordered proteins (Thomasen et al, 2022;Klein et al, 2021;Tran and Kitao, 2020). Several reviews have also been dedicated to the role of intrinsic disorder during lipid-protein interactions highlighting the effects on membrane curvature (Has, Sivadas and Das, 2022;Cornish et al, 2020;Fakhree, Blum and Claessens, 2019;Snead and Stachowiak, 2018). Intrinsic disorder presents itself as an additional complexity to the already difficult problem of lipid-protein interactions during biological events that require large configurational and conformational changes.…”

Section: Intrinsic Disorder In Lipid-protein Interactionsmentioning

confidence: 99%

Enhanced sampling for lipid-protein interactions during membrane dynamics

Masone¹

2023

Biocell

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The inflexible concept of membrane curvature as an independent property of lipid structures is today obsolete.Lipid bilayers behave as many-body entities with emergent properties that depend on their interactions with the environment. In particular, proteins exert crucial actions on lipid molecules that ultimately condition the collective properties of the membranes. In this review, the potential of enhanced molecular dynamics to address cell-biology problems is discussed. The cases of membrane deformation, membrane fusion, and the fusion pore are analyzed from the perspective of the dimensionality reduction by collective variables. Coupled lipid-protein interactions as fundamental determinants of large membrane remodeling events are also commented. Finally, novel strategies merging cell biology and physics are considered as future lines of research.

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“…BAR domain class of proteins are the quintessential curvature inducing scaffold proteins and are ubiquitously present in the endocytic recycling pathways and play a crucial role in vesicular transport processes in the cell. ,− BAR family of proteins have a wide range of curvatures with proteins such as F-Bar and N-BAR exhibiting positive curvatures ,, and proteins such as I-BAR exhibiting negative curvature . When these proteins bind to the membrane surface, they impose their local curvature on the membrane and also work in concert with each other at longer length scales to induce nonlocal curvatures on the membrane. − Though the subcellular processes of vesicular transports is mediated by multiple curvature proteins interacting in concert with each other, this aspect has not been studied very much in reconstitution experiments. − Also, lately role of flexible intrinsically disordered regions in scaffolding proteins has been shown to be important, − which highlights the importance of considering the effective curvature of the scaffold protein as a distribution rather than having one fixed curvature value. Even the quintessential “scaffold” proteins such as BAR domain proteins can have extremely anisotropic shapes and a range of interaction strength with the membrane that significantly affects the sorting of proteins on the membrane surface .…”

Section: Introductionmentioning

confidence: 99%

Membrane Remodeling Due to a Mixture of Multiple Types of Curvature Proteins

Kumar

Srivastava

2022

J. Chem. Theory Comput.

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We present an extension of the Monte Carlo based mesoscopic membrane model, where the membrane is represented as a dynamically triangulated surface and the proteins are modeled as anisotropic inclusions formulated as in-plane nematic field variables adhering to the deformable elastic sheet. In the extended model, we have augmented the Hamiltonian to study membrane deformation due to a mixture of multiple types of curvature generating proteins. This feature opens the door for understanding how multiple kinds of curvature-generating proteins may be working in a coordinated manner to induce desired membrane morphologies. For example, among other things, we study membrane deformations and tubulation due to a mixture of positive and negative curvature proteins as mimics of various proteins from BAR domain family. We also study the effect of membrane anisotropy that manifests as differential binding affinity and organization of curvature proteins, leading to insights into the tightly regulated cargo sorting and transport processes. Our simulation results show different morphology of deformed vesicles that depend on membrane tension, the curvatures and number of the participating proteins as well as on protein–protein and membrane–protein interactions.

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Insights into Membrane Curvature Sensing and Membrane Remodeling by Intrinsically Disordered Proteins and Protein Regions

Cited by 25 publications

References 236 publications

Digital nanoreactors for control over absolute stoichiometry and spatiotemporal behavior of receptors within lipid bilayers

Digital nanoreactors for control over absolute stoichiometry and spatiotemporal behavior of receptors within lipid bilayers

Enhanced sampling for lipid-protein interactions during membrane dynamics

Membrane Remodeling Due to a Mixture of Multiple Types of Curvature Proteins

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