Membrane bending by protein phase separation

Feng, Yuan; Alimohamadi, Haleh; Bakka, Brandon; Trementozzi, Andrea N.; Day, Kasey J.; Fawzi, Nicolas L.; Rangamani, Padmini; Stachowiak, Jeanne C.

doi:10.1073/pnas.2017435118

Cited by 168 publications

(190 citation statements)

References 66 publications

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“…However, one interesting observation in all the species we investigated here is that there was no clear distinctive molecular machine at the base of the membrane projections, raising the question of what drives their formation. This observation is consistent with a recent study which showed that liquid-like assemblies of proteins in membranes can lead to the formation of tubular extensions without the need for solid scaffolds [39].…”

Section: Discussionsupporting

confidence: 93%

In situ imaging of bacterial membrane projections and associated protein complexes using electron cryo-tomography

Kaplan

Chreifi

Metskas

et al. 2021

Preprint

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The ability to produce membrane projections in the form of tubular membrane extensions (MEs) and membrane vesicles (MVs) is a widespread phenomenon among bacteria. Despite this, our knowledge of the ultrastructure of these extensions and their associated protein complexes remains limited. Here, we surveyed the ultrastructure and formation of MEs and MVs, and their associated protein complexes, in tens of thousands of electron cryo-tomograms of ~ 90 bacterial species that we have collected for various projects over the past 15 years (Jensen lab database), in addition to data generated in the Briegel lab. We identified MEs and MVs in 13 species and classified several major ultrastructures: 1) tubes with a uniform diameter (with or without an internal scaffold), 2) tubes with irregular diameter, 3) tubes with a vesicular dilation at their tip, 4) pearling tubes, 5) connected chains of vesicles (with or without neck-like connectors), 6) budding vesicles and nanopods. We also identified several protein complexes associated with these MEs and MVs which were distributed either randomly or exclusively at the tip. These complexes include a secretin-like structure and a novel crown-shaped structure observed primarily in vesicles from lysed cells. In total, this work helps to characterize the diversity of bacterial membrane projections and lays the groundwork for future research in this field.

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Section: Discussionsupporting

confidence: 93%

In situ imaging of bacterial membrane projections and associated protein complexes using electron cryo-tomography

Kaplan

Chreifi

Metskas

et al. 2021

Preprint

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“…We note that for a given value ofŜ, the variance decreases with increasingL for higher values ofŜ and this decrease is more dramatic when compared to the Cahn-Hilliard model (Figure 4b). Even though the number of patches remains more or less unaltered for small values ofŜ asL increases, the number decreases with increasingL for larger values ofŜ (Figure 7e), consistent with the stability behavior noted in Equation (52). These results suggest that the landscape of protein inhomogeneity is not only governed by theÂ-Ŝ space as is the case in the Cahn-Hilliard model; rather the curvature parameters, specificallyL in this case, can have a significant impact on the protein aggregation behavior.…”

Section: Numerical Simulationssupporting

confidence: 82%

“…These observations can lead to system-specific claims of whether membrane protein interactions result in a mechanochemical feedback between curvature and aggregation. In the context of specific biological processes such as endocytosis, aggregation of domains of protein-induced curvature is often assumed a priori or curvature is proposed as an organizing factor to explain cellular observations and experiments in reconstituted systems [46][47][48][49][50][51][52]. By developing a general theoretical framework that accounts for the coupled effects of protein diffusion, aggregation, and curvature generation, we have eliminated the need for such strong assumptions and more importantly, demonstrated that the intricate interactions between these different physics can lead to different regimes of pattern formation and membrane deformations.…”

Section: Discussionmentioning

confidence: 99%

“…Surprisingly, whenŜ = 2000, we noticed that protein aggregates do not form for the value ofL = 8 × 10 −3 and the membrane remains flat. This phenomenon can be explained from the critical value of A in Equation (52). Since bothL andŜ have stabilizing effect on density fluctuations φ (Equation ( 52)), for higher value ofŜ andL, an aggregation coefficient ofÂ = 25 is not sufficient to overcome the stabilizing barrier.…”

Section: Numerical Simulationsmentioning

confidence: 99%

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Curvature-driven feedback on aggregation-diffusion of proteins in lipid bilayers

Mahapatra

Saintillan

Rangamani

2021

Preprint

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Membrane bending is an extensively studied problem from both modeling and experimental perspectives because of the wide implications of curvature generation in cell biology. Many of the curvature generating aspects in membranes can be attributed to interactions between proteins and membranes. These interactions include protein diffusion and formation of aggregates due to protein-protein interactions in the plane of the membrane. Recently, we developed a model that couples the in-plane flow of lipids and diffusion of proteins with the out-of-plane bending of the membrane. Building on this work, here, we focus on the role of explicit aggregation of proteins on the surface of the membrane in the presence of membrane bending and diffusion. We develop a comprehensive framework that includes lipid flow, membrane bending energy, the entropy of protein distribution, and an explicit aggregation potential and derive the governing equations. We compare this framework to the Cahn-Hillard formalism to predict the regimes in which the proteins form patterns on the membrane. We demonstrate the utility of this model using numerical simulations to predict how aggregation and diffusion, coupled with curvature generation, can alter the landscape of membrane-protein interactions.

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“…Thin and mushroom spines, which have defined head shapes, require more mechanical features—heterogeneous force distributions, normal or axial forces, and an induced spontaneous deviatoric curvature representing the periodic protein rings or other deviatoric curvature inducing mechanics along the neck. The heterogeneous distribution of actin-mediated forces and BAR domain proteins can be related to the nanoscale organization of actin filaments and protein phase separation on the membrane surface (Nowak et al, 2021 ; Yuan et al, 2021 ).…”

Section: Discussionmentioning

confidence: 99%

Mechanical Principles Governing the Shapes of Dendritic Spines

et al. 2021

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Dendritic spines are small, bulbous protrusions along the dendrites of neurons and are sites of excitatory postsynaptic activity. The morphology of spines has been implicated in their function in synaptic plasticity and their shapes have been well-characterized, but the potential mechanics underlying their shape development and maintenance have not yet been fully understood. In this work, we explore the mechanical principles that could underlie specific shapes using a minimal biophysical model of membrane-actin interactions. Using this model, we first identify the possible force regimes that give rise to the classic spine shapes—stubby, filopodia, thin, and mushroom-shaped spines. We also use this model to investigate how the spine neck might be stabilized using periodic rings of actin or associated proteins. Finally, we use this model to predict that the cooperation between force generation and ring structures can regulate the energy landscape of spine shapes across a wide range of tensions. Thus, our study provides insights into how mechanical aspects of actin-mediated force generation and tension can play critical roles in spine shape maintenance.

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Membrane bending by protein phase separation

Cited by 168 publications

References 66 publications

In situ imaging of bacterial membrane projections and associated protein complexes using electron cryo-tomography

In situ imaging of bacterial membrane projections and associated protein complexes using electron cryo-tomography

Curvature-driven feedback on aggregation-diffusion of proteins in lipid bilayers

Mechanical Principles Governing the Shapes of Dendritic Spines

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