Physical Principles of Membrane Shape Regulation by the Glycocalyx

Shurer, Carolyn R.; Kuo, Joe Chin-Hun; Roberts, LaDeidra Monét; Gandhi, Jay G.; Colville, Marshall J.; Enoki, Thais A.; Pan, Hao; Su, Jin; Noble, Jade M.; Hollander, Michael J.; O’Donnell, John P.; Yin, Rose T.; Pedram, Kayvon; Möckl, Leonhard; Kourkoutis, Lena F.; Moerner, W. E.; Bertozzi, Carolyn R.; Feigenson, Gerald W.; Reesink, Heidi L.; Paszek, Matthew J.

doi:10.1016/j.cell.2019.04.017

Cited by 208 publications

(257 citation statements)

References 117 publications

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“…These results suggested that the corolla pattern formation can also be driven by a phase separation process with competition for space between a percolating phase enriched in CD45 and microdomains enriched in CD2-CD58. Other glycocalyx components could contribute to corolla formation (42).…”

Section: Glycocalyx Proteins Residing In the Dsmac Promote Corolla Pamentioning

confidence: 99%

In silicocharacterization of mechanisms positioning costimulatory and checkpoint complexes in immune synapses

Siokis

Robert

Demetriou

et al. 2020

Preprint

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One Sentence Summary: Computer simulations of immunological synapses reveal the localization mechanisms of immunoglobulin superfamily adhesion and costimulatory/checkpoint complexes.Abstract: Integrin and small immunoglobulin superfamily (sIGSF) adhesion complexes function physiologically in human immunological synapses (IS) wherein sIGSF complexes form a corolla of microdomains around an integrin ring and secretory core. The corolla recruits and retains the major costimulatory and checkpoint complexes that regulate the response to T cell receptor (TCR) engagement, making forces that govern corolla formation of particular interest. We developed a phenomenological agent-based model in order to test different hypotheses concerning the mechanisms underlying molecular reorganization during IS formation. The model showed that sIGSF complexes are passively excluded to the distal aspect of the IS as long as their interaction with the ramified F-actin transport network is absent or weaker than that of integrins. An attractive force between sIGSF adhesion and costimulatory/checkpoint complexes relocates the latter from the centre of the IS to the corolla. The simulations suggest that size based sorting interactions with large glycocalyx components as well as a short-range selfattraction between sIGSF complexes explain the corolla "petals". These molecular and mechanistic features establish a general model that can recapitulate complex pattern formation processes observed in cell-bilayer and cell-cell interfaces.

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Section: Glycocalyx Proteins Residing In the Dsmac Promote Corolla Pamentioning

confidence: 99%

In silicocharacterization of mechanisms positioning costimulatory and checkpoint complexes in immune synapses

Siokis

Robert

Demetriou

et al. 2020

Preprint

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“…Since peaks of ecdysone-controlled Tnc (Fraichard et al, 2006) coincide with formation of new boutons, Tnc may play a major role in the restructuring of the synaptic structures. Mucins appear to be particularly effective at bending cell membranes (Shurer et al, 2019). At synaptic terminals, this cell behavior may facilitate formation of round boutons, with minimal cell surface, thus concentrating the AZ components.…”

Section: Discussionmentioning

confidence: 99%

A presynaptic spectrin network controls active zone assembly and neurotransmitter release

Wang

Friend

Vicidomini

et al. 2019

Preprint

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We have previously reported that Drosophila Tenectin (Tnc) recruits PS2/PS integrin to ensure structural and functional integrity at larval NMJs (Wang et al., 2018). In muscles, Tnc/integrin engages the spectrin network to regulate the size and architecture of synaptic boutons. In neurons, Tnc/integrin controls neurotransmitter release. Here we show that presynaptic Tnc/integrin modulates the synaptic accumulation of key active zone components, including the Ca 2+ channel Cac and the active zone scaffold Brp. Presynaptic α-Spectrin appears to be both required and sufficient for the recruitment of Cac and Brp. We visualized the endogenous α-Spectrin and found that Tnc controls spectrin recruitment at synaptic terminals. Thus, Tnc/integrin anchors the presynaptic spectrin network and ensures the proper assembly and function of the active zones. Since pre-and postsynaptic Tnc/integrin limit each other, we hypothesize that this pathway links dynamic changes within the synaptic cleft to changes in synaptic structure and function. The synaptic extracellular matrix (ECM) contains various synaptic organizers and diffusible molecules that establish and modify synaptic connections during development. ECM receptors, including integrins, transduce these signals by sensing the changes in the synaptic environment and orchestrating the appropriate changes in synapse structure and function (Chavis and Westbrook, 2001;Huang et al., 2006). Disruption of integrins impair synapse development and maturation, neurotransmission, and long-term synaptic plasticity (reviewed in (Park and Goda, 2016)). Integrins together with their ECM ligands form complexes with cytoskeletal proteins and active zone (AZ) components (Carlson et al., 2010;Nishimune et al., 2004;Sunderland et al., 2000). However, it remains unclear how these interactions could influence neurotransmitter release.Spectrin, a principal component of the membrane skeleton, is critical for synaptic transmission (Featherstone et al., 2001;Goodman, 1999). Spectrin subunits function as docking platforms for membrane channels, neurotransmitter receptors and adhesion molecules (reviewed in (Machnicka et al., 2014)). For example, spectrins associate with presynaptic Ca 2+ channels in synaptosome lysates (Carlson et al., 2010;Khanna et al., 2007a;Khanna et al., 2007b). Also, a spectrin-containing presynaptic web enables AZ function in the rodent CNS (Phillips et al., 2001). Recent super-resolution fluorescence microscopy uncovered periodic actin/spectrin lattices along axons, dendrites and spines in a broad range of neuronal cell types (He et al., 2016;Qu et al., 2017;Xu et al., 2013); however, at presynaptic and postsynaptic sites, these patterns were absent (Sidenstein et al., 2016).We have previously found that Drosophila Tenectin (Tnc), an integrin ligand that accumulates in the synaptic cleft at the larval NMJ, modulates synapse development and function (Wang et al., 2018). Tnc recruits αPS2/βPS integrin and forms cis active complexes with distinct pre-and post-synaptic functions....

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“…Cell membrane (plasma membrane) and nuclear membrane are lipid bilayers that are dotted with various protein complexes and ion channels that allow for the transmigration of molecules. In a coarse-grained scenario, the cell membrane can be considered to be composed of a combination of a lipid bilayer, glycocalyx (polymer chains of glycolipids and glycoproteins [46]) and the actin cytoskeleton meshwork attached to the lipid bilayer. This composite cell membrane behaves as a viscoelastic material that ows like a viscous liquid over a short time duration but exhibits a solid-like elastic behaviour at suciently long timescales.…”

Section: Viscoelasticity Of Cell and Extracellular Matrix (Ecm)mentioning

confidence: 99%

Nuclear Plasticity Increases Susceptibility to Damage During Confined Migration

Mukherjee

Barai

Singh

et al. 2020

Preprint

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Large nuclear deformations during migration through conned spaces have been associated with nuclear membrane rupture and DNA damage. However, the stresses associated with nuclear damage remain unclear. Here, using a quasi-static plane strain nite element model, we map evolution of nuclear shape and stresses during conned migration of a cell through a deformable matrix. Plastic deformation of the nucleus observed for a cell with sti nucleus transiting through a stier matrix lowered nuclear stresses, but also led to kinking of the nuclear membrane. In line with model predictions, transwell migration experiments with brosarcoma cells showed that while nuclear softening increased invasiveness, nuclear stiening led to plastic deformation and higher levels of DNA damage. In addition to highlighting the advantage of nuclear softening during conned migration, our results suggest that plastic deformations of the nucleus during transit through sti tissues may lead to bending-induced nuclear membrane disruption and subsequent DNA damage.

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Physical Principles of Membrane Shape Regulation by the Glycocalyx

Cited by 208 publications

References 117 publications

In silicocharacterization of mechanisms positioning costimulatory and checkpoint complexes in immune synapses

In silicocharacterization of mechanisms positioning costimulatory and checkpoint complexes in immune synapses

A presynaptic spectrin network controls active zone assembly and neurotransmitter release

Nuclear Plasticity Increases Susceptibility to Damage During Confined Migration

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