On the mobility, membrane location and functionality of mechanosensitive channels in Escherichia coli

Berg, Jonas van den; Galbiati, Heloisa; Rasmussen, Akiko; Miller, Samantha; Poolman, Bert

doi:10.1038/srep32709

Cited by 21 publications

(32 citation statements)

References 53 publications

(68 reference statements)

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“…Although all these studies suggest cluster formation for native channels, the debate around this question is still open. A recent study, through use of PALM (photo-activated localization microscopy) and SPT (single particle tracking), had shown strong indications that labeling with fluorescent molecules predisposes MscL channels to form clusters [34]. In either case, if there is any form of channel aggregation in bacterial cells, the collective phenomena we describe here may be directly relevant for the osmotic response of bacteria.…”

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confidence: 95%

Cooperative response and clustering: Consequences of membrane-mediated interactions among mechanosensitive channels

2017

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Mechanosensitive (MS) channels are ion channels which act as cells' safety valves, opening when the osmotic pressure becomes too high and making cells avoid damage by releasing ions. They are found on the cellular membrane of a large number of organisms. They interact with each other by means of deformations they induce in the membrane. We show that collective dynamics arising from the inter-channel interactions lead to first and second-order phase transitions in the fraction of open channels in equilibrium relating to the formation of channel clusters. We show that this results in a considerable delay of the response of cells to osmotic shocks, and to an extreme cell-to-cell stochastic variations in their response times, despite the large numbers of channels present in each cell. We discuss how our results are relevant for E. coli.Abrupt changes in the osmolarity of the environment is a hazard most organisms are subject to at one time or another [1][2][3][4][5][6]. A sudden drop in osmolarity (an osmotic shock ) will cause water to rush into a living cell, and requires an immediate response by the cell to prevent it from getting damaged or undergoing lysis from the increased tension on the cellular membrane. Mechanosensitive channels (or MS channels) are ion channels located on the cell membrane, which open when the membrane tension becomes too high [7,8], and play a crucial role in the cell's defence mechanism against osmotic shocks [9,10]. They act as safety valves, releasing ions and decreasing the osmotic pressure and the membrane tension. Mechanosensitive channels are found in many organisms, and have been well characterised in the bacterium E. coli [11-13].The cellular membrane in which the mechanosensitive channels are inserted is a lipid bilayer. The interior of the bilayer is hydrophobic, making it energetically favourable for it to thicken or compress to match the hydrophobic parts of the channel proteins inserted in the membrane [14]. This results in a deformation profile around each channel, with the thickness of the bilayer being a function of position. This deformation mediates a shortrange effective force between two neighbouring channels, similar to the force between two nearby corks floating on water, which interact through the deformation they induce on the surface of water. This interaction can be attractive or repulsive, depending on the shapes of the two molecules. Furthermore, a theoretical analysis suggests that the interaction between two neighbouring channels lowers the tension needed to open them during an osmotic shock [15], raising the possibility that their function could be influenced by their spatial distribution on the membrane (as already noticed for other membrane proteins [16,17]). This is reinforced by the fact that the channels' attractive forces suggest that they may agglomerate into clusters. Our goal in this paper is to determine the consequences that the inter-channel interaction has on the dynamics of this system, focusing in particular on channel clustering and its con...

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Cooperative response and clustering: Consequences of membrane-mediated interactions among mechanosensitive channels

2017

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“…Driven by membrane tension, the helices are thought to tilt with respect to one another, creating a space between them (up to 3 nm in diameter) for small solutes to non-selectively pass through [15]. Recent studies debate the existence and the role of spontaneous clustering of one of the MSCs found in Escherichia coli, MSC of large conductance (MscL) [16,17]. Indeed, membrane clustering appears to be a common mechanism in cellular signaling, and has been observed for many transmembrane proteins and signaling receptors [18].…”

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confidence: 99%

“…Clustering of MSC in vitro has been shown to result in collective, non-linear gating behavior [16], suggesting that it could tamper with cell's passive response during a hypoosmotic shock recovery. However, assessing the extent of MscL aggregation via imaging techniques in vivo has proven to be difficult due to the potential artifacts of the MscL tags on the process [17], and hence opens a need to explore orthogonal ways to investigate the aggregation phenomenon. Here, by developing a minimal computer model of MSCs embedded in a fluid membrane, we investigate the physical mechanisms behind the MSC cluster formation and cooperative gating, and their implications on cell-volume regulation.…”

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confidence: 99%

“…redAs we did not observed any MSC clustering due to pure membrane-mediated interactions, we chose a top-down strategy. We know that: (i) MSC aggregation has been reported in vitro [16], and in vivo while working with MSCs labelled with a small covalent dye [17], (ii) direct inter-protein interactions, such as polar and electrostatic interactions and packing of small apolar side chains [24][25][26][27][28][29], can lead to attractions of trans-membrane proteins [18]. In addition, local lipid phase separation around the protein can yield effective inter-protein attraction and protein aggregation.…”

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confidence: 99%

“…Our prediction on the role of clustering for the cell volume regulation can be probed experimentally by tracing the volume recovery posthypoosmotic shock for different extents of the clustering. The MSC clustering can be enhanced by tagging the channels with fluorescent proteins [17] or modulated by expressing the channels to different levels.…”

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Dynamic clustering regulates activity of mechanosensitive membrane channels

Paraschiv

Hegde

Ganti

et al. 2019

Preprint

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Experiments have suggested that bacterial mechanosensitive channels separate into 2D clusters, the role of which is unclear. By developing a coarse-grained computer model we find that clustering promotes the channel closure, which is highly dependent on the channel concentration and membrane stress. This behaviour yields a tightly regulated gating system, whereby at high tensions channels gate individually, and at lower tensions the channels spontaneously aggregate and inactivate. We implement this positive feedback into the model for cell volume regulation, and find that the channel clustering protects the cell against excessive loss of cytoplasmic content.

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Thiopseudomonas acetoxidans sp. nov., an aerobic acetic and butyric acids oxidizer isolated from anaerobic fermentation liquid of food waste

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et al. 2024

Antonie van Leeuwenhoek

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On the mobility, membrane location and functionality of mechanosensitive channels in Escherichia coli

Cited by 21 publications

References 53 publications

Cooperative response and clustering: Consequences of membrane-mediated interactions among mechanosensitive channels

Cooperative response and clustering: Consequences of membrane-mediated interactions among mechanosensitive channels

Dynamic clustering regulates activity of mechanosensitive membrane channels

Thiopseudomonas acetoxidans sp. nov., an aerobic acetic and butyric acids oxidizer isolated from anaerobic fermentation liquid of food waste

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