Team:Paris Bettencourt/Modeling/Assisted diffusion/Tube formation

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<h1>Tube formation</h1>
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<h1>1. Tube formation</h1>
<h3>How a connection between two bacteria might be established?</h3>
<h3>How a connection between two bacteria might be established?</h3>
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We do not know much about connections between bacteria. Let's suppose that the sugar envelope of one bacterium is somehow connected to another. Then inside this envelope, for several reasons, the inner pressure of bacteria can locally rise. This pressure can cause the formation of bulges growing from each bacteria inside the envelope. Their tubes could meet and even touch each other on the extremities.
We do not know much about connections between bacteria. Let's suppose that the sugar envelope of one bacterium is somehow connected to another. Then inside this envelope, for several reasons, the inner pressure of bacteria can locally rise. This pressure can cause the formation of bulges growing from each bacteria inside the envelope. Their tubes could meet and even touch each other on the extremities.
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In this situation, the phospholipids on the ends of the tubes are rather unstable. Their hydrophobic parts are more exposed to water because of the high curvature on the extremities. So the energy-preferable state is to fuse.  
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In this situation, the phospholipids on the ends of the tubes are rather unstable. Their hydrophobic parts are more exposed to water because of the high curvature on the extremities. So the energy-preferable state is to fuse. <a href="https://2011.igem.org/Team:Paris_Bettencourt/Modeling/Assisted_diffusion/Tube_formation#references">[1]</a>
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In this case, there is no specific protein involved to do the fusion, so this explanation seems to be the compatible with reality.
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In this case, there is no specific protein involved to do the fusion, so this explanation seems to be the compatible with reality, even though a lot of parameters are unknown.  
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In further paragraphs we will propose a version of the process happening after the membrane fusion.
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To what is happening after the membrane fusion go to <a href="https://2011.igem.org/Team:Paris_Bettencourt/Modeling/Assisted_diffusion/Membrane_tension">2. Membrane tension section.</a>
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Click here to come back to <a href='https://2011.igem.org/Team:Paris_Bettencourt/Modeling/Assisted_diffusion'>Assisted diffusion section.</a></p>
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<li><i>Control of Membrane Fusion Mechanism by Lipid Composition: Predictions from Ensemble Molecular Dynamics</i>, Peter M. Kasson, Vijay S. Pande, PLoS, 2007, available <a href="http://www.ploscompbiol.org/article/info%3Adoi%2F10.1371%2Fjournal.pcbi.0030220">here</a></li>
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Latest revision as of 02:32, 29 October 2011

Team IGEM Paris 2011

1. Tube formation

How a connection between two bacteria might be established?

We do not know much about connections between bacteria. Let's suppose that the sugar envelope of one bacterium is somehow connected to another. Then inside this envelope, for several reasons, the inner pressure of bacteria can locally rise. This pressure can cause the formation of bulges growing from each bacteria inside the envelope. Their tubes could meet and even touch each other on the extremities.

In this situation, the phospholipids on the ends of the tubes are rather unstable. Their hydrophobic parts are more exposed to water because of the high curvature on the extremities. So the energy-preferable state is to fuse. [1]

In this case, there is no specific protein involved to do the fusion, so this explanation seems to be the compatible with reality, even though a lot of parameters are unknown.

To what is happening after the membrane fusion go to 2. Membrane tension section.

Click here to come back to Assisted diffusion section.

References

  1. Control of Membrane Fusion Mechanism by Lipid Composition: Predictions from Ensemble Molecular Dynamics, Peter M. Kasson, Vijay S. Pande, PLoS, 2007, available here