Team:INSA-Lyon/Molecular
From 2014.igem.org
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One of the main goals of our modeling work this year was to understand the <b>structure</b> of the curli subunit protein, <b>CsgA</b> and its behavior when engineered with a tag constituted of either six histidines (that we will call <b>His1-tag</b> from now on) or twice that motif (<b>His2-tag</b>), since this peptide is known for its nickel chelation properties.</br> | One of the main goals of our modeling work this year was to understand the <b>structure</b> of the curli subunit protein, <b>CsgA</b> and its behavior when engineered with a tag constituted of either six histidines (that we will call <b>His1-tag</b> from now on) or twice that motif (<b>His2-tag</b>), since this peptide is known for its nickel chelation properties.</br> | ||
- | We then discussed over our results with the | + | We then discussed over our results with the wet lab members to define a way to confirm the accuracy of our model, and so we were able to assess that, in accordance with litterature, the <b>best position</b> for the tag was by the <b>C-terminus</b> of the protein. We also determined that the His-tag was more likely to take a <b>floating conformation</b> instead of folding itself around CsgA. |
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- | The results of the | + | The results of the wet lab however, showed <a href="https://2014.igem.org/Team:INSA-Lyon/Results#contenu1">no particular decrease</a> in curli formation between tagged and wildtype-producing <i>E.coli</i>, and added to this, the nickel chelation seemed greater with the tags than without it, although the difference was hard to catch since <a href="https://2014.igem.org/Team:INSA-Lyon/Results#contenu2">CsgA wildtype is already able to chelate nickel </a>. This means that <b>the floating conformation seems more likely to happen <i>in vivo</i> than the folded one</b>. |
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- | <i>"Then what is the point of tagging the original protein when it already chelates so much?"</i> are you going to ask me. The answer is quite simple : just for one protein, with only one His1-tag we can hope for a <b>25 % increase of its chelation power</b>. Now remember that CsgA is only the subunit of a fiber that is composed of thousands of them; that one bacterium bears hundreds, maybe thousands of these fibers; and that a culture of such bacteria allows for a countless number of bacteria as well. It's easy to understand how an increase of 25% of efficiency of the elementary unit of the fiber is already quite something! Well, that's provided the floating conformation is the preferred one, but as the <a href="https://2014.igem.org/Team:INSA-Lyon/Results#contenu2"> | + | <i>"Then what is the point of tagging the original protein when it already chelates so much?"</i> are you going to ask me. The answer is quite simple : just for one protein, with only one His1-tag we can hope for a <b>25 % increase of its chelation power</b>. Now remember that CsgA is only the subunit of a fiber that is composed of thousands of them; that one bacterium bears hundreds, maybe thousands of these fibers; and that a culture of such bacteria allows for a countless number of bacteria as well. It's easy to understand how an increase of 25% of efficiency of the elementary unit of the fiber is already quite something! Well, that's provided the floating conformation is the preferred one, but as the <a href="https://2014.igem.org/Team:INSA-Lyon/Results#contenu2">wet lab results</a> seem to prove that His2-tagged CsgA chelates better than His1-tagged CsgA, that already chelates more than wildtype CsgA, we can be confident in saying that <b>the floating conformation is actually the most present</b> in the fiber. However, as we are still unable to accurately quantify curli and CsgA, we unfortunately cannot provide any information regarding the difference between the theoretical chelating power of CsgA and the experimentally determined quantity of captured nickel. |
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Revision as of 00:18, 18 October 2014
One of the main goals of our modeling work this year was to understand the structure of the curli subunit protein, CsgA and its behavior when engineered with a tag constituted of either six histidines (that we will call His1-tag from now on) or twice that motif (His2-tag), since this peptide is known for its nickel chelation properties. We then discussed over our results with the wet lab members to define a way to confirm the accuracy of our model, and so we were able to assess that, in accordance with litterature, the best position for the tag was by the C-terminus of the protein. We also determined that the His-tag was more likely to take a floating conformation instead of folding itself around CsgA.
Conclusion
Overall sum up
Through our molecular study of a CsgA protein engineered with either His1-tag or His2-tag, we came to the conclusion that since it has a longer reach and its mobility makes it more available for chelation, using a tag positioned by the C-terminus of the protein is more relevant than placing it in the middle of the sequence, although doing so may provide a little more chelation power as long as the tag isn't too long. We also showed that there are two possible conformations : one is folded on the side of CsgA and a priori does not increase the already-existing chelating power of CsgA; the other is a "floating" conformation where the tag is not attracted to the protein and is able to improve its chelating power by up to 25%!
What we couldn't achieve
Unfortunately, having very little time and people, there are a few things we couldn't investigate as extensively as we wanted. Here are a few of those things:
- more simulations with His2-tag. Since they took an awful lot of time, we only ran a handful of them;
- modelisation of the docking between two CsgA proteins, and the influence of the His-tags, that our lack of experience prevented us from conducting;
- find out just how many tags can be added without altering the protein properties of adherence and polymerization;