Team:Osaka/MOTILITY

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Motile cells, such as <i>Escherichia Coli</i> and <I>Salmonella typhimurium</I> swim by means of flagella. So, we can regard cells as biological paints, we named ColorColi, that can move automatically on soft agar. Although we can create a lot of artworks (you can see our works at <a href="https://2009.igem.org/Team:Osaka/WORKS">WORKS</a>) by using innate motility of cells, engineering cells motility should expand the application of ColorColi in Art. This year, we aimed to stop the swarming motility of cell for out-put of arithmetic processing by cell-cell communication.(see <a href="https://2009.igem.org/Team:Osaka/SIGNAL">SIGNAL</a>). </p>
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Motile cells, such as <i>Escherichia Coli</i> and <I>Salmonella typhimurium</I> swim by means of flagella. So, we can regard cells as biological paints, we named ColorColi, that can move automatically on soft agar. Although we can create a lot of artworks (you can see our works at <a href="https://2009.igem.org/Team:Osaka/WORKS">WORKS</a>) by using innate motility of cells, engineering cells motility should expand the application of ColorColi in Art. This year, we aimed to stop the swarming motility of cell for one of the out-put of arithmetic processing by cell-cell communication.(see <a href="https://2009.igem.org/Team:Osaka/SIGNAL">SIGNAL</a>). </p>
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<p>In past iGEM projects, several teams tried to control cell motility (<a href="https://2008.igem.org/Team:iHKU">iHKU2008</a>, <a href="https://2008.igem.org/Team:Imperial_College">Imperial2008</a>, <a href="http://parts.mit.edu/wiki/index.php/Penn_State_University_2006">Penn State Uni2006</a>). However, all their approaches focused on the motor rotation itself. Bacteria flagella, one of nano machines, has a noteworthy characteristic expect motor mechanism, which is "protein translocation" from the cytoplasm to the external environment. This protein translocation mechanism might be broadly applicable to problems in biotechnology if it is possible to control protein  translocation.</p>
<p>In past iGEM projects, several teams tried to control cell motility (<a href="https://2008.igem.org/Team:iHKU">iHKU2008</a>, <a href="https://2008.igem.org/Team:Imperial_College">Imperial2008</a>, <a href="http://parts.mit.edu/wiki/index.php/Penn_State_University_2006">Penn State Uni2006</a>). However, all their approaches focused on the motor rotation itself. Bacteria flagella, one of nano machines, has a noteworthy characteristic expect motor mechanism, which is "protein translocation" from the cytoplasm to the external environment. This protein translocation mechanism might be broadly applicable to problems in biotechnology if it is possible to control protein  translocation.</p>

Revision as of 15:10, 18 October 2009

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MOTILITY

Overview

Under construction

Object

Motile cells, such as Escherichia Coli and Salmonella typhimurium swim by means of flagella. So, we can regard cells as biological paints, we named ColorColi, that can move automatically on soft agar. Although we can create a lot of artworks (you can see our works at WORKS) by using innate motility of cells, engineering cells motility should expand the application of ColorColi in Art. This year, we aimed to stop the swarming motility of cell for one of the out-put of arithmetic processing by cell-cell communication.(see SIGNAL).


In past iGEM projects, several teams tried to control cell motility (iHKU2008, Imperial2008, Penn State Uni2006). However, all their approaches focused on the motor rotation itself. Bacteria flagella, one of nano machines, has a noteworthy characteristic expect motor mechanism, which is "protein translocation" from the cytoplasm to the external environment. This protein translocation mechanism might be broadly applicable to problems in biotechnology if it is possible to control protein translocation.


So we made a new part to inhibit flagellar protein translocation and as a result stop the motility as a result of failure of flagellar assemebly. And in addition, we tested the compatibility of EpsE that work as molecular clutch and stop the motor rotation in B. subtilis for further work.


Design

Bacterial flagellar assembly is proceed by highly sophisticated manner in which gene regulation coordinates with self assembly of motor proteins[1].To form the flagellar axial structure, "molecular propeller", at the cell exterior, these protein subunits must be translocated across the cell membrane. And this work is carried out by flagellar type III secretion system [2]. By a lot of study, the molecular mechanism of this systems is being elucidated recently.Currently, the following model for flagellar protein export is suggested (Fig. 1). N-terminal of segment of a substrate is initially docked with by formation of the FliHx-FliI6 complex. And then, ATP hydrolysis induces dissociation of the FliHx-FliI6 and successive unfolding and translocation of the substrates is driven by the PMF.



FliH, the regulator of ATPase FliI, is one of soluble components of export apparatus. In the absence of FliI, FliH inhibits the protein translocation [3]. Further more, even in the presence of FliI, FliH expression from pTrc99A vector caused pronounced inhibition of swariming motility of the cell [4].


Considering above mentioned molecular mechanism, we aimed to control flagellar protein transloaction by expressing FliH. Because the molecular propeller is required for motility, the inhibition of flagellar assembly should lead the inhibition of cell motility. Furthermore, the components of flagellar export apparatus is highly conserved among a number of bacteria, this method can be potentially applied for various bacteria.


Results

We successfully constructed BioBrick fliH.(パーツのリンク)To characterize the effect of FliH on the swarming motility and protein secretion level, we used pTet and pT7 promoters. Salmonella typhimurium was transformed with [ptet flih], [pt7 flih], and pUC19 for vector control. FliH expression from both parts severely decreased the swarming motility of the cell [スワーム図, relative swarm size]. And the secretion level of flagellar protein is also decreased [secretion level]. So, these results showed that FliH can be used to control the swarming motility and the secretion level of flagellar protein as we expected.

In addition, we tested the compatibility of our parts in Escherichia Coli (うのっち)....

We also tried to stop the flagellar rotation by using EpsE. We used pTet promotor to express EpsE. However, EpsE had no effect on swarming motility of the cell. Although FliG which EpsE interacts with is highly conserved between Salmonella typhimurium and B. subtilis, EpsE was no functional in Salmonella typhimurium. Furthermore, other B. subtilis's intrinsic protein might be required for mediating the interaction between EpsE and FliG (personal communication with Dr. Phil Aldridge).Taken all together, using EpsE in any host other than B. subtilis to control the flagellar rotation and cell motility is ill-advised action.

Application

We showed that FliH is useful parts to control the swarming motility and protein secretion level. Now we are integrating this parts with cell-cell communication systems. Although we used FliH to control the swarm size, there are potentially several applications of this part. Flagellar type III protein export is notably fast and the protein export rate is 55kDa subunits persec. Therefore, this system can be applied to drug delivery system in the future[5].