Team:UNICAMP-Brazil/Coliguard/Killing
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=The Coliguard - Killing= | =The Coliguard - Killing= | ||
==Introduction== | ==Introduction== | ||
- | After the detection of a contaminant by our | + | After the detection of a contaminant by our Coliguard System, part of the labor population must become the killer population, which has as the most remarkable feature the ability to kill this contaminant. |
- | As our project is focused to solve the problem in the production of ethanol, we decided to develop our killing mechanism to be able to destroy the most important bacterial contaminant of this process, the | + | As our project is focused to solve the problem in the production of ethanol, we decided to develop our killing mechanism to be able to destroy the most important bacterial contaminant of this process, the ''Lactobacillus'' group, a group of Gram positive bacteria. |
- | But how can a bacteria kill another bacteria without killing itself? That was our first question to answer in the development of this mechanism. To solve this problem we focused in the main biological difference between our guard bacteria, E. coli, and the contaminant, | + | But how can a bacteria kill another bacteria without killing itself? That was our first question to answer in the development of this mechanism. To solve this problem we focused in the main biological difference between our guard bacteria, ''E. coli'', and the contaminant, ''Lactobacillus''. |
- | The main difference is that E. coli is a Gram Negative bacteria and | + | The main difference is that ''E. coli'' is a Gram Negative bacteria and ''Lactobacillus'' is a Gram positive. That means ''E. coli'' have two cell membranes around a thin cell wall which remains isolated from the intracellular and extracellular environment. That not occurs with the Gram positive bacteria, because they have a thick cell wall with direct contact with the extracellular environment and surrounds the cell membrane. |
- | With these differences in mind we propose a way to attack the exposed cell wall of | + | With these differences in mind we propose a way to attack the exposed cell wall of ''Lactobacillus'' secreting something in the medium capable of doing harm just to this structure and not to E. coli’s outer membrane. |
We found lysozymes the most able enzyme to do this work, and we chose it as our weapon. | We found lysozymes the most able enzyme to do this work, and we chose it as our weapon. | ||
- | Now that our weapon has been chosen, we face a new problem. How to put it out the E. coli? | + | Now that our weapon has been chosen, we face a new problem. How to put it out the ''E. coli''? |
==The Alpha Hemolysin Secretion System== | ==The Alpha Hemolysin Secretion System== | ||
- | E. coli, as a Gram negative bacteria, doesn’t have a well developed secretion system to transport proteins to the extracellular medium. The best system we found is the alpha hemolysin secretion system. | + | ''E. coli'', as a Gram negative bacteria, doesn’t have a well developed secretion system to transport proteins to the extracellular medium. The best system we found is the alpha hemolysin secretion system. |
- | The alpha hemolysin secretions system is encoded in a operon containing four genes, Picture1A: hlyD and HlyB constitutes the transporter, HlyA is the hemolysin itself and HlyC codifies to a protein important to make HlyA active (1). | + | The alpha hemolysin secretions system is encoded in a operon containing four genes, Picture1A: ''hlyD'' and ''HlyB'' constitutes the transporter, ''HlyA'' is the hemolysin itself and ''HlyC'' codifies to a protein important to make ''HlyA'' active (1). |
- | To use the hemolysin system we intend to construct a biobrick with HlyB and HlyD and 252 bp of the carboxy terminal region of HlyA, using primers in Silver Standard, Picture 1B. This 252 bp works as a signaling region enabling the genes fused to it to codify for a peptide capable of being recognized by hlyB and hlyD and be transported outside the cell (2,3). | + | To use the hemolysin system we intend to construct a biobrick with ''HlyB'' and ''HlyD'' and 252 bp of the carboxy terminal region of ''HlyA'', using primers in Silver Standard, Picture 1B. This 252 bp works as a signaling region enabling the genes fused to it to codify for a peptide capable of being recognized by hlyB and hlyD and be transported outside the cell (2,3). |
- | This is the first biobrick designed to make E. coli secretes a protein using a transport system and can be used to a big range of targets helping to solve the problem of secretion in E. coli. | + | This is the first biobrick designed to make ''E. coli'' secretes a protein using a transport system and can be used to a big range of targets helping to solve the problem of secretion in ''E. coli''. |
- | [[Image: | + | [[Image:Hemolysin_secretion_system.JPG|center|500px]] |
- | We will fuse to this biobrick another one with the lambda phage’s lysozyme without the stop codon | + | We will fuse to this biobrick another one with the lambda phage’s lysozyme without the stop codon. We hope this lysozyme with the signaling peptide will be secreted and outside the cell it will be able to kill and destroy all the Lactobacilli and Gram positive contaminants who dare to stay on our way. |
- | This secretion system doesn’t works for all proteins and the only way to know it is by trial and error. So in parallel we created | + | This secretion system doesn’t works for all proteins and the only way to know it is by trial and error. So in parallel we created others killing mechanisms. |
==The Kamikaze System== | ==The Kamikaze System== | ||
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To test this device we will use only biobricks already made, we will fuse a T7 promoter, BBa I7469, designed by the Cambridge 2007 team, to the T4-Endolysin, BBa K112806, designed by the UC Berkeley 2008 team. | To test this device we will use only biobricks already made, we will fuse a T7 promoter, BBa I7469, designed by the Cambridge 2007 team, to the T4-Endolysin, BBa K112806, designed by the UC Berkeley 2008 team. | ||
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+ | [[Image:Endolysin strategy.JPG|center|500px]] | ||
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In our system, only the contaminant which receive CeaB will transcript and translate this gene leading to its death by the destruction of its own DNA. This system is less metabolic expensive than the Alpha Hemolysin Secreation System and the Kamikaze Sytem, the target will have to afford with the costs of his own killing system. | In our system, only the contaminant which receive CeaB will transcript and translate this gene leading to its death by the destruction of its own DNA. This system is less metabolic expensive than the Alpha Hemolysin Secreation System and the Kamikaze Sytem, the target will have to afford with the costs of his own killing system. | ||
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- | + | ===References=== | |
+ | ---- | ||
+ | #<p style=”text-align:justify;”>Binet, R., Letoffe, S., Ghigo, J.M., Delepelaire, P., Wandersman, C. Gene, 1997, 192, 7–11.</p> | ||
+ | #<p style=”text-align:justify;”>Holland, I.B., Blight, M.A. and Kenny, B. J. Bioenerg. Biomembr. 1990. 22, 473 491.</p> | ||
+ | #<p style=”text-align:justify;”>Gentschev I., Mollenkopf H., Sokolovic Z., Hess J., Kaufmann S.H.E., Goebel W. Gene. 1996, 179,133–140.</p> | ||
+ | #<p style=”text-align:justify;”>Young R. Microbiol Rev. 1992, 56. 430–481</p> | ||
+ | #<p style=”text-align:justify;”>James, R., Kleanthous, C. and Moore, G.R., Microbiology.1996. 142, 1569–1580.</p> | ||
+ | #<p style=”text-align:justify;”>Braun, V., Pilsl, H. and Gross, P. Arch. Microbiol. 2004. 161, 199–206.</p> | ||
+ | #<p style=”text-align:justify;”>Kleanthous, C., Hemmings, A.M., Moore, G.R. and James, R. Mol. Microbiol.. 2002. 28, 227–233.</p> | ||
Latest revision as of 03:06, 22 October 2009
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