Team:USTC-China/Project

From 2011.igem.org

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Revision as of 18:42, 5 October 2011


Contents

Overview

Abstract
 Introduction/motivation</br>  Methods
 Results and discussion
 Conclusion
 Limitations & Future work
 Reference



Abstract

    So far we have successfully constructed a novel system in which bacterial colonies will automatically divide into two parts after certain time. Over the summer we have been working on assembling riboswitches finely tuned by small molecules, which will act as the main power to drive two parts away from each other, and toggle switches pushed on and off while memorizing current state, which will play the role of giving birth to two ‘different’ kinds of bacteria in one colony. Furthermore, we have been modulating the toggle switch to produce a more balanced ratio and creatively integrating quorum sensing system (to Modules/Quorum sensing) into our system to optimize our results .

    As to modeling, we have not only been building models of the movement but also been collecting and analyzing data for a aptamers database for small molecules and corresponding genomic sequences and structures in guiding bacteria.

    Finally, we are intended to construct a Artificial Innate Immunity System (AIIS) with our self-organized bacteria, in which reprogrammed intestinal bacteria is used as a safety weapon to destroy the pathogens which invade the intestinal mucosal system.

Introduction/Motivation

    Cells grow and cells divide. This is the basis of life and nature. In our eyes, a bacterial colony, which is also formed by bacterial growth and division, is a big cell too. Given that bacteria always play their roles as a ‘group’ instead of an ‘individual’, a bacterial colony can be considered as the unit of our intended function. It may not be hard to imagine if this unit could grow and divide itself automatically, significant applications would be developed. In fact, similar ideas have already been realized in eukaryotic systems.

    Chemotaxis has always been a powerful tool in organizing bacteria’s movement and it’s always an important ability to reprogram bacteria to follow entirely new chemical signals. Riboswitches, which have been a hot issue of synthetic biology recently, can be used to guide E.Coli toward and precisely localized to a completely new chemical signal. We take advantage of them in our system to act as the main power to drive two parts of a bacterial colony away from each other. Here we really want to thank Professor J. S. Parkinson for providing ΔcheZ strain RP1616 and the corresponding wild type RP437 and Professor J. P. Gallivan for directing our construction of riboswitches.

    Now the key problem is to produce two different kinds of bacterial in one colony, in which one kind could be guided by riboswitches mentioned above while the other would keep still or move to the opposite side. The work of PKU-IGEM 2007 provides us with a ideal platform in which bacterial are equipped with devices to differentiate out of homogeneous conditions.Thanks to their warm help, we acquire Toggle-switches and made efforts to modulate the switch into to produce a more balanced ratio, so that the results would be more likely to be apparently visible.

    With the help of modeling, it’s spotted that the part driven away cannot be efficiently turned into another colony compared with the other part staying, since bacteria tend to move instead of grouping on their way towards the most concentrated location of the chemical signal. Quorum sensing, as another most applied mechanism in synthetic biology, give us a hint in solving this problem.

    The final step is to picture the blueprint of the application of our system. Here we present one in medical area, in which reprogrammed intestinal bacteria can help you with pathogens invasion. (Artificial Innate Immunity System) Given the difficulties of human experiment, we conduct a simulation in E.coli.

Method

  1. Verification of ΔcheZ strain
  2. Construction of Riboswitch: Theophylline guided riboswitch + cheZ
  3. Verification of Toggle-switch
  4. Modulate Toggle-switches to produce more balanced ratio
  5. Incorporation of Riboswitch into one side of Toggle-switch
  6. Verification of the constructed system’s function
  7. Integration of Quorum-sensing system (not finished yet)
  8. Test (not finished yet)
  9. Application: simulation of AIIS(not finished yet)
  10. Results and Discussion

Results and Discussions

Conclusion

    

Limitations and Future work

References

1.Timothy S. Gardner, Charles R. Cantor, James J. Collins (2000) Construction of a Genetic toggle switch in Escherichia coli. Nature, 403,339-342
2.Shana Topp, Justin P. Gallivan (2006) Guiding Bacteria with Small Molecules and RNA. J.Am.Chem.Soc, 129,6870-6811
3.Chunbo Lou, Xili Liu, Ming Ni.etc (2010) Synthesizing a novel genetic sequential logic circuit: a push-on push-off switch. Molecular Systems Biology, 6:350
4.Joy Sinha, Samuel J Reyes, Justin P Gallivan (2010) Reprogramming bacteria to seek and destroy an herbicide. Nature Chemical Biology, 6,464-470
5.Steven L. Porter, George H. Wadhams, Judith P. Armitage (2011) Signal processing in complex chemotaxis pathways. Nature Reviews Microbiology, 9,153-165
6.Warren C. Ruder, Ting Lu, James J. Collins (2011) Synthetic Biology Moving into the Clinic. Science,333,1248-1252
7.Nazanin Saeidi, Choon Kit Wong, Tat-Ming Lo .etc (2011) Engineering microbes to sense and eradicate Pseudomonas aeruginosa, a human pathogen. Molecular Systems Biology,7:251