Team:Tsinghua-A/Project

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<p>'Life' is too big a word, especially when we are talking about synthetic biology, but we still find it interesting, in our life, when everyone meets alternatives and makes his decisions, that colorful behaviors and lifestyles just differentiate from small left-or-right choices, and that widely-differed ones make up a well-operated society. This year our study will be concentrated on controllable choice-making E. Coli, with left-or-right directions of gene expression to be determined, thus to realize the life-like differentiation and dedifferentiation, and synthesized function of the cell 'teamwork'. That's the idea why we named our project after 'E. CoLIFE'.<a class="textLink" href="www.baidu.com">readmore</a></p>
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<p>Biological parts ,one of the most important tools in the research of synthetic biology ,have been designed ,created and documented in large numbers, most of which ,however, lack scalability. To be more precise, the scalability of a biological part refers to its ability of handling of expanding scale of input and output and the ability of expansion in function. In our project, we aim to demonstrate that a scalable biological part could be devised through proper arrangement of certain sequences in the presence of some protein.
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We resort to an scalable electronic component ,PLD or Programmable Logic Device in this project. The definition of PLD from Wikipedia is quoted as below:” A programmable logic device or PLD is an electronic component used to build reconfigurable digital circuits. Unlike a logic gate, which has a fixed function, a PLD has an undefined function at the time of manufacture. Before the PLD can be used in a circuit it must be programmed, that is, reconfigured.” That is, digital systems could be integrated to it at will through computer programming by the user, instead of producing an electronic component with a fixed function. Actually, we have constructed a biological part that functions as a PLD, though primitive.
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The most basic elements in digital circuits are the AND gate and OR gate. We resort to Cre/LoxP system to enable the biological part with the ability to interchange between AND gate and OR gate by regulation of the concentration of the protein Cre.<a class="textLink" href="https://2012.igem.org/Team:Tsinghua-A/Project/Motivation">readmore</a>
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<p>With the help of site-specific recombination, we manage to change the logic from the physical layer. To a further step, we design a system whose logic changes between AND and OR.<a class="textLink" href="https://2012.igem.org/Team:Tsinghua-A/Project/Design">readmore</a></p>
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<p>'Life' is too big a word, especially when we are talking about synthetic biology, but we still find it interesting, in our life, when everyone meets alternatives and makes his decisions, that colorful behaviors and lifestyles just differentiate from small left-or-right choices, and that widely-differed ones make up a well-operated society. This year our study will be concentrated on controllable choice-making E. Coli, with left-or-right directions of gene expression to be determined, thus to realize the life-like differentiation and dedifferentiation, and synthesized function of the cell 'teamwork'. That's the idea why we named our project after 'E. CoLIFE'.</p>
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<p>We can transform AND gate into OR gate through a flip of the sequence between opposite loxP sites. Moreover, based on a similar idea, our system shows a strong scalability in further design.<a class="textLink" href="https://2012.igem.org/Team:Tsinghua-A/Project/Scalability">readmore</a></p>
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Latest revision as of 20:25, 26 October 2012

Tsinghua-A::Project

Abstract

Biological parts ,one of the most important tools in the research of synthetic biology ,have been designed ,created and documented in large numbers, most of which ,however, lack scalability. To be more precise, the scalability of a biological part refers to its ability of handling of expanding scale of input and output and the ability of expansion in function. In our project, we aim to demonstrate that a scalable biological part could be devised through proper arrangement of certain sequences in the presence of some protein. We resort to an scalable electronic component ,PLD or Programmable Logic Device in this project. The definition of PLD from Wikipedia is quoted as below:” A programmable logic device or PLD is an electronic component used to build reconfigurable digital circuits. Unlike a logic gate, which has a fixed function, a PLD has an undefined function at the time of manufacture. Before the PLD can be used in a circuit it must be programmed, that is, reconfigured.” That is, digital systems could be integrated to it at will through computer programming by the user, instead of producing an electronic component with a fixed function. Actually, we have constructed a biological part that functions as a PLD, though primitive. The most basic elements in digital circuits are the AND gate and OR gate. We resort to Cre/LoxP system to enable the biological part with the ability to interchange between AND gate and OR gate by regulation of the concentration of the protein Cre.readmore

Design

With the help of site-specific recombination, we manage to change the logic from the physical layer. To a further step, we design a system whose logic changes between AND and OR.readmore

Scalability

We can transform AND gate into OR gate through a flip of the sequence between opposite loxP sites. Moreover, based on a similar idea, our system shows a strong scalability in further design.readmore