Team:XMU-China/background

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   <p class="tit" >Background  and Approach </p>
   <p class="tit" >Background  and Approach </p>
   <p> <strong class="subtitle"><a name="_Toc01"></a>1. Logic Gates</strong><br>
   <p> <strong class="subtitle"><a name="_Toc01"></a>1. Logic Gates</strong><br>
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                         A&nbsp;logic  gate&nbsp;is an idealized or physical device implementing a&nbsp;<a href="http://en.wikipedia.org/wiki/Boolean_function" title="Boolean function">Boolean function</a>, that is, it performs a <a href="http://en.wikipedia.org/wiki/Logical_operation" title="Logical operation">logical  operation</a>&nbsp;on one or more logic inputs and produces a single logic output<sup>[1]</sup> .</p>
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                         A&nbsp;logic  gate&nbsp;is an idealized or physical device implementing a&nbsp;<a href="http://en.wikipedia.org/wiki/Boolean_function" title="Boolean function">Boolean function</a>, that is, it performs a <a href="http://en.wikipedia.org/wiki/Logical_operation" title="Logical operation">logical  operation</a>&nbsp;on one or more logic inputs and produces a single logic output<sup><a href="#_ENREF_1" title="Ron Weiss, 2003 #2">[1]</a></sup> .</p>
   <p>&nbsp;</p>
   <p>&nbsp;</p>
   <table id="gatetable">
   <table id="gatetable">
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</br>
</br>
                        
                        
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                         The <strong>AIM </strong>of our project is to construct a fluorescent  digital&nbsp;display device of genetic circuits with synthetic logic gates. The  finished device will display and switch numbers. Similar to electronic  circuits, logic regulation operation in cells integrates the extracellular and  intracellular signals. We assembled several pairs of promoters and their  activators or repressors into computing building block of the circuit: <em>P<sub>BAD</sub></em>-Arabinose, <em>P<sub>cI</sub></em>-CI, and <em>P<sub>tet</sub>R</em>-TetR. These computation  units act as genetic logic gates perform AND, OR and  NOR  gate functions.&nbsp;<br>
+
                         The <strong>AIM </strong>of our project is to construct a fluorescent  digital&nbsp;display device of genetic circuits with synthetic logic gates. The  finished device will display and switch numbers. Similar to electronic  circuits, logic regulation operation in cells integrates the extracellular and  intracellular signals. We assembled several pairs of promoters and their  activators or repressors into computing building block of the circuit: <em>P<sub>BAD</sub></em>-Arabinose, <em>P<sub>cI</sub></em>-CI, and <em>P<sub>tet</sub></em>-TetR. These computation  units act as genetic logic gates perform AND, OR and  NOR  gate functions.&nbsp;<br>
   <p align="center"><img src="https://static.igem.org/mediawiki/2012/2/2e/Background_img01.jpg" alt="" width="305" height="163" ><br>
   <p align="center"><img src="https://static.igem.org/mediawiki/2012/2/2e/Background_img01.jpg" alt="" width="305" height="163" ><br>
                         (Alvin Tamsir , et al. Nature, 2011)</p>
                         (Alvin Tamsir , et al. Nature, 2011)</p>
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                       <hr>
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                       <hr><br>
                       <p> <strong class="subtitle"><a name="_Toc02"></a>2. Green Fluorescent Protein</strong><br>
                       <p> <strong class="subtitle"><a name="_Toc02"></a>2. Green Fluorescent Protein</strong><br>
-
                         The green fluorescent  protein (GFP) is a protein composed of 238 amino acid residues (26.9kDa) that  exhibits bright green fluorescence when exposed to light in the blue light wavelength range<sup>[2]</sup>. Considering that the common types of GFP usually tend to  be very stable and hard to &quot;quench&quot;, we chose unstable GFP to make  our device reusable and convert in a fast speed.  This kind of  GFP is tagged with a C-terminal extension that will be recognized  and degraded by tail-specific proteases, leading to a short half-life and fast  degradation of the protein.Degradation rate should be confined at a  suitable range; otherwise the device would either have no light or take a long  time to change numbers.<br>
+
                         The green fluorescent  protein (GFP) is a protein composed of 238 amino acid residues (26.9kDa) that  exhibits bright green fluorescence when exposed to light in the blue light wavelength range<sup><a href="#_ENREF_2" title="Ron Weiss, 2003 #2">[2]</a></sup>. Considering that the common types of GFP usually tend to  be very stable and hard to &quot;quench&quot;, we chose unstable GFP to make  our device reusable and convert in a fast speed.  This kind of  GFP is tagged with a C-terminal extension that will be recognized  and degraded by tail-specific proteases, leading to a short half-life and fast  degradation of the protein. Degradation rate should be confined at a  suitable range; otherwise the device would either have no light or take a long  time to change numbers.<br>
                       <p align="center"><img src="https://static.igem.org/mediawiki/2012/5/52/Background_img02.jpg" alt="" width="403" height="403"><br>
                       <p align="center"><img src="https://static.igem.org/mediawiki/2012/5/52/Background_img02.jpg" alt="" width="403" height="403"><br>
                         GFP crystal structure (Ormo, M., Cubitt, AB, Kallio,
                         GFP crystal structure (Ormo, M., Cubitt, AB, Kallio,
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                         <img src="https://static.igem.org/mediawiki/2012/4/4f/Background_img03.jpg" alt="" width="558" height="52"> <br>
                         <img src="https://static.igem.org/mediawiki/2012/4/4f/Background_img03.jpg" alt="" width="558" height="52"> <br>
                         (K., Gross, et al. Science, 1996) </p>
                         (K., Gross, et al. Science, 1996) </p>
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                       <hr>
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                       <hr><br>
                       <strong class="subtitle"><a name="_Toc03"></a>3. Cell  Immobilization</strong><br>
                       <strong class="subtitle"><a name="_Toc03"></a>3. Cell  Immobilization</strong><br>
                       It is a  technique to fix cells in a suitable matrix. Immobilized cells have been  employed to perform biotransformation and reported to have higher production  rates than freely suspended cells. In our project, we have selected three  methods to immobilize our engineering bacteria:
                       It is a  technique to fix cells in a suitable matrix. Immobilized cells have been  employed to perform biotransformation and reported to have higher production  rates than freely suspended cells. In our project, we have selected three  methods to immobilize our engineering bacteria:
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                      <p></p>
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    <dl><dd>(1)Entrapping  cells in calcium alginate beads; <br>
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                      <p></p>
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    (2)Entrapping  cells in intra-hollow Ca-alginate capsules; <br>
-
                      <ol>
+
    (3)Embedding cells in PDMDAAC-NaCS  microcapsules.<br>
-
                        <li>Entrapping  cells in calcium alginate beads; </li>
+
    </dd></dl>
-
                        <li>Entrapping  cells in intra-hollow Ca-alginate capsules; </li>
+
                       <hr><br>
-
                        <li> Embedding cells in PDMDAAC-NaCS  microcapsules.</li>
+
-
                      </ol>
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-
                       <hr>
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                       <p align="left"><strong class="subtitle"><a name="_Toc04"></a>4. Quorum Sensing</strong><br>
                       <p align="left"><strong class="subtitle"><a name="_Toc04"></a>4. Quorum Sensing</strong><br>
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                         It is a method of communication between bacteria that enables  the coordination of group-based behavior based on population density<sup>[3].</sup><br>
+
                         It is a method of communication between bacteria that enables  the coordination of group-based behavior based on population density<sup><a href="#_ENREF_1" title="Ron Weiss, 2003 #2">[3]</a></sup>.<br>
                       <p align="center"><img src="https://static.igem.org/mediawiki/2012/3/36/Background_img04.jpg" alt="" width="504" height="342"><br>
                       <p align="center"><img src="https://static.igem.org/mediawiki/2012/3/36/Background_img04.jpg" alt="" width="504" height="342"><br>
                         (Melissa B. Miller, et al. Annual Review of Microbiology, 2001)</p>
                         (Melissa B. Miller, et al. Annual Review of Microbiology, 2001)</p>
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                       <hr>
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                       <hr><br>
-
                       <strong class="subtitle"><a name="_Toc05"></a>5. Time Delay</strong><br>
+
                       <p><strong class="subtitle"><a name="_Toc05"></a>5. Time Delay</strong><br>
-
                       Constructing a unique  display device which can let each  unit light up one after another is beneficial for our team to accomplish the aim of  time delay, which means that it is necessary to construct a series of cells  those can express the characteristic of different time delay. As a result, we  take advantage of Quorum-sensing system to change the time delay of GFP expression via  different intensity of RBS.
+
                       Constructing a unique  display device which can let each  unit light up one after another is beneficial for our team to accomplish the aim of  time delay, which means that it is necessary to construct a series of cells  those can express the characteristic of different time delay. As a result, we  take advantage of quorum-sensing system to change the time delay of GFP expression via  different intensity of RBS.</p>
-
                      <p></p>
+
                       <hr><br>
-
                       <hr>
+
                       <p><strong class="subtitle"><a name="_Toc06"></a>6. Original  Design</strong><br>
                       <p><strong class="subtitle"><a name="_Toc06"></a>6. Original  Design</strong><br>
                         In reality, we selected this project from the first brainstorm which was  put forward by the members of Group 2 and its previous name was Bioscreen, as  you see, which turned to be E.lumoli nowadays. To gain more details about the  original task, please link to: </p>
                         In reality, we selected this project from the first brainstorm which was  put forward by the members of Group 2 and its previous name was Bioscreen, as  you see, which turned to be E.lumoli nowadays. To gain more details about the  original task, please link to: </p>
-
                       <p><a href="https://2012.igem.org/Template:Team:XMU-China/brainstorm#_Toc02">Brainstorm: Contents: Group 2: Bioscreen</a><u> </u></p>
+
                       <p><a href="https://2012.igem.org/Team:XMU-China/brainstorm#_Toc02">Brainstorm: Contents: Group 2: Bioscreen</a><u> </u></p>
-
                       <hr>
+
                       <hr><br>
                       <p><strong class="subtitle"><a name="_Toc07"></a>7. Project Overview</strong><br>
                       <p><strong class="subtitle"><a name="_Toc07"></a>7. Project Overview</strong><br>
                         Under  usual condition, traditional seven-segment displays acted as a  number &ldquo;8&rdquo; need 7 tubes. Through different combinations of the tubes, the  device can display different numbers or characters. Actually most modern  displays are controlled by electric signals which are converted by chemical or  biological signals. But in several situations, especially in detect of trace  amounts or minute amounts of biological signals, we found that it is difficult  to transfer and display the results. Besides, the relevant parameters which are  controlled in real time in some fields of industrial application are hard to be  the same as the reality. The aim of our project is to design a shining&nbsp;synthetic  device&nbsp;for&nbsp;digit&nbsp;or time-course display which can replace the  traditional methods. </p>
                         Under  usual condition, traditional seven-segment displays acted as a  number &ldquo;8&rdquo; need 7 tubes. Through different combinations of the tubes, the  device can display different numbers or characters. Actually most modern  displays are controlled by electric signals which are converted by chemical or  biological signals. But in several situations, especially in detect of trace  amounts or minute amounts of biological signals, we found that it is difficult  to transfer and display the results. Besides, the relevant parameters which are  controlled in real time in some fields of industrial application are hard to be  the same as the reality. The aim of our project is to design a shining&nbsp;synthetic  device&nbsp;for&nbsp;digit&nbsp;or time-course display which can replace the  traditional methods. </p>
                       <p>Fortunately,  2012 XMU iGEM team has constructed a fluorescent  digital&nbsp;display device with synthetic logic gates,&nbsp;which is able to respond  to signals by displaying and switching numbers. We put GFP equipped with  degradation tags in downstream to illuminate our numbers and change them  quickly as well. Considering our engineering background, we  accordingly employ cell immobilization to build our device. Engineering  bacteria have been embedded in intra-hallow calcium alginate microcapsules and  in PDMDAAC-NaCS microcapsules respectively. In addition, 3D CAD design is performed  for a perfect device.</p>
                       <p>Fortunately,  2012 XMU iGEM team has constructed a fluorescent  digital&nbsp;display device with synthetic logic gates,&nbsp;which is able to respond  to signals by displaying and switching numbers. We put GFP equipped with  degradation tags in downstream to illuminate our numbers and change them  quickly as well. Considering our engineering background, we  accordingly employ cell immobilization to build our device. Engineering  bacteria have been embedded in intra-hallow calcium alginate microcapsules and  in PDMDAAC-NaCS microcapsules respectively. In addition, 3D CAD design is performed  for a perfect device.</p>
                       <p>Our  genetic circuits vary in length and RBS strength, leading to different durations  of time delay for GFP expression which inspired us to extend our work of 2011  XMU iGEM team. By altering the strength of RBS at five grades, another five  circuits have been built.Once induced by arabinose, the duration of response  time for GFP expression increases as the strength of RBS declines, bringing  about a time-course display.</p>
                       <p>Our  genetic circuits vary in length and RBS strength, leading to different durations  of time delay for GFP expression which inspired us to extend our work of 2011  XMU iGEM team. By altering the strength of RBS at five grades, another five  circuits have been built.Once induced by arabinose, the duration of response  time for GFP expression increases as the strength of RBS declines, bringing  about a time-course display.</p>
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                       <hr>
+
                       <hr><br>
                       <p><strong class="subtitle"><a name="_Toc08"></a>8. References</strong><br>
                       <p><strong class="subtitle"><a name="_Toc08"></a>8. References</strong><br>
-
                         [1] <a href="http://en.wikipedia.org/wiki/Logic_gate">http://en.wikipedia.org/wiki/Logic_gate</a></p>
+
                         <a name="_ENREF_1" id="_ENREF_1">[1] <a href="http://en.wikipedia.org/wiki/Logic_gate">http://en.wikipedia.org/wiki/Logic_gate</a></a></p>
-
                       <p>[2] <a href="http://en.wikipedia.org/wiki/Green_fluorescent_protein">http://en.wikipedia.org/wiki/Green_fluorescent_protein</a></p>
+
                       <p><a name="_ENREF_2" id="_ENREF_2">[2] <a href="http://en.wikipedia.org/wiki/Green_fluorescent_protein">http://en.wikipedia.org/wiki/Green_fluorescent_protein</a></a></p>
-
                       <p>[3] Eberhard A, Burlingame A. L,  Eberhard C, Kenyon G. L, Nealson K. H, Oppenheimer N. J. Structural  identification of autoinducer of Photobacterium fischeri luciferase[J].  Biochemistry, 1981, 20 (9): 2444&ndash;2449.<strong> </strong></p>
+
                       <p><a name="_ENREF_3" id="_ENREF_3">[3] Eberhard A, Burlingame A. L,  Eberhard C, Kenyon G. L, Nealson K. H, Oppenheimer N. J. Structural  identification of autoinducer of Photobacterium fischeri luciferase[J].  <em>Biochemistry</em>, <strong>1981</strong>, <em>20</em> (9): 2444&ndash;2449.</a></p>
                      
                      
        
        

Latest revision as of 19:51, 26 September 2012

XMU-CSS

XMU

backgroundindex

Contents[hide][show]
  • Logic gate
  • Green Fluorescent Protein
  • Cell immobilization
  • Quorum Sensing
  • Time delay
  • Original Design
  • Project Overview
  • References
  • XMU-BACKGROUND

    Background and Approach

    1. Logic Gates
    A logic gate is an idealized or physical device implementing a Boolean function, that is, it performs a logical operation on one or more logic inputs and produces a single logic output[1] .

     

    AND gate

    INPUT

    OUTPUT

    A

    B

    0

    0

    0

    0

    1

    0

    1

    0

    0

    1

    1

    1

    OR gate

    INPUT

    OUTPUT

    A

    B

    0

    0

    0

    0

    1

    1

    1

    0

    1

    1

    1

    1


    The AIM of our project is to construct a fluorescent digital display device of genetic circuits with synthetic logic gates. The finished device will display and switch numbers. Similar to electronic circuits, logic regulation operation in cells integrates the extracellular and intracellular signals. We assembled several pairs of promoters and their activators or repressors into computing building block of the circuit: PBAD-Arabinose, PcI-CI, and Ptet-TetR. These computation units act as genetic logic gates perform AND, OR and NOR gate functions. 


    (Alvin Tamsir , et al. Nature, 2011)



    2. Green Fluorescent Protein
    The green fluorescent protein (GFP) is a protein composed of 238 amino acid residues (26.9kDa) that exhibits bright green fluorescence when exposed to light in the blue light wavelength range[2]. Considering that the common types of GFP usually tend to be very stable and hard to "quench", we chose unstable GFP to make our device reusable and convert in a fast speed. This kind of GFP is tagged with a C-terminal extension that will be recognized and degraded by tail-specific proteases, leading to a short half-life and fast degradation of the protein. Degradation rate should be confined at a suitable range; otherwise the device would either have no light or take a long time to change numbers.


    GFP crystal structure (Ormo, M., Cubitt, AB, Kallio, K., Gross, LA, Tsien, RY, Remington, SJ (1996) Science 273, 1392–1395)

    (K., Gross, et al. Science, 1996)



    3. Cell Immobilization
    It is a technique to fix cells in a suitable matrix. Immobilized cells have been employed to perform biotransformation and reported to have higher production rates than freely suspended cells. In our project, we have selected three methods to immobilize our engineering bacteria:
    (1)Entrapping cells in calcium alginate beads;
    (2)Entrapping cells in intra-hollow Ca-alginate capsules;
    (3)Embedding cells in PDMDAAC-NaCS microcapsules.


    4. Quorum Sensing
    It is a method of communication between bacteria that enables the coordination of group-based behavior based on population density[3].


    (Melissa B. Miller, et al. Annual Review of Microbiology, 2001)



    5. Time Delay
    Constructing a unique display device which can let each unit light up one after another is beneficial for our team to accomplish the aim of time delay, which means that it is necessary to construct a series of cells those can express the characteristic of different time delay. As a result, we take advantage of quorum-sensing system to change the time delay of GFP expression via different intensity of RBS.



    6. Original Design
    In reality, we selected this project from the first brainstorm which was put forward by the members of Group 2 and its previous name was Bioscreen, as you see, which turned to be E.lumoli nowadays. To gain more details about the original task, please link to:

    Brainstorm: Contents: Group 2: Bioscreen



    7. Project Overview
    Under usual condition, traditional seven-segment displays acted as a number “8” need 7 tubes. Through different combinations of the tubes, the device can display different numbers or characters. Actually most modern displays are controlled by electric signals which are converted by chemical or biological signals. But in several situations, especially in detect of trace amounts or minute amounts of biological signals, we found that it is difficult to transfer and display the results. Besides, the relevant parameters which are controlled in real time in some fields of industrial application are hard to be the same as the reality. The aim of our project is to design a shining synthetic device for digit or time-course display which can replace the traditional methods.

    Fortunately, 2012 XMU iGEM team has constructed a fluorescent digital display device with synthetic logic gates, which is able to respond to signals by displaying and switching numbers. We put GFP equipped with degradation tags in downstream to illuminate our numbers and change them quickly as well. Considering our engineering background, we accordingly employ cell immobilization to build our device. Engineering bacteria have been embedded in intra-hallow calcium alginate microcapsules and in PDMDAAC-NaCS microcapsules respectively. In addition, 3D CAD design is performed for a perfect device.

    Our genetic circuits vary in length and RBS strength, leading to different durations of time delay for GFP expression which inspired us to extend our work of 2011 XMU iGEM team. By altering the strength of RBS at five grades, another five circuits have been built.Once induced by arabinose, the duration of response time for GFP expression increases as the strength of RBS declines, bringing about a time-course display.



    8. References
    [1] http://en.wikipedia.org/wiki/Logic_gate

    [2] http://en.wikipedia.org/wiki/Green_fluorescent_protein

    [3] Eberhard A, Burlingame A. L, Eberhard C, Kenyon G. L, Nealson K. H, Oppenheimer N. J. Structural identification of autoinducer of Photobacterium fischeri luciferase[J]. Biochemistry, 1981, 20 (9): 2444–2449.