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Team:OUC-China
From 2012.igem.org
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<div id="da-slider" class="da-slider"> | <div id="da-slider" class="da-slider"> | ||
<div class="da-slide"> | <div class="da-slide"> | ||
| - | <h2 >Overview</h2> | + | <h2 style="border-bottom:none;">Overview</h2> |
<p>The sensors for next-generation detector of red tide!</p> | <p>The sensors for next-generation detector of red tide!</p> | ||
<a href="" class="da-link">Read more</a> | <a href="" class="da-link">Read more</a> | ||
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</div> | </div> | ||
<div class="da-slide"> | <div class="da-slide"> | ||
| - | <h2>Sensor</h2> | + | <h2 style="border-bottom:none;">Sensor</h2> |
<p>The sensors for next-generation detector of red tide!</p> | <p>The sensors for next-generation detector of red tide!</p> | ||
<a href="https://2012.igem.org/Team:OUC-China/Project/Sensor/AbstractandBackground" class="da-link">Read more</a> | <a href="https://2012.igem.org/Team:OUC-China/Project/Sensor/AbstractandBackground" class="da-link">Read more</a> | ||
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</div> | </div> | ||
<div class="da-slide"> | <div class="da-slide"> | ||
| - | <h2>Model-Driven Design</h2> | + | <h2 style="border-bottom:none;">Model-Driven Design</h2> |
<p> | <p> | ||
Parameter optimization in ternary system... | Parameter optimization in ternary system... | ||
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</div> | </div> | ||
<div class="da-slide"> | <div class="da-slide"> | ||
| - | <h2>Making decision through sRNA</h2> | + | <h2 style="border-bottom:none;">Making decision through sRNA</h2> |
<p>The sophisticated 'CPU' of our red tide detector...<br/> | <p>The sophisticated 'CPU' of our red tide detector...<br/> | ||
Engineering CPU for your own "synthia"!</p> | Engineering CPU for your own "synthia"!</p> | ||
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<section id="project_step"> | <section id="project_step"> | ||
<div class="moduletable"> | <div class="moduletable"> | ||
| - | <h3>Our Project</h3> | + | <h3 style="border-bottom:none;">Our Project</h3> |
<div> | <div> | ||
<ul id="tab"> | <ul id="tab"> | ||
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<div class="tup"><img src="https://static.igem.org/mediawiki/2012/3/3a/Ouc-home-step1-2.png" /></div> | <div class="tup"><img src="https://static.igem.org/mediawiki/2012/3/3a/Ouc-home-step1-2.png" /></div> | ||
<div class="nr"> | <div class="nr"> | ||
| - | <h1>Step 1</h1> | + | <h1 style="border-bottom:none;">Step 1</h1> |
<p>Our phosphate- and nitrate-sensitive devices are responsible for detection of environmental phosphate and nitrate. Besides that they transform the input signals into "readable information" for decision-making devices.</p> | <p>Our phosphate- and nitrate-sensitive devices are responsible for detection of environmental phosphate and nitrate. Besides that they transform the input signals into "readable information" for decision-making devices.</p> | ||
<p>much work has been done for characterization and modification of nitrate- and phosphate-sensitive promoters. A whole set of design ideas for TCS modifications are also presented for other igemers. Additionally an actuator that can remove the phosphate is recommended.</p> | <p>much work has been done for characterization and modification of nitrate- and phosphate-sensitive promoters. A whole set of design ideas for TCS modifications are also presented for other igemers. Additionally an actuator that can remove the phosphate is recommended.</p> | ||
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<div class="tup"><img src="https://static.igem.org/mediawiki/2012/a/a1/Ouc-home-step3-02.png" /></div> | <div class="tup"><img src="https://static.igem.org/mediawiki/2012/a/a1/Ouc-home-step3-02.png" /></div> | ||
<div class="nr"> | <div class="nr"> | ||
| - | <h1>Step2</h1> | + | <h1 style="border-bottom:none;">Step2</h1> |
<p>Our decision-making device aims at processing the concentration change of nitrate or phosphate into visible buoyancy increase. Comparator recognizes the difference of two inputs quantitatively ,while ratio sensor could senses a particular ratio between two inputs.</p> | <p>Our decision-making device aims at processing the concentration change of nitrate or phosphate into visible buoyancy increase. Comparator recognizes the difference of two inputs quantitatively ,while ratio sensor could senses a particular ratio between two inputs.</p> | ||
<p>Both comparator and ratio sensor facilitate a ternary system consisted of two small RNA and GFP mRNA. The concentration change of external two inducers leads to the transcription rate change of small RNA(alpha s)in this ternary system, the interactions between three RNAs will lead to interesting behaviors of our system like sensing the difference between two inputs quantitatively(Comparator) or the ratio of two inputs(Ratio senor).</p> | <p>Both comparator and ratio sensor facilitate a ternary system consisted of two small RNA and GFP mRNA. The concentration change of external two inducers leads to the transcription rate change of small RNA(alpha s)in this ternary system, the interactions between three RNAs will lead to interesting behaviors of our system like sensing the difference between two inputs quantitatively(Comparator) or the ratio of two inputs(Ratio senor).</p> | ||
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<div class="tup"><img src="https://static.igem.org/mediawiki/2012/f/fa/Ouc-step3-last.png" /></div> | <div class="tup"><img src="https://static.igem.org/mediawiki/2012/f/fa/Ouc-step3-last.png" /></div> | ||
<div class="nr"> | <div class="nr"> | ||
| - | <h1>Step3</h1> | + | <h1 style="border-bottom:none;">Step3</h1> |
<p>In our project, by transforming the buoyancy device BBa_K737010, the gas vesicle cluster from the genome of Planktothrix rubescens into E.Coli, we succeed in making Escherichia.Coli floating on the surface of the water. It can help the cells produce the gas vesicle inside, which could make densities significant stratification in the culture. Not only the gene cluster but the two parts BBa_K737006 and BBa_K737007, which produce the gas vesicle structure protein, can also make the Escherichia.Coli floating. We use the shorter length of the part achieve a better effect than BBa_K190033 and the gas vesicle application prospect.</p> | <p>In our project, by transforming the buoyancy device BBa_K737010, the gas vesicle cluster from the genome of Planktothrix rubescens into E.Coli, we succeed in making Escherichia.Coli floating on the surface of the water. It can help the cells produce the gas vesicle inside, which could make densities significant stratification in the culture. Not only the gene cluster but the two parts BBa_K737006 and BBa_K737007, which produce the gas vesicle structure protein, can also make the Escherichia.Coli floating. We use the shorter length of the part achieve a better effect than BBa_K190033 and the gas vesicle application prospect.</p> | ||
<p><a href="https://2012.igem.org/Team:OUC-China/Project/GVP/GasandBackground"><strong>learn more</strong></a> | <p><a href="https://2012.igem.org/Team:OUC-China/Project/GVP/GasandBackground"><strong>learn more</strong></a> | ||
Revision as of 03:30, 27 September 2012
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Project Overview
-
HumanPractice Overview
-
JudgingForm
-
Contact Us
Project Overview
Sensor
Decision-making Device
Gas vesicle
ODEModel
Parameter Sensitivity Analysis
Parameter Sweep
Noise Analysis
HumanPractice Overview
Meeting and Academic Communication
Camps, Class and Lectures
Special HP
Team Members
Instructors
Acknowledgement and Cooperation
Lab
Parts
Safety
Labnote
Modeling Note
ProtocolS
Making decision through sRNA
The sophisticated 'CPU' of our red tide detector...
Engineering CPU for your own "synthia"!
Oceanfloat and Oceanfeel
----a floating biosenser
Our Project
step 1
step 2
step 3
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Step 1
Our phosphate- and nitrate-sensitive devices are responsible for detection of environmental phosphate and nitrate. Besides that they transform the input signals into "readable information" for decision-making devices.
much work has been done for characterization and modification of nitrate- and phosphate-sensitive promoters. A whole set of design ideas for TCS modifications are also presented for other igemers. Additionally an actuator that can remove the phosphate is recommended.
-
Step2
Our decision-making device aims at processing the concentration change of nitrate or phosphate into visible buoyancy increase. Comparator recognizes the difference of two inputs quantitatively ,while ratio sensor could senses a particular ratio between two inputs.
Both comparator and ratio sensor facilitate a ternary system consisted of two small RNA and GFP mRNA. The concentration change of external two inducers leads to the transcription rate change of small RNA(alpha s)in this ternary system, the interactions between three RNAs will lead to interesting behaviors of our system like sensing the difference between two inputs quantitatively(Comparator) or the ratio of two inputs(Ratio senor).
-
Step3
In our project, by transforming the buoyancy device BBa_K737010, the gas vesicle cluster from the genome of Planktothrix rubescens into E.Coli, we succeed in making Escherichia.Coli floating on the surface of the water. It can help the cells produce the gas vesicle inside, which could make densities significant stratification in the culture. Not only the gene cluster but the two parts BBa_K737006 and BBa_K737007, which produce the gas vesicle structure protein, can also make the Escherichia.Coli floating. We use the shorter length of the part achieve a better effect than BBa_K190033 and the gas vesicle application prospect.
