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In hope of ~~putting more values in~~ our biological heating device, we strive to improving the sensitivity of our sensor － the cold shock promoter. This final goal can be break down on two parts: 1. tuning the temperature-responsive range of cold shock promoter 2. amplifying its signal under low temperature. In order to understand what kind of structure of a genetic circuit and what kinds of characteristics of activator and repressor are needed for our purpose, we create several mathematical models to explore the problem. In the end, we expect to get some useful information as a guidance to screen possible biological parts when we actually start to construct the genetic circuit.

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In hope of ?? the value of our biological heating device, we strive to improving the sensitivity of our sensor － the cold shock promoter. This final goal can be break down on two parts: 1. tuning the temperature-responsive range of cold shock promoter 2. amplifying its signal under low temperature. In order to understand what kind of structure of a genetic circuit and what kinds of characteristics of activator and repressor are needed for our purpose, we create several mathematical models to explore the problem. In the end, we expect to get some useful information as a guidance to screen possible biological parts when we actually start to construct the genetic circuit.

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<div class="col-md-11" style="margin-top: 10px"><p>We predicted the Tir-1 promoter should be at about 1000 base pairs upstream, so we tried to amplified the Tir-1 promoter sequence from Saccharomyces cerevisiae by PCR. We design the primer with expanded restriction enzyme sites and about 30 base pairs complementary to the S.c. genome sequence, preventing from non-specific product. However, it’s harder to PCR a sequence from genomic DNA than plasmid. In hence, we tried different annealing temperature to make sure we have target product and decrease non-specific band.</p></div>

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<p>For estimate the heat-production ability of the SrUCP in yeast. We built up a straight way to analyze it. </p>

<p>After both experimental group (pRS424-GAL1-SrUCP-TAP) and negative control group (pRS424-GAL1∆) induced by 2% galactose for 21 hours, we couldn’t find out statistical difference between control and experimental group by our first experimental method. Most of the heat production is come from the fermentation and shaking of the incubator.</p>

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<p>However, we didn’t analyze the quantity of yeasts during the experiment. We consider that the experimental group (which had been transformed SrUCP) might grow slower than the control group and then cause the result t I show below:

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<p>However, we didn’t analyze the quantity of yeasts during the experiment. We consider that the experimental group (which had been transformed SrUCP) might grow slower than the control group and then cause the result t I show below:<br/>

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Experimental: Heat(E) = Fermentation(1) + SrUCP

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Experimental: Heat(E) = Fermentation(1) + SrUCP<br/>

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Control: Heat(C) = Fermentation(2)

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Control: Heat(C) = Fermentation(2)<br/>

Because the heat of fermentation(1) is lower than fermentation(2), even if SrUCP produce heat, the total Heat(E) equal to Heat(C).

In hence, the better method to test heat production is incubate in isothermal environment or use the isothermal titration calorimetry. We will try these more precise method.

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              <p>
-                 In hope of putting more values in our biological heating device, we strive to improving the sensitivity of our sensor － the cold shock promoter. This final goal can be break down on two parts: 1. tuning the temperature-responsive range of cold shock promoter 2. amplifying its signal under low temperature. In order to understand what kind of structure of a genetic circuit and what kinds of characteristics of activator and repressor are needed for our purpose, we create several mathematical models to explore the problem. In the end, we expect to get some useful information as a guidance to screen possible biological parts when we actually start to construct the genetic circuit.
+                 In hope of ?? the value of our biological heating device, we strive to improving the sensitivity of our sensor － the cold shock promoter. This final goal can be break down on two parts: 1. tuning the temperature-responsive range of cold shock promoter 2. amplifying its signal under low temperature. In order to understand what kind of structure of a genetic circuit and what kinds of characteristics of activator and repressor are needed for our purpose, we create several mathematical models to explore the problem. In the end, we expect to get some useful information as a guidance to screen possible biological parts when we actually start to construct the genetic circuit.
              </p>
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                  <div class="container">
-                     <img class="pull-left img-responsive" src="https://static.igem.org/mediawiki/2013/d/d4/Tir1-1-1.png" alt-src="./images/result/tir1-1.png" style="margin-top: 50px" width=400>
+                     <img class="pull-left img-responsive" src="https://static.igem.org/mediawiki/2013/d/d4/Tir1-1-1.png" alt-src="./images/result/tir1-1.png" style="margin-top: 50px"width=600>
                      <img class="pull-right img-responsive" src="https://static.igem.org/mediawiki/2013/b/b1/Tir1-2.png" alt-src="./images/result/tir1-2.png" width= 500>
                      <div class="col-md-11" style="margin-top: 10px"><p>We predicted the Tir-1 promoter should be at about 1000 base pairs upstream, so we tried to amplified the Tir-1 promoter sequence from Saccharomyces cerevisiae by PCR. We design the primer with expanded restriction enzyme sites and about 30 base pairs complementary to the S.c. genome sequence, preventing from non-specific product. However, it’s harder to PCR a sequence from genomic DNA than plasmid. In hence, we tried different annealing temperature to make sure we have target product and decrease non-specific band.</p></div>
@@ Line 2,281: / Line 2,280: @@
                  <p>For estimate the heat-production ability of the SrUCP in yeast. We built up a straight way to analyze it. </p>
                  <p>After both experimental group (pRS424-GAL1-SrUCP-TAP) and negative control group (pRS424-GAL1∆) induced by 2% galactose for 21 hours, we couldn’t find out statistical difference between control and experimental group by our first experimental method. Most of the heat production is come from the fermentation and shaking of the incubator.</p>
-                 <p>However, we didn’t analyze the quantity of yeasts during the experiment. We consider that the experimental group (which had been transformed SrUCP) might grow slower than the control group and then cause the result t I show below:
+                 <p>However, we didn’t analyze the quantity of yeasts during the experiment. We consider that the experimental group (which had been transformed SrUCP) might grow slower than the control group and then cause the result t I show below:<br/>
-                     Experimental: Heat(E) = Fermentation(1) + SrUCP
+                     Experimental: Heat(E) = Fermentation(1) + SrUCP<br/>
-                     Control: Heat(C) = Fermentation(2)
+                     Control: Heat(C) = Fermentation(2)<br/>
                      Because the heat of fermentation(1) is lower than fermentation(2), even if SrUCP produce heat, the total Heat(E) equal to Heat(C).
                      In hence, the better method to test heat production is incubate in isothermal environment or use the isothermal titration calorimetry. We will try these more precise method.

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Revision as of 04:05, 28 September 2013