Team:USTC-China

From 2012.igem.org

(Difference between revisions)
Line 126: Line 126:
<h3>WELCOME!</h3>
<h3>WELCOME!</h3>
<hr/>
<hr/>
-
<img src="https://static.igem.org/mediawiki/2012/8/84/Project_overview.jpg" style="float:right;width:300px;height:225px;margin:15px;"  />
+
<a href="https://static.igem.org/mediawiki/2012/8/84/Project_overview.jpg"><img src="https://static.igem.org/mediawiki/2012/8/84/Project_overview.jpg" style="float:right;width:300px;height:225px;margin:15px;"  /></a>
<p class="project">Bacteriophage is one of the most severe threats the fermentation factories have to face. To help solve the problem, we design a gene circuit which can both detect and defend against the phages. We use the modified promoter pRM to sense the phage’s infection and initiate the defence. The lysis gene which can make bacteria lyse is installed in our circuit. When it works, the phage won’t be able to take advantage of its host to replicate any longer. To win more time for lysis to function well, we design antisense RNA to prevent the phage from turning into lytic life cycle. Thus, when the lysis protein kills the host, the phage is still at lysogenic life cycle or the newly assembled phages are still immature. By using the quorum sensing system, the bacteria around the host will prepare to defend in advance. Attribute to these parts, our bacteria survive.</p>  
<p class="project">Bacteriophage is one of the most severe threats the fermentation factories have to face. To help solve the problem, we design a gene circuit which can both detect and defend against the phages. We use the modified promoter pRM to sense the phage’s infection and initiate the defence. The lysis gene which can make bacteria lyse is installed in our circuit. When it works, the phage won’t be able to take advantage of its host to replicate any longer. To win more time for lysis to function well, we design antisense RNA to prevent the phage from turning into lytic life cycle. Thus, when the lysis protein kills the host, the phage is still at lysogenic life cycle or the newly assembled phages are still immature. By using the quorum sensing system, the bacteria around the host will prepare to defend in advance. Attribute to these parts, our bacteria survive.</p>  

Revision as of 13:19, 25 September 2012

WELCOME TO THE WIKI OF USTC-CHINA IGEM TAEM! ENJOY YOUR EXPLORATION!

PARTS

This summer we have contributed 21 parts to the partsregistry!

MODELING

We have theoretically analysed our system through Mathematical Modeling!

OUTREACH

Our team have conducted several activities for public recognition of synthetic biology!

SAFETY

The project is considered to have the minimal risks!

TEAM

Members in USTC_China enjoyed themselves this summer!

WELCOME!


Bacteriophage is one of the most severe threats the fermentation factories have to face. To help solve the problem, we design a gene circuit which can both detect and defend against the phages. We use the modified promoter pRM to sense the phage’s infection and initiate the defence. The lysis gene which can make bacteria lyse is installed in our circuit. When it works, the phage won’t be able to take advantage of its host to replicate any longer. To win more time for lysis to function well, we design antisense RNA to prevent the phage from turning into lytic life cycle. Thus, when the lysis protein kills the host, the phage is still at lysogenic life cycle or the newly assembled phages are still immature. By using the quorum sensing system, the bacteria around the host will prepare to defend in advance. Attribute to these parts, our bacteria survive.

SPONSORS