Team:Bologna

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The aim of our project is the design of a new device to control the synthesis of any protein of interest. This "general-purpose" standard device, implemented in <i>E. coli</i>, acts at the translational level to allow a switch in protein expression faster than transcriptional promoter regulation. We named this device <b>T-REX</b> (<b>T</b>rans <b>R</b>epressor of <b>EX</b>pression).  
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The aim of our project is the design of a standard device to control the synthesis of any protein of interest. This "general-purpose" device, implemented in <i>E. coli</i>, acts at the translational level to allow silencing of protein expression faster than using regulated promoters. We named this device <b>T-REX</b> (<b>T</b>rans <b>R</b>epressor of <b>EX</b>pression).  
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CIS-repressing and TRANS-repressor sequences were designed by [[Team:Bologna/Software#1|BASER]] software.
CIS-repressing and TRANS-repressor sequences were designed by [[Team:Bologna/Software#1|BASER]] software.
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Transcription of the target gene yields a mRNA strand - containing the CIS-repressing sequence at its 5' end - available for translation into protein by ribosomes (<i>see Fig. 1, right panel</i>). Induction of the promoter controlling the TRANS coding sequence, releases a transcript complementary to the CIS mRNA sequence. The TRANS/CIS <b>RNA duplex</b> prevents ribosomes from binding to RBS on target mRNA, thus <b>repressing protein synthesis</b>. The amount of the TRANS-repressor regulates the rate of translation of the target mRNA (<i>see Fig. 1, left panel</i>)
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Transcription of the target gene yields a mRNA strand - containing the CIS-repressing sequence at its 5' end - available for translation into protein by ribosomes (<i>see Fig. 1, right panel</i>). When the promoter controlling the TRANS coding sequence is active, it drives the transcription of an oligoribonucleotide complementary to the CIS mRNA sequence. The TRANS/CIS <b>RNA duplex</b> prevents ribosomes from binding to RBS on target mRNA, thus <b>silencing protein synthesis</b>. The amount of the TRANS-repressor regulates the rate of translation of the target mRNA (<i>see Fig. 1, left panel</i>)
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[[Image:project3b.png|center|950px|thumb|<center>Figure 1 - T-REX device</center>]]
[[Image:project3b.png|center|950px|thumb|<center>Figure 1 - T-REX device</center>]]

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Project Summary


Our idea

The aim of our project is the design of a standard device to control the synthesis of any protein of interest. This "general-purpose" device, implemented in E. coli, acts at the translational level to allow silencing of protein expression faster than using regulated promoters. We named this device T-REX (Trans Repressor of EXpression).


How T-REX works


The device consists of two new BioBricks:

  • CIS-repressing, to be assembled upstream of the target coding sequence.
  • TRANS-repressor, complementary to the CIS-repressing and placed under the control of a different promoter.

CIS-repressing and TRANS-repressor sequences were designed by BASER software.

Transcription of the target gene yields a mRNA strand - containing the CIS-repressing sequence at its 5' end - available for translation into protein by ribosomes (see Fig. 1, right panel). When the promoter controlling the TRANS coding sequence is active, it drives the transcription of an oligoribonucleotide complementary to the CIS mRNA sequence. The TRANS/CIS RNA duplex prevents ribosomes from binding to RBS on target mRNA, thus silencing protein synthesis. The amount of the TRANS-repressor regulates the rate of translation of the target mRNA (see Fig. 1, left panel)

Figure 1 - T-REX device



How we can test the device


In order to test and characterize our T-REX device, we developed the following genetic circuit (Fig 2):

Figure 2 - Genetic Circuit




More details about our work are reported in the Project section.


Acknowledgements



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