Team:Alberta/Project/Promoters & Terminators

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     <h1>Promoter and Terminator Design</h1>
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<h3> Why Promoter and Terminator design? </h3>
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<p> Our project tests the limits to which biology can be standardized. Towards this goal, the endogenous promoter of every essential gene will be replaced with one of seven standard promoters producing different expression levels. The terminator of every essential gene will also be replaced with a standard biobrick terminator. The promoters and terminators are biobrick parts and are currently being functionally tested. To determine which promoter to pair with which gene, microarray expression data from the literature was used. </P>
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<p> Our project tests the limits to which biology can be standardized. Towards this goal, the endogenous promoter of every essential gene will be replaced with one of seven standard promoters producing different expression levels. The promoters are biobrick parts and are currently being functionally tested. To determine which promoter to pair with which gene, microarray expression data from the literature was used. The terminator of every essential gene will also be replaced with a standard biobrick terminator. </P>
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<b>Advantages of standardized promoters include:</b>
<b>Advantages of standardized promoters include:</b>
<ul>
<ul>
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<li> streamlined amplifaction of genes from genomic DNA, as amplicons can all start precisely at the start codon </li>
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<li> streamlined amplification of genes from genomic DNA, as amplicons can all start precisely at the start codon. No data about where the endogenous promoter begins is required. </li>
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< potential for easy manipulation of gene expression levels: the same gene part can easily be assembled with different promoters to test the effect of different expression levels </li>
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<li> potential for easy manipulation of gene expression levels: the same gene part can easily be assembled with different promoters to test the effect of different expression levels. </li>
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<li> no concerns about which transcription factors need to be retained in the essential gene list to ensure essential genes are transcibed </li>
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<li> we need not be concerned about including all the transcription factors need to express the essential genes. </li>
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<li> as the location and properties of many enhancers are unknown, using all standardize promoters results in a much better characterized, well understood system, which is more amenabel to alteration </li>
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<li> as the location and properties of many promoters are unknown, using all standardized promoters results in a much better characterized system that is more amenable to manipulation. </li>
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    <h1>Promoters</h1>
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<p>The standardized promoters were based from a series of promoters produced by the 2006 Berkeley iGEM team.  These are a series of promoters which have been mutated from the consensus sigma 70 promoter allowing for varying levels of promoter activity to be produced.  The promoters can be found <a href="http://partsregistry.org/wiki/index.php?title=Part:BBa_J23100"> here </a>.  The following promoters were selected:
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<ul>
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<li>J23119 - Sigma 70 Consensus Sequence
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<li>J23102 - Sigma 70 75% Strength Promoter
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<li>J23118 - Sigma 70 50% Strength Promoter
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<li>J23105 - Sigma 70 25% Strength Promoter
 +
<li>J23114 - Sigma 70 10% Strength Promoter
 +
<li>J23113 - Sigma 70 1% Strength Promoter
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</ul>
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 +
    These promoters were tested by the Anderson group by construction of J61002.  This plasmid consists of the promoter of interest, the RFP gene, and a double terminator.  By measuring the amount of fluorescence produced by each promoter, it is possible to determine the promoter's strength.  Unfortunately, the strength of the consensus promoter was not measured.  Therefore it was assigned a fluorescence of 2900 based on the rate of decrease in fluorescence per base pair mutation.  In order to confirm the strength of each promoter, we are presently in the process of testing our new BioByte promoters (see below for more details on other alterations made to each promoter) using the same experimental procedure as the Anderson Group.</p>
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    <h1>Terminator</h1>
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<p>The part which was used as the universal terminator in our standardized parts list was Bba b1006.  This is a bidirectional terminator with 6 nucleotide loop and 8 bp stem which has been shown to terminate transcription 99% of the time (Please see <a href="http://partsregistry.org/Help:Terminators/Measurement/Cassie_Huang"> here </a> for terminator characterization information).  The sequence of the terminator is:
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<center><h3>AAAAAAAACCCCGCCCCTGACAGGGCGGGGTTTTTTTT</h3>
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    <h1>Modifications To Promoters and Terminators</h1>
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<p>Alterations were made to the Anderson collection promoters to allow for use with the BioBytes assembly system.  Two restriction sites were removed, and two nucleotides were added to slightly alter the start site of transcription.  Both the promoters and terminators had a PstI and XbaI site added allowing for insertion into pAB or pBA.  Please see the attached document <a href="https://2009.igem.org/Image:UofA_Promoter_Terminator.zip"> here </a> for sequence information regarding the modified promoters and terminators.
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    <h1>Microarray Determination of Standardized Promoters</h1>
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<p>With a series of standardized promoters and a list of essential genes it is important to be able to compare these to one another and assign the appropriate promoter to each gene.  In order to accomplish this, microarray data was used for the <i>E. coli</i> genome under aerobic conditions.  The <a href="https://2009.igem.org/Image:UofA_Covert.pdf"> Covert et al 2004</a> paper was used to determine this information.  They looked at a series of gene knockouts under a variety of media conditions and determined the level of transcript for 1010 metabolic genes during the growth phase of the organism.  We used the WT data determined a level of each gene's transcript and used this to assign individual promoters to the genes.  A list of the literature essential genes with their promoter levels can be found <a href="https://2009.igem.org/Image:UofA_MicroarrayData.xls"> here </a>.</p>
 +
<p>These results however are not complete since there are many variables which need to be considered in order to ensure the correct level of transcript is produced.  Further research will be required to see the effects of different cellular stages and conditions.</p>
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Latest revision as of 00:30, 22 October 2009

University of Alberta - BioBytes










































































































Promoter and Terminator Design

Our project tests the limits to which biology can be standardized. Towards this goal, the endogenous promoter of every essential gene will be replaced with one of seven standard promoters producing different expression levels. The terminator of every essential gene will also be replaced with a standard biobrick terminator. The promoters and terminators are biobrick parts and are currently being functionally tested. To determine which promoter to pair with which gene, microarray expression data from the literature was used.

Advantages of standardized promoters include:
  • streamlined amplification of genes from genomic DNA, as amplicons can all start precisely at the start codon. No data about where the endogenous promoter begins is required.
  • potential for easy manipulation of gene expression levels: the same gene part can easily be assembled with different promoters to test the effect of different expression levels.
  • we need not be concerned about including all the transcription factors need to express the essential genes.
  • as the location and properties of many promoters are unknown, using all standardized promoters results in a much better characterized system that is more amenable to manipulation.

Promoters

The standardized promoters were based from a series of promoters produced by the 2006 Berkeley iGEM team. These are a series of promoters which have been mutated from the consensus sigma 70 promoter allowing for varying levels of promoter activity to be produced. The promoters can be found here . The following promoters were selected:

  • J23119 - Sigma 70 Consensus Sequence
  • J23102 - Sigma 70 75% Strength Promoter
  • J23118 - Sigma 70 50% Strength Promoter
  • J23105 - Sigma 70 25% Strength Promoter
  • J23114 - Sigma 70 10% Strength Promoter
  • J23113 - Sigma 70 1% Strength Promoter
These promoters were tested by the Anderson group by construction of J61002. This plasmid consists of the promoter of interest, the RFP gene, and a double terminator. By measuring the amount of fluorescence produced by each promoter, it is possible to determine the promoter's strength. Unfortunately, the strength of the consensus promoter was not measured. Therefore it was assigned a fluorescence of 2900 based on the rate of decrease in fluorescence per base pair mutation. In order to confirm the strength of each promoter, we are presently in the process of testing our new BioByte promoters (see below for more details on other alterations made to each promoter) using the same experimental procedure as the Anderson Group.

Terminator

The part which was used as the universal terminator in our standardized parts list was Bba b1006. This is a bidirectional terminator with 6 nucleotide loop and 8 bp stem which has been shown to terminate transcription 99% of the time (Please see here for terminator characterization information). The sequence of the terminator is:

AAAAAAAACCCCGCCCCTGACAGGGCGGGGTTTTTTTT

Modifications To Promoters and Terminators

Alterations were made to the Anderson collection promoters to allow for use with the BioBytes assembly system. Two restriction sites were removed, and two nucleotides were added to slightly alter the start site of transcription. Both the promoters and terminators had a PstI and XbaI site added allowing for insertion into pAB or pBA. Please see the attached document here for sequence information regarding the modified promoters and terminators.

Microarray Determination of Standardized Promoters

With a series of standardized promoters and a list of essential genes it is important to be able to compare these to one another and assign the appropriate promoter to each gene. In order to accomplish this, microarray data was used for the E. coli genome under aerobic conditions. The Covert et al 2004 paper was used to determine this information. They looked at a series of gene knockouts under a variety of media conditions and determined the level of transcript for 1010 metabolic genes during the growth phase of the organism. We used the WT data determined a level of each gene's transcript and used this to assign individual promoters to the genes. A list of the literature essential genes with their promoter levels can be found here .

These results however are not complete since there are many variables which need to be considered in order to ensure the correct level of transcript is produced. Further research will be required to see the effects of different cellular stages and conditions.