Team:Amsterdam/project/molecular design

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__NOTOC__
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<center>'''Click on one of the buttons to get the information on our modules!'''</center>
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<script type='text/javascript' src='https://2012.igem.org/Template:Team:Amsterdam/scripts/mapper.js?action=raw'></script>
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function sensorText(){
function sensorText(){
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     $('#moldesign-content').append("<h1>Sensor</h1><h4>What does a sensor mean to the Cellular Logbook?</h4><p>A logbook aims to store the occurrence, encounter or presence of an external signal. Whether this signal comes from a metabolite, a chemical or a toxin, compound or substrate, does not matter! What matters for our Cellular Logbook is if the signal can be taken up by the cell and is able to activate a promoter that will induce the transcription of our writer module. Therefore any well-characterized promoter in the parts registry can be used in the sensor module.</p><p>For our proof-of-concept we chose to implement two different promoters as sensors:</p><h4>Lac-hybrid promoter:</h4><p>The lac promoter and its different protein components have been studied for decades and is widely used as one of the common systems for recombinant protein production in E. coli.</p><p>In its repressive state, the LacI repressor, an allosteric protein constitutively expressed by E. Coli, binds the promoter with high affinity, thereby preventing transcription. Once bound by an inducer such as lactose or IPTG, the repressor is released from the promoter and the RNA polymerase complex can be formed to enable synthesis.</p><p>Our first sensor uses the lac-hybrid promoter (BBa_R0011) together with a medium ribosomal binding site (BBa_B0032). Derived from the original Lac Operon (BBa_R0010), this adaptation does not rely on the presence of glucose, but only on lactose.</p><h4>Arabinose promoter:</h4><p>This promoter is derived from wild-type E. coli and has a modified AraI1 site, which causes this promoter to be less responsive to low concentrations of induction and therefore exhibits a lower maximum response.</p><p>pBAD is very specifically activated by L-Arabinose. In the absence of arabinose, the repressor protein AraC binds to AraI1 AraO2, blocking transcription. In the presence of arabinose, AraC binds to it and changes its conformation such that it interacts with the AraI1 and AraI2 operator sites, allowing transcription.</p><p>For the characterization of our system, we intentionally chose a weak version of the promoter, the pBAD-weak (BBa_K206001), from the parts registry.</p>")
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     $('#moldesign-content').append("<h1>Sensor</h1><h4>What does a sensor mean to the Cellular Logbook?</h4><p>A logbook aims to store the occurrence, encounter or presence of an external signal. Whether this signal comes from a metabolite, a chemical or a toxin, compound or substrate, does not matter! What matters for our Cellular Logbook is if the signal can be taken up by the cell and is able to activate a promoter that will induce the transcription of our writer module. Therefore any well-characterized promoter in the parts registry can be used in the sensor module.</p><p>For our proof-of-concept we chose to implement two different promoters as sensors:</p><h4>Lac-hybrid promoter:</h4><p>The lac promoter and its different protein components have been studied for decades and is widely used as one of the common systems for recombinant protein production in <i>E. coli</i>.</p><p>In its repressive state, the LacI repressor, an allosteric protein constitutively expressed by <i>E. Coli</i>, binds the promoter with high affinity, thereby preventing transcription. Once bound by an inducer such as lactose or IPTG, the repressor is released from the promoter and the RNA polymerase complex can be formed to enable synthesis.</p><p>Our first sensor uses the lac-hybrid promoter (BBa_R0011) together with a medium ribosomal binding site (BBa_B0032). Derived from the original Lac Operon (BBa_R0010), this adaptation does not rely on the presence of glucose, but only on lactose.</p><h4>Arabinose promoter:</h4><p>This promoter is derived from wild-type E. coli and has a modified <i>AraI1</i> site, which causes this promoter to be less responsive to low concentrations of induction and therefore exhibits a lower maximum response.</p><p>pBAD is very specifically activated by L-Arabinose. In the absence of arabinose, the repressor protein AraC binds to <i>AraI1 AraO2</i>, blocking transcription. In the presence of arabinose, <i>AraC</i> binds to it and changes its conformation such that it interacts with the <i>AraI1</i> and <i>AraI2</i> operator sites, allowing transcription.</p><p>For the characterization of our system, we intentionally chose a weak version of the promoter, the pBAD-weak (BBa_K206001), from the parts registry.</p>")
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function writerText(){
function writerText(){
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     $('#moldesign-content').append("<h1>Writer</h1><p>To efficiently write information in our Cellular Logbook, we need a good pen! Methylation of DNA is one of the main epigenetic marks used in eukaryotes to store epigenetic information and stably alter the gene expression pattern in cells over cell division. In our Cellular Logbook design we aim to take advantage of this natural epigenetic memory system to build the writer module.</p><h4>A methyltransferase to write</h4><p>The M.ScaI protein is a type II methyltransferase expressed in Streptomyces caespitosus that recognizes specifically the sequence 5’- AGTACT- ‘3 and leaves an N4-methylcytosine (m4) on the 5th cytosine of this sequence. m4 methylation is natively absent from E. coli and the site that M.ScaI recognises is not methylated by any of E. coli's native methylation systems (Dam, Dcm). We designed our writer module by utilizing the M.ScaI’s ability to methylate a specific site, thereby creating a writer module. The M.ScaI sequence was taken from Streptomyces caespitosus (REBASE), with some silent point mutations included to avoid forbidden sites and illegal sites specified by the parts registry. The modified M.ScaI methyltransferase sequence (BBa_K874000) constitutes the foundation of the writer module present in the Cellular Logbook.</p><h4>A polydactyl Zinc Finger (PZF) for the site</h4><p>In an attempt to achieve high specificity of the M.ScaI methyltransferase, we fused it to a Polydactyl Zinc Finger (BBa_K874001) consisting of 6 Zinc-fingers using a myc-linker (BBa_K874021). BBa_K874001 recognises the 18 bp E2C transcription factor motif 5’- GGGGCCGGAGCCGCAGTG- 3’. Assuming that PZFs have a higher binding affinity compared to methyltransferases, M.ScaI can be used for multiple sensors, which establishes a vital part of the expandability of the Cellular Logbook to log multiple signals via different sensors.</p><p>Altogether, the M.ScaI methyltransferase and the PZF create the writer module of the Cellular Logbook where the PZF provides the specificity or structure (the pen) for the M.ScaI to register events (the ink) in the Cellular Logbook.</p>")
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     $('#moldesign-content').append("<h1>Writer</h1><p>To efficiently write information in our Cellular Logbook, we need a good pen! Methylation of DNA is one of the main epigenetic marks used in eukaryotes to store epigenetic information and stably alter the gene expression pattern in cells over cell division. In our Cellular Logbook design we aim to take advantage of this natural epigenetic memory system to build the writer module.</p><h4>A methyltransferase to write</h4><p>The M.ScaI protein is a type II methyltransferase expressed in Streptomyces caespitosus that recognizes specifically the sequence 5’- AGTACT- ‘3 and leaves an N4-methylcytosine (m4) on the 5th cytosine of this sequence. m4 methylation is natively absent from <i>E. coli</i> and the site that M.ScaI recognises is not methylated by any of <i>E. coli</i>'s native methylation systems (Dam, Dcm). We designed our writer module by utilizing the M.ScaI’s ability to methylate a specific site, thereby creating a writer module. The M.ScaI sequence was taken from Streptomyces caespitosus (REBASE), with some silent point mutations included to avoid forbidden sites and illegal sites specified by the parts registry. The modified M.ScaI methyltransferase sequence (BBa_K874000) constitutes the foundation of the writer module present in the Cellular Logbook.</p><h4>A polydactyl Zinc Finger (PZF) for the site</h4><p>In an attempt to achieve high specificity of the M.ScaI methyltransferase, we fused it to a Polydactyl Zinc Finger (BBa_K874001) consisting of 6 Zinc-fingers using a myc-linker (BBa_K874021). BBa_K874001 recognises the 18 bp E2C transcription factor motif 5’- GGGGCCGGAGCCGCAGTG- 3’. Assuming that PZFs have a higher binding affinity compared to methyltransferases, M.ScaI can be used for multiple sensors, which establishes a vital part of the expandability of the Cellular Logbook to log multiple signals via different sensors.</p><p>Altogether, the M.ScaI methyltransferase and the PZF create the writer module of the Cellular Logbook where the PZF provides the specificity or structure (the pen) for the M.ScaI to register events (the ink) in the Cellular Logbook.</p>")
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<a href="https://2012.igem.org/Team:Amsterdam/software/logbook_designer/webtool><img src="https://static.igem.org/mediawiki/2012/d/d7/Fred.png" width="100px" \></a>
<img src="https://static.igem.org/mediawiki/2012/e/ee/Amsterdam_moldesign.png" alt="" usemap="#MolDesign" style="border-style:none; width:auto; border=0" class="mapper" />
<img src="https://static.igem.org/mediawiki/2012/e/ee/Amsterdam_moldesign.png" alt="" usemap="#MolDesign" style="border-style:none; width:auto; border=0" class="mapper" />
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<center>[https://2012.igem.org/Team:Amsterdam/software/logbook_designer/webtool '''Design your own logbook!''']</center><br\><br\>
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<h1>Sensor</h1><h4>What does a sensor mean to the Cellular Logbook?</h4><p>A logbook aims to store the occurrence, encounter or presence of an external signal. Whether this signal comes from a metabolite, a chemical or a toxin, compound or substrate, does not matter! What matters for our Cellular Logbook is if the signal can be taken up by the cell and is able to activate a promoter that will induce the transcription of our writer module. Therefore any well-characterized promoter in the parts registry can be used in the sensor module.</p><p>For our proof-of-concept we chose to implement two different promoters as sensors:</p><h4>Lac-hybrid promoter:</h4><p>The lac promoter and its different protein components have been studied for decades and is widely used as one of the common systems for recombinant protein production in <i>E. coli</i>.</p><p>In its repressive state, the LacI repressor, an allosteric protein constitutively expressed by <i>E. Coli</i>, binds the promoter with high affinity, thereby preventing transcription. Once bound by an inducer such as lactose or IPTG, the repressor is released from the promoter and the RNA polymerase complex can be formed to enable synthesis.</p><p>Our first sensor uses the lac-hybrid promoter (BBa_R0011) together with a medium ribosomal binding site (BBa_B0032). Derived from the original Lac Operon (BBa_R0010), this adaptation does not rely on the presence of glucose, but only on lactose.</p><h4>Arabinose promoter:</h4><p>This promoter is derived from wild-type <i>E. coli</i> and has a modified <i>AraI1</i> site, which causes this promoter to be less responsive to low concentrations of induction and therefore exhibits a lower maximum response.</p><p>pBAD is very specifically activated by L-Arabinose. In the absence of arabinose, the repressor protein AraC binds to AraI1 AraO2, blocking transcription. In the presence of arabinose, <i>AraC</i> binds to it and changes its conformation such that it interacts with the <i>AraI1</i> and <i>AraI2</i> operator sites, allowing transcription.</p><p>For the characterization of our system, we intentionally chose a weak version of the promoter, the pBAD-weak (BBa_K206001), from the parts registry.</p>
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Latest revision as of 04:00, 27 September 2012