Team:USyd-Australia/pUS204

From 2014.igem.org

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<h2>pUS204 Gene Cassette in pSB1C3 backbone</h2>
<h2>pUS204 Gene Cassette in pSB1C3 backbone</h2>
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<img src="https://static.igem.org/mediawiki/2014/1/1c/USyd-Australia_pUS204_Map.png" align="right" width="60%">
<h3 onclick="toggle_visibility('Aim');">Aim</h3>
<h3 onclick="toggle_visibility('Aim');">Aim</h3>
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<div id="Aim">
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<img src="https://static.igem.org/mediawiki/2014/c/c4/USyd-Australia_Integron_Design-Produce_Cassettes.png" width="300px">
 
To construct a reporter gene cassette consisting of aeBlue reporter and gentamicin resistance selective marker, and attC site.  The cassette must be cloned into standard iGEM pSB1C3 backbone with all sequences void of forbidden restriction sites as per iGEM requirements.  The cassette must be easily recovered as a circular product from the backbone for further work.
To construct a reporter gene cassette consisting of aeBlue reporter and gentamicin resistance selective marker, and attC site.  The cassette must be cloned into standard iGEM pSB1C3 backbone with all sequences void of forbidden restriction sites as per iGEM requirements.  The cassette must be easily recovered as a circular product from the backbone for further work.
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</br></br></br></br>
<h3 onclick="toggle_visibility('Approach');">Approach</h3>
<h3 onclick="toggle_visibility('Approach');">Approach</h3>
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<div id="Approach">
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<li>Primers<ul>
<li>Primers<ul>
<li>pSB1C3 linearisation primers containing edited biobrick prefix and suffix, <a href="https://2014.igem.org/Team:USyd-Australia/Notebook/Primers#iGEM1417">iGEM1417</a> and <a href="https://2014.igem.org/Team:USyd-Australia/Notebook/Primers#iGEM1418">iGEM1418</a>
<li>pSB1C3 linearisation primers containing edited biobrick prefix and suffix, <a href="https://2014.igem.org/Team:USyd-Australia/Notebook/Primers#iGEM1417">iGEM1417</a> and <a href="https://2014.igem.org/Team:USyd-Australia/Notebook/Primers#iGEM1418">iGEM1418</a>
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<li>aeBlue-aacC1 GmR-AttC gblock linearisation primers
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<li>aeBlue-aacC1 GmR-AttC gblock linearisation primers <a href="https://2014.igem.org/Team:USyd-Australia/Notebook/Primers#iGEM1419">iGEM1419</a> and <a href="https://2014.igem.org/Team:USyd-Australia/Notebook/Primers#iGEM1420">iGEM1420</a>
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<li>2 sets of junction primers</ul>
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<li>Junction primers <a href="https://2014.igem.org/Team:USyd-Australia/Notebook/Primers#iGEM1407">iGEM1407</a> and <a href="https://2014.igem.org/Team:USyd-Australia/Notebook/Primers#iGEM1408">iGEM1408</a></ul>
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<h3 onclick="toggle_visibility('Method');">Method</h3>
<h3 onclick="toggle_visibility('Method');">Method</h3>
<div id="Method">
<div id="Method">
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Part 1: Design and order gBlock for aeBlue-AttC construct</br>
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Part 1: Design and order gBlock for aeBlue-GmR-AttC construct</br>
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Part 2: Perform PCR on pSB1C3 linearised backbone (kit</br>
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Part 2: Perform PCR on pSB1C3 linearised backbone (kit)</br>
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Part 3: Preparation of pSB1C3 backbone by XbaI digestion</br>
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Part 3: Perform PCR on aeBlue-GmR-AttC gBlock</br>
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Part 4: Gibson Assembly of the three components.
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Part 4: Clone by digestion-ligation via EcoRI and PstI sites
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<h3>Results</h3>
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<p>PCR amplified gBlock was <a href="https://2014.igem.org/Team:USyd-Australia/Project/Protocols#restrict">cut</a> with EcoRI and PstI, and <a href="https://2014.igem.org/Team:USyd-Australia/Project/Protocols#ligation">ligated</a> into similarly cut linearised pSB1C3 backbone.  Ligation mixtures were transformed by heat shock into Top10 competent <i>E. coli</i>, and plated onto Chloramphenicol selective LB agar.  Chloramphenicol resistant colonies were picked and subjected to junction PCRs of direct colonies using primers <a href="https://2014.igem.org/Team:USyd-Australia/Notebook/Primers#iGEM1407">iGEM1407</a> and <a href="https://2014.igem.org/Team:USyd-Australia/Notebook/Primers#iGEM1408">iGEM1408</a></ul>.  26/27 of the colonies screened were positive at the expected amplicon size of 449bp.  Two clones, 9 and 17, were selected from the patch plate generated before <a href="https://2014.igem.org/Team:USyd-Australia/Project/Protocols#PCR">colony PCR</a>, and plasmids extracted via <a href="https://2014.igem.org/Team:USyd-Australia/Project/Protocols#plasmid>plasmid mini prep</a>
<h3 onclick="toggle_visibility('Validation');">Validation</h3>
<h3 onclick="toggle_visibility('Validation');">Validation</h3>
<div id="Validation">
<div id="Validation">
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<img src="https://static.igem.org/mediawiki/2014/c/c4/USyd-Australia_Integron_Design-Produce_Cassettes.png" width="300px" align="left">
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<p>To validate the function of the cassette, PCR products of the aeBlue-GmR gBlock were subjected to <a href="https://2014.igem.org/Team:USyd-Australia/Project/Protocols#ELAN"> ELAN</a> to produce circular cassettes. The original PCR and the ELAN were then run on a gel to confirm that indeed new products were being produced.</p>
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<img src="https://static.igem.org/mediawiki/2014/8/82/USyd-Australia_14-10-01_aeBlue_cassette_ELAN_abi.jpg" align="right">
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<p>ELAN reactions were repeated, and transformed into JM109 <i>E. coli</i> containing pUS44 and pUS42, two plasmids previously shown in NVC lab to contain functional AttI site with Pc promoter, and constitutive integrase respectively.  When plated on Gentamycin resistant plates, we should see selection of transformants in which the cassette has integrated into the AttI1 site in pUS44, thereby becoming gentamycin resistant.  As expected, we observed a lot of growth of Gm resistant colonies, ~50% of which grew again when re-plated onto Gm plates.  However, none of these colonies were the expected blue phenotype, indicating that there were issues with the aeBlue reporter gene.
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Latest revision as of 03:57, 18 October 2014

iGEM_Link


pUS204 Gene Cassette in pSB1C3 backbone

Aim

To construct a reporter gene cassette consisting of aeBlue reporter and gentamicin resistance selective marker, and attC site. The cassette must be cloned into standard iGEM pSB1C3 backbone with all sequences void of forbidden restriction sites as per iGEM requirements. The cassette must be easily recovered as a circular product from the backbone for further work.




Approach

The BioBrick parts were ordered as a synthetic gBlock from IDT, along with primers to amplify the entire gBlock by PCR. pSB1C3 linearised backbone was amplified by PCR using new primers to re-introduce the full biobrick prefix and suffix. The two parts were joined by restriction-ligation using EcoRI and PstI. The components were assembled as a circular plasmid in the order: pSB1C3 → AttC → aeBlue → aacC1 GmR→ pSB1C3. To retrieve functional cassettes, PCR primers containing compatible but non-identical restriction enzyme sites (XbaI and SpeI) at the end. From PCR products, circular cassettes were generated using Enzymatic Ligation Assisted by Nucleases (ELAN) via the XbaI and SpeI sites.

Materials

  • DNA
    • pSB1C3, linearised - by PCR
    • aeBlue-aacC1 GmR-AttC - gBlock order from IDT
  • Primers

Method

Part 1: Design and order gBlock for aeBlue-GmR-AttC construct
Part 2: Perform PCR on pSB1C3 linearised backbone (kit)
Part 3: Perform PCR on aeBlue-GmR-AttC gBlock
Part 4: Clone by digestion-ligation via EcoRI and PstI sites

Results

PCR amplified gBlock was cut with EcoRI and PstI, and ligated into similarly cut linearised pSB1C3 backbone. Ligation mixtures were transformed by heat shock into Top10 competent E. coli, and plated onto Chloramphenicol selective LB agar. Chloramphenicol resistant colonies were picked and subjected to junction PCRs of direct colonies using primers iGEM1407 and iGEM1408. 26/27 of the colonies screened were positive at the expected amplicon size of 449bp. Two clones, 9 and 17, were selected from the patch plate generated before colony PCR, and plasmids extracted via Validation

To validate the function of the cassette, PCR products of the aeBlue-GmR gBlock were subjected to ELAN to produce circular cassettes. The original PCR and the ELAN were then run on a gel to confirm that indeed new products were being produced.

ELAN reactions were repeated, and transformed into JM109 E. coli containing pUS44 and pUS42, two plasmids previously shown in NVC lab to contain functional AttI site with Pc promoter, and constitutive integrase respectively. When plated on Gentamycin resistant plates, we should see selection of transformants in which the cassette has integrated into the AttI1 site in pUS44, thereby becoming gentamycin resistant. As expected, we observed a lot of growth of Gm resistant colonies, ~50% of which grew again when re-plated onto Gm plates. However, none of these colonies were the expected blue phenotype, indicating that there were issues with the aeBlue reporter gene.

With thanks to: