Team:EPF-Lausanne/Tools/Gibson assembly

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We successfully used Gibson assembly for our plasmid assemblies, allowing us to put different genes in our plasmid backbones. You can find our protocol in our Notebook, under "Protocols" section.
We successfully used Gibson assembly for our plasmid assemblies, allowing us to put different genes in our plasmid backbones. You can find our protocol in our Notebook, under "Protocols" section.
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== Requirements ==
 
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In order to perform Gibson assembly on two DNA sequences, these sequences need to overlap by at least 20bp at the edge. You can easily add these overlaps by extension PCR
 
== Principle ==
== Principle ==
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Gibson assembly relies on the activity of 3 different enzymes:
Gibson assembly relies on the activity of 3 different enzymes:
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* Taq ligase
* Taq ligase
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In order to perform Gibson assembly on two DNA sequences, these sequences need to overlap by at least 20bp at the edge. You can easily add these overlaps by extension PCR.
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Combined together, these 3 enzymes allow overlapping DNA sequences (sequences A and B) to be ligated together in a single and isothermal reaction. First, the T5 exonuclease chews up bases at the 5' end on each strand, creating single-strands on the edges. Due to the sequence overlap, the single strand from A will anneal with the single strand from B. Then, the Phusion polymerase extend the DNA sequence from the 3' of the AB overlap. Finally, when there all the gaps have been filled by the polymerase, the Taq ligase ties up the A and B fragments.
 
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[[File:EPFL_Gibson_paper_picture.jpg]]
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Combined together, these 3 enzymes allow overlapping DNA sequences (sequences A and B) to be ligated together in a single and isothermal reaction. First, the T5 exonuclease chews up bases at the 5' end on each strand, creating single-strands on the edges. Due to the sequence overlap, the single strand from A will anneal with the single strand from B. Then, the Phusion polymerase extends the DNA sequence from the 3' of the AB overlap. Finally, when there all the gaps have been filled by the polymerase, the Taq ligase ties up the A and B fragments.
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[[File:EPFL_GibsonAssemblystrandscoloured.jpg|600px]]
== Step-by-step ==
== Step-by-step ==
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'''# Preparing the parts:''' For every pair of parts that you want to asemble, you need to add 20bp overhang with the other part. This implies running a PCR with primers that contain the overhang on their 5' end. After the PCR, you can purify your reaction products with a PCR purification kit and measure the DNA concentration.
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# '''Preparing the parts:''' For every pair of parts that you want to asemble, you need to add 20bp overhang with the other part (see illustration below). This implies running a PCR with primers that contain the overhang on their 5' end. After the PCR, you can purify your reaction products with a PCR purification kit and measure the DNA concentration.
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# '''Preparing the assembly reaction:''' In order to have a successful reaction, you must mix together equimolar ratios of each of the parts. An easy way to calculate this is to divide the DNA concentration by the part length; you can also go on the Gibthon Construct Designer website and use the online tool. For inserting a gene in a plasmid backbone, we suggest to use a 2:1 ratio of the gene over the backbone.
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# '''Running the reaction:''' Add Gibson mastermix and simply heat the tubes at 50°C for 45 minutes. You can use a normal PCR cycler for this step.
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# '''Transforming cells:''' After the reaction, simply use a few microliters of it to transform cells.
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# '''Negative control:''' For the negative control, make a Gibson reaction on just the plasmid backbone DNA and transform it. This will show you how much of the backbone closes itself up in your actual Gibson reaction.
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=== Preparing the parts ===
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Left overhang (green):
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* The '''backbone''' has a light green extension, whose sequence is the '''first 20bp of the RFP fragment'''
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* The '''RFP fragment''' has a dark green extension, whose sequence is the last 20bp of the backbone
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Right overhang (red):
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* The '''backbone''' has a dark red extension, whose sequence is the '''last 20bp of the RFP fragment'''
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* The '''RFP fragment''' has an orange extension, whose sequence is the '''first 20bp of the backbone
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'''
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[[File:EPFL_Gibson_overhangs.jpg]]
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== Advantages ==
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'''# Preparing the assembly reaction:''' In order to have a successful reaction, you must mix together equimolar ratios of each of the parts. An easy way to calculate this is to divide the DNA concentration by the part length; you can also go on the Gibthon Construct Designer website and use the online tool. For inserting a gene in a plasmid backbone, we suggest to use a 2:1 ratio of the gene over the backbone.
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* No need to use restriction enzymes: this can sometimes be very tricky, if a cleavage site is present in one of your sequences. Also, it means that you can perform Gibson on any DNA sequence.
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* Simplified reaction: 45min at 50°C replaces digestions and religations.
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* No scar: this allows you to place a promoter and RBS in front of a gene for example
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'''# Running the reaction:''' Add Gibson mastermix and simply heat the tubes at 50°C for 45 minutes. You can use a normal PCR cycler for this step.
 
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'''# Transforming cells:''' After the reaction, simply use a few microliters of it to transform cells.
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== Disadvantages ==
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* Primers are more complicated to design and longer - they are more expensive and take longer to be produced
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'''# Negative control:''' For the negative control, make a Gibson reaction on just the plasmid backbone DNA and transform it. This will show you how much of the backbone closes itself up in your actual Gibson reaction.
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* The reaction mastermix is expensive - due to large amounts of Taq ligase needed
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* A lot of negative results, due to the tendency of the plasmid backbone to close up on itself

Latest revision as of 21:41, 18 September 2011