Team:Cambridge/Gibson/Protocol

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{{:Team:Cambridge/Templates/headerMinimalprototype}}
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{{:Team:Cambridge/Templates/headerbar|colour=#96d446|title=Gibson Assembly: Protocols}}
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{{:Team:Cambridge/Templates/headerbar|colour=#fb5c2b|title=Gibson Assembly: Protocol}}
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The formal paper in nature describing Gibson Assembly can be found [http://www.nature.com/nmeth/journal/v6/n5/full/nmeth.1318.html here].
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The original paper in nature describing Gibson Assembly can be found [http://www.nature.com/nmeth/journal/v6/n5/full/nmeth.1318.html here].
==Step 1: Design Primers==
==Step 1: Design Primers==
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{{:Team:Cambridge/Templates/RightImage|image=Cambridge-oligoface.jpg|caption=Designing Oligos Old-School}}
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{{:Team:Cambridge/Templates/RightImage|image=Cambridge-oligoface.jpg|caption=Designing Oligos Old-School - Try out our new and improved [[Team:Cambridge/Tools/Gibson | Gibthon]] Oligo design}}
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{{:Team:Cambridge/Templates/RightImage|image=Gibthon.png|caption=New and improved Gibthon oligo design}}
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<div style="float:right; clear:both">&nbsp;</div>
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*If you wish to ligate two pieces of DNA using Gibson they must be altered so as to have 40bp of overlap at the point of ligation.
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If you wish to ligate two pieces of DNA using Gibson they must be altered so as to have 40bp of overlap at the point of ligation.
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*The standard way to do this is with PCR with specialised primers
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The standard way to do this is with PCR with specialised primers (see [[Team:Cambridge/Gibson/Mechanism |mechanism]]). We have designed a tool to help you do this: [http://www.gibthon.org Gibthon]
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*We have designed a tool to help you do this: [http://www.gibthon.org Gibthon]
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==Step 2: Order Primers==
==Step 2: Order Primers==
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*This step can take a while, so Gibson Assembly requires some planning ahead
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This step can take a while, so Gibson Assembly requires some planning ahead
==Step 3: PCR ==
==Step 3: PCR ==
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PCR is a bit of a dark art, but we have found that these general principles have served us well over the summer:
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<div style="float:right; clear:both">&nbsp;</div>
{{:Team:Cambridge/Templates/RightImage|image=Phusion.jpg|caption=Phusion Polymerase}}
{{:Team:Cambridge/Templates/RightImage|image=Phusion.jpg|caption=Phusion Polymerase}}
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PCR is a bit of a dark art, but we have found that these general principles have served us well over the summer.
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<style>
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table.vistable td{border-right:1px solid gray; border-top:1px solid gray; padding:10px;}
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table.vistable{border-left:1px solid gray; border-bottom:1px solid gray;}
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</style>
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<div align="left">
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<table class="vistable" padding="0" cellspacing="0">
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{|class="wikitable"
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<tr>
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|-
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<td>Step
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|Step
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</td><td>Temp
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|Temp
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</td><td>Time
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|Time
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</td></tr>
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|-
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<tr>
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|1:Initial Melting
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<td>1:Initial Melting
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|98°C
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</td><td>98°C
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|30s
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</td><td>30s
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|-
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</td></tr>
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|2:Melting
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<tr>
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|98°C
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<td>2:Melting
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|10s
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</td><td>98°C
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|-
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</td><td>10s
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|3:Annealing
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</td></tr>
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|T<sub>m</sub>°C
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<tr>
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|15s
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|-
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<td>3:Annealing
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|4:Elongation
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</td><td>T<sub>m</sub>°C
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|72
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</td><td>15s
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|45s per kb DNA
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</td></tr>
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|-
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<tr>
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|5:GoTo step 2
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<td>4:Elongation
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|
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</td><td>72
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|30 times
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</td><td>45s per kb DNA
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|-
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</td></tr>
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|6:Final Elongation
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<tr>
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|72°C
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<td>5:GoTo step 2
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|7m30
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</td><td>
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|-
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</td><td>30 times
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|7:Final Hold
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</td></tr>
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|4°C
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<tr>
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|
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|}
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<td>6:Final Elongation
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</td><td>72°C
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</td><td>7m30
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</td></tr>
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<tr>
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<td>7:Final Hold
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</td><td>4°C
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</td><td>
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</td></tr>
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</table>
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</div>
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</html>
The Annealing T<sub>m</sub> that should be used is the temperature of the main 20 or so bases of the primer (not including the flap), since the flap only begins to anneal after the first few cycles, by which point primer specificity is less of an issue.
The Annealing T<sub>m</sub> that should be used is the temperature of the main 20 or so bases of the primer (not including the flap), since the flap only begins to anneal after the first few cycles, by which point primer specificity is less of an issue.
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==Step 4: Gibson Assembly==
==Step 4: Gibson Assembly==
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*Prepare [[Team:Cambridge/Gibson/MasterMix | Gibson Master Mix]]
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1) Prepare [[Team:Cambridge/Gibson/MasterMix | Gibson Master Mix]]
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*Add DNA to be ligated and Master Mix in volumetric ratio 1:3
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*Incubate for 1 hour at 50°C
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2) Add DNA to be ligated and Master Mix in volumetric ratio 1:3
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3) Incubate for 1 hour at 50°C
<i>e.g. If you were ligating two fragments (A and B) you could put:</i>
<i>e.g. If you were ligating two fragments (A and B) you could put:</i>
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{|class="wikitable"
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<html>
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|-
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<style>
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|<i>2.5µl</i>
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table.vistable td{border-right:1px solid gray; border-top:1px solid gray; padding:10px;}
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|<i>fragment A</i>
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table.vistable{border-left:1px solid gray; border-bottom:1px solid gray;}
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|-
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</style>
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|<i>2.5µl</i>
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<div align="left">
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|<i>fragment B</i>
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<table class="vistable" padding="0" cellspacing="0">
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|-
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<tr>
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|<i>15µl</i>
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<td><i>2.5µl</i>
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|<i>Gibson Master Mix</i>
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</td><td><i>fragment A</i>
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|}
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</td></tr>
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<tr>
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<td><i>2.5µl</i>
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</td><td><i>fragment B</i>
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</td></tr>
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<tr>
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<td><i>15µl</i>
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</td><td><i>Gibson Master Mix</i>
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</td></tr>
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</table>
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</div>
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</html>
==Step 5: Transformation==
==Step 5: Transformation==
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The reaction mixture generated above should contain enough DNA to directly transform cells, although this is of course limited by the amount of DNA in the tube before the ligation.
{{:Team:Cambridge/Templates/footer}}
{{:Team:Cambridge/Templates/footer}}

Latest revision as of 20:31, 26 October 2010