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Team:BostonU/Backbones
From 2014.igem.org
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<th scope="col">The work carried out by previous BU iGEM teams used destination vectors, or plasmid backbones, with high-copy origins of replication. These high-copy plasmids in our library would not allow for optimal performance of our multiplexed transcriptional units and larger constructs. Additionally, works upon which we are basing our complex circuit assembly do not use high copy origins in their devices due to this loss of correct functionality. Circuit behavior would be desynchronized with the presence of a high copy origin, as it causes overexpression of the plasmid in a cell, leading to a high amount of transcription and protein expression. For more complex circuits, this overexpression pushes the limit of the amount of ribosomes that can be sequestered for translation, in addition to straining the cell's protein degradation mechanisms. <br><br>Detailed progress on new vector backbone creation can be found in the <a href="https://2014.igem.org/Team:BostonU/BackbonesNotebook">backbones notebook</a>.</th> | <th scope="col">The work carried out by previous BU iGEM teams used destination vectors, or plasmid backbones, with high-copy origins of replication. These high-copy plasmids in our library would not allow for optimal performance of our multiplexed transcriptional units and larger constructs. Additionally, works upon which we are basing our complex circuit assembly do not use high copy origins in their devices due to this loss of correct functionality. Circuit behavior would be desynchronized with the presence of a high copy origin, as it causes overexpression of the plasmid in a cell, leading to a high amount of transcription and protein expression. For more complex circuits, this overexpression pushes the limit of the amount of ribosomes that can be sequestered for translation, in addition to straining the cell's protein degradation mechanisms. <br><br>Detailed progress on new vector backbone creation can be found in the <a href="https://2014.igem.org/Team:BostonU/BackbonesNotebook">backbones notebook</a>.</th> | ||
| - | <th scope="col"><img src="https://static.igem.org/mediawiki/2014/ | + | <th colspan="2" scope="col"> |
| + | <center><img src="https://static.igem.org/mediawiki/2014/9/94/BackbonesDiagram1_BU14.png"><br><br><capt><br>Schematic of origin cloning - The PCR primer design added restriction sites for the MfeI restriction enzyme, which would give the ends of each of the amplified fragments compatible 4bp overhangs suitable for ligation. (Detailed primer design available <a href="https://static.igem.org/mediawiki/2014/c/c6/Primer_Design_6-23_BU14.xls">here</a>).</capt></center> | ||
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Revision as of 17:38, 28 July 2014
| The work carried out by previous BU iGEM teams used destination vectors, or plasmid backbones, with high-copy origins of replication. These high-copy plasmids in our library would not allow for optimal performance of our multiplexed transcriptional units and larger constructs. Additionally, works upon which we are basing our complex circuit assembly do not use high copy origins in their devices due to this loss of correct functionality. Circuit behavior would be desynchronized with the presence of a high copy origin, as it causes overexpression of the plasmid in a cell, leading to a high amount of transcription and protein expression. For more complex circuits, this overexpression pushes the limit of the amount of ribosomes that can be sequestered for translation, in addition to straining the cell's protein degradation mechanisms. Detailed progress on new vector backbone creation can be found in the backbones notebook. |
 Schematic of origin cloning - The PCR primer design added restriction sites for the MfeI restriction enzyme, which would give the ends of each of the amplified fragments compatible 4bp overhangs suitable for ligation. (Detailed primer design available here). |
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