Team:UC Berkeley/Assembly

From 2008.igem.org

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The choice of antibiotic resistance markers in the assembly plasmids are predetermined such that once the two plasmids recombine, the new plasmid will have a combination of markers from the two assembly vectors. Although there are four possible products of this reaction, only one will have both of the correct antibiotic resistance markers.
The choice of antibiotic resistance markers in the assembly plasmids are predetermined such that once the two plasmids recombine, the new plasmid will have a combination of markers from the two assembly vectors. Although there are four possible products of this reaction, only one will have both of the correct antibiotic resistance markers.
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[[2ab.jpg]]
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[[Image:2ab.jpg]]
The assembly reaction can be repeated to combine a number of basic parts into the desired order.  
The assembly reaction can be repeated to combine a number of basic parts into the desired order.  
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====Destination Layer====
====Destination Layer====
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Transfer of the composite part to the Destination plasmid using another Gateway cloning reacion [[https://2008.igem.org/Team:UC_Berkeley/GatewayOverview]].
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The Destination plasmid is tailored to a specific experiment or assay. This allows a single composite part to be transfered to several different Destination plasmids for further experimentation or characterization.
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[[Image:cdb5]]

Revision as of 20:38, 25 October 2008


Contents

Introduction

Layered assembly is a straight-forward and robust method for combining two or more basic parts into a destination vector. There are three layers (Entry, Assembly and Destination). Both Entry and Assembly layers are standardized for ease of use, while the Destination plasmid can be tailored to a specific experiment.

Entry Layer

The Entry plasmid contains a Spectinomycin antibiotic resistance marker and EcoRI, BglII and BamHI restriction sites. All basic parts are cloned into the entry vector. The basic part is flanked by attR1 and attr2 recombination sites.

entryplasmid.jpg

Since the entry plasmid attR1 and attR2 recombination sites, the basic part can easily be transferred into one of six different assembly vectors using the Gateway cloning scheme described here [[1]].

Assembly Layer

The six assembly plasmids contain two of three different antibiotic resistance markers (kanamycin, ampilicin and Chloramphenicol) separated by a XhoI restriction site.

assemblyplasmid.jpg

The assembly plasmids are transformed into cells that are engineered to either methylate BamHI or BglII restriction sites. Part A is transformed into a "lefty" cell that is methylated on BglII restriction sites while Part B is transformed into a "righty" cell that is methylated on BamHI restriction sites.

In a single eppendorf tube, lefty and righty plasmids are digested with BglII, BamHI and XhoI. Since restriction enzymes will not cut methylated DNA, the restriction site BglII site in the lefty cell and the BamHI restriction site in the righty cell are blocked from digestion.

The choice of antibiotic resistance markers in the assembly plasmids are predetermined such that once the two plasmids recombine, the new plasmid will have a combination of markers from the two assembly vectors. Although there are four possible products of this reaction, only one will have both of the correct antibiotic resistance markers.

2ab.jpg

The assembly reaction can be repeated to combine a number of basic parts into the desired order.

Once the composite part is complete, it is transferred to a destination plasmid.

Destination Layer

Transfer of the composite part to the Destination plasmid using another Gateway cloning reacion [[2]].

The Destination plasmid is tailored to a specific experiment or assay. This allows a single composite part to be transfered to several different Destination plasmids for further experimentation or characterization.

File:Cdb5