Team:Alberta/Project/Chromosome Assembly

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     <h1>What is Recombineering?</h1>
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     <h1>Chromosome Assembly</h1>
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<p>A powerful implementation of BioBytes technology is the construction of artificial chromosomes. One of the goals of our project was the design of a minimalized <i>Escherichia coli</i> genome (see <a href="https://2009.igem.org/Team:Alberta/Project/Bioinformatics">Organism Design</a>). However, BioBytes alone can only facilitate the <i>in vitro</i> construction of a synthetic chromosome. A method is needed to insert the construct into a cell and displace the original chromosome.</p>
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Recombineering refers to the strategic use of recombination <i>in vivo</i> in order to reach a defined goal. In the case of BioBytes, a method is required to target the final construct to insertion at a specific place on the <i>E. coli</i> chromosome.</p>  
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<p>One approach would be to fabricate the entire construct <i>in vitro</i> in the form of a bacterial artificial chromosome (BAC), insert the BAC, and then inactivate the host chromosome. However, we have adopted the approach of piecing together the chromosome <i>in vivo</i> by recombining synthetic sections into the original host chromosome.  This provides a step-wise means of testing the functionality of smaller gene subsets rather than attempting to find errors in an entire minimal chromosome.</p>
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        <h2><i>In Vivo</i> Construction</h2>
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To do this successfully, three components must be taken into account:
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<p><b>Figure 1.</b></p>  
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<P>     -  There must be a system for targeting the construct to a specific site for insertion </p>
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<P>     -  Activation of the recombination system must be under experimenter control </p>
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<P>      -  It must be possible to select for and verify colonies in which the insertion was successful </p>
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        <p>This method requires a technique known as Lambda Red recombination (see <a href="https://2009.igem.org/Team:Alberta/Project/Recombineering">Recombineering</a>). Synthetic sections produced via the BioBytes method can be transformed through electroporation as linear fragments. Once a fragment is in a cell, the Red recombination genes direct the section to a double crossover event at regions on the chromosome homologous to regions flanking the ends of the synthetic section. This results in the replacement of a large portion of the original chromosome with a synthetic construct. For a fully synthetic genome, this process can be repeated until only the original origin of replication remains.</p>
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<p><b>Figure 2.</b></p>  
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    <h1>Targeting<h1>
 
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The BioBytes team has chosen to use a recombination system from bacteriophage lambda. Lambda Red recombinase specifically recombines on the ends of a linear fragment of DNA. If the ends of this fragment are homologous to two separate sites on the <i>E. coli</i> chomosome, the genetic material between these two homologous regions will be exchanged. This will be the basis for our targeting system.</p>
 
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<P>The homologous regions must be a minimum of 50 base pairs in length for recombination to occur at a significant frequency. This can be achieved in different ways:</p>
 
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<P>First 5' extensions corresponding to the homologous sequence can be added to any gene using PCR amplification. This would allow a PCR product to be targeted to a specific site for insertion. Because our constructs will be recircularized and grown (see <i>DNA assembly</i>), this would require us to PCR each plasmid construct seperately in order to add the homologous regions to the ends.</p>
 
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<P>An alternative is to use the genes on either end of our construct as the homologous regions. As an example, we could first locate a region of genes which were deemed inessential through literature review and our Matlab modelling. This region would necessarily be flanked by an essential gene at either end. We would then assemble a plasmid containing these two essential genes. If the insertion is successful, we would be left with a chromosome without this region of inessential genes:</p>
 
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<h2>Advantages of Recombination Over Building BAC's</h2>
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    <h1>Inducible Recombination System<h1>
 
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<li>For one, it can be very difficult to transform a 400 kb construct into E. coli as a single piece. An <i>in vivo</i> approach allows for the transformation of a number of much smaller constructs.</li>
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<li>By building the synthetic chromosome onto the original chromosome, there is no need for a complicated method of “rebooting” the cell. Transforming the entire new chromosome would require a way to smoothly inactivate or destroy the host chromosome without killing the cell in the process. <i>in vivo</i> construction allows for a smooth transition from the original to the artificial cell.</li>
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<li>The step wise integration of synthetic material into the host genome also allows for greater ability to test the functionality of subsets of the artificial genome. If the cells die upon integration of a synthetic fragment, then there may be a problem with the new construct, or the construct has displaced an essential gene without replacing it.</li>
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Latest revision as of 00:20, 22 October 2009

University of Alberta - BioBytes










































































































Chromosome Assembly

A powerful implementation of BioBytes technology is the construction of artificial chromosomes. One of the goals of our project was the design of a minimalized Escherichia coli genome (see Organism Design). However, BioBytes alone can only facilitate the in vitro construction of a synthetic chromosome. A method is needed to insert the construct into a cell and displace the original chromosome.

One approach would be to fabricate the entire construct in vitro in the form of a bacterial artificial chromosome (BAC), insert the BAC, and then inactivate the host chromosome. However, we have adopted the approach of piecing together the chromosome in vivo by recombining synthetic sections into the original host chromosome. This provides a step-wise means of testing the functionality of smaller gene subsets rather than attempting to find errors in an entire minimal chromosome.

In Vivo Construction

Figure 1.

This method requires a technique known as Lambda Red recombination (see Recombineering). Synthetic sections produced via the BioBytes method can be transformed through electroporation as linear fragments. Once a fragment is in a cell, the Red recombination genes direct the section to a double crossover event at regions on the chromosome homologous to regions flanking the ends of the synthetic section. This results in the replacement of a large portion of the original chromosome with a synthetic construct. For a fully synthetic genome, this process can be repeated until only the original origin of replication remains.

Figure 2.

Advantages of Recombination Over Building BAC's

  • For one, it can be very difficult to transform a 400 kb construct into E. coli as a single piece. An in vivo approach allows for the transformation of a number of much smaller constructs.
  • By building the synthetic chromosome onto the original chromosome, there is no need for a complicated method of “rebooting” the cell. Transforming the entire new chromosome would require a way to smoothly inactivate or destroy the host chromosome without killing the cell in the process. in vivo construction allows for a smooth transition from the original to the artificial cell.
  • The step wise integration of synthetic material into the host genome also allows for greater ability to test the functionality of subsets of the artificial genome. If the cells die upon integration of a synthetic fragment, then there may be a problem with the new construct, or the construct has displaced an essential gene without replacing it.

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