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Chromosome Engineering provides many benefits over plasmid based engineering, including precise copy number and stable maintenance without selection. Plasmid-based systems can add unnecessary noise to synthetic biology systems, limiting the potential complexity of these systems. However, a plasmid can easily be isolated, engineered with restriction enzymes and reintroduced into a host strain. Chromosomes cannot be engineered in this way. | Chromosome Engineering provides many benefits over plasmid based engineering, including precise copy number and stable maintenance without selection. Plasmid-based systems can add unnecessary noise to synthetic biology systems, limiting the potential complexity of these systems. However, a plasmid can easily be isolated, engineered with restriction enzymes and reintroduced into a host strain. Chromosomes cannot be engineered in this way. | ||
| - | Traditionally, methods to engineer chromosomes in bacteria have been based on homologous recombination, which is an inefficient process. Other methods have taken advantage of recombinant lysogenic phage, such as the <i>E. coli</i> phage λ. These phage integrate their genome into the bacterial chromosome via a site-specific recombination. So genes that have been added to the small phage genome will be carried along. The mechanisms of phage genome integration have been studied and there are some well characterized systems. These systems can be separated from the phage itself. They can be used to engineer DNA molecules <i>in vitro</i> or <i>in vivo</i>. | + | Traditionally, methods to engineer chromosomes in bacteria have been based on homologous recombination, which is an inefficient process. Other methods have taken advantage of recombinant lysogenic phage, such as the <i>E. coli</i> phage λ. These phage integrate their genome into the bacterial chromosome via a site-specific recombination. So genes that have been added to the small phage genome will be carried along. The mechanisms of phage genome integration have been studied and there are some well characterized systems. These systems can be separated from the phage itself. They can be used to engineer DNA molecules <i>in vitro</i> or <i>in vivo</i> without actually infecting the bacteria with a phage. |
| - | The phage integration system usually involves an integrase/recombinase enzyme, the phage attachment site (<i>attP</i>), the bacterial attachment site (<i>attB</i>), and for the reverse reaction an excisionase enzyme. The integrase enzyme catalyzes a stand exchange between <i>attP</i> and <i>attB</i> sites on the DNA yielding <i>attL</i> and <i>attR</i> sites which are composites of <i>attP</i> and <i>attB</i> sites. If there is excisionase and integrase present the reaction will go in the reverse direction. The well known λ integration system is the basis of Invitrogen's Gateway® technology. | + | The phage integration system usually involves an integrase/recombinase enzyme, the phage attachment site (<i>attP</i>), the bacterial attachment site (<i>attB</i>), and for the reverse reaction an excisionase enzyme. The integrase enzyme catalyzes a stand exchange between <i>attP</i> and <i>attB</i> sites on the DNA yielding <i>attL</i> and <i>attR</i> sites which are composites of <i>attP</i> and <i>attB</i> sites. If there is excisionase and integrase present the reaction will go in the reverse direction. The well known λ integration system is the basis of Invitrogen's Gateway® technology.Gateway® technology uses the activity of the λ integrase and excisionase to carry out cassette exchange reactions, where sections of two molecules each flanked by respective <i>att</i> sites are exchanged. The system is used to engineer plasmids as an alternative to traditional cloning using restriction enzymes. For our project, the goal of engineering chromosomes, without conflicting with the widely adopted Gateway® system, led us to choose the integrase from the <i>Streptomyces</i> phage C31 (ΦC31). |
| - | + | ||
| - | Gateway® technology uses the activity of the λ integrase and excisionase to carry out cassette exchange reactions, where sections of two molecules each flanked by respective <i>att</i> sites are exchanged. The system is used to engineer plasmids as an alternative to traditional cloning using restriction enzymes. For our project the goal of engineering chromosomes, without conflicting with the widely adopted Gateway® system, led us to choose the integrase from the <i>Streptomyces</i> phage C31 (ΦC31). | + | |
== The Experiments == | == The Experiments == | ||
Revision as of 17:11, 12 October 2009
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Contents |
Chromobricks: A Platform for Chromosome Engineering with BioBricks
The aim of our project is to develop a fully-featured platform for chromosome engineering, allowing the in vivo assembly of a synthetic chromosome from interchangeable parts, followed by selective degradation of the native chromosome. We have designed a proof-of-concept for chromosome-building that will use the site-specific integrase of phage ΦC31 to integrate a BioBrick into a defined locus of the E. coli genome. Six pairs of integrase-targeted att sites have been designed to be non-cross-reactive in order to support repeatable cassette-exchange reactions for chromosome building. We have also written software to model the integrase-mediated rearrangement of DNA molecules containing att sites, to aid the design of more elaborate chromosome-building systems. To selectively degrade the native chromosome we designed a nuclease-based, inducible genome-degradation system. In its simplest form, our system can be used to integrate biological devices into a chromosome in situations requiring stable copy number and selection-free maintenance.
Introduction
Background
Chromosome Engineering provides many benefits over plasmid based engineering, including precise copy number and stable maintenance without selection. Plasmid-based systems can add unnecessary noise to synthetic biology systems, limiting the potential complexity of these systems. However, a plasmid can easily be isolated, engineered with restriction enzymes and reintroduced into a host strain. Chromosomes cannot be engineered in this way.
Traditionally, methods to engineer chromosomes in bacteria have been based on homologous recombination, which is an inefficient process. Other methods have taken advantage of recombinant lysogenic phage, such as the E. coli phage λ. These phage integrate their genome into the bacterial chromosome via a site-specific recombination. So genes that have been added to the small phage genome will be carried along. The mechanisms of phage genome integration have been studied and there are some well characterized systems. These systems can be separated from the phage itself. They can be used to engineer DNA molecules in vitro or in vivo without actually infecting the bacteria with a phage.
The phage integration system usually involves an integrase/recombinase enzyme, the phage attachment site (attP), the bacterial attachment site (attB), and for the reverse reaction an excisionase enzyme. The integrase enzyme catalyzes a stand exchange between attP and attB sites on the DNA yielding attL and attR sites which are composites of attP and attB sites. If there is excisionase and integrase present the reaction will go in the reverse direction. The well known λ integration system is the basis of Invitrogen's Gateway® technology.Gateway® technology uses the activity of the λ integrase and excisionase to carry out cassette exchange reactions, where sections of two molecules each flanked by respective att sites are exchanged. The system is used to engineer plasmids as an alternative to traditional cloning using restriction enzymes. For our project, the goal of engineering chromosomes, without conflicting with the widely adopted Gateway® system, led us to choose the integrase from the Streptomyces phage C31 (ΦC31).
