Team:BostonU/MoCloChara

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<h1>MoClo Library Characterization</h1>
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<h2>Modular Cloning DNA Assembly</h2>
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<h9>An Introduction to MoClo</h9>
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<h5>An Introduction to MoClo</h5>
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<p><a href="http://www.plosone.org/article/info%3Adoi%2F10.1371%2Fjournal.pone.0016765#pone.0016765-Engler1">Modular Cloning</a>, or MoClo, is a relatively new assembly method introduced in 2011 by Ernst Weber et al., whereby using Type IIS restriction sites allows the user to ligate up to six DNA parts together in a one-pot reaction. It is a method based on <a href="http://www.plosone.org/article/info%3Adoi%2F10.1371%2Fjournal.pone.0005553">Golden Gate Assembly</a>. Type IIS restriction enzymes cleave outside of their recognition site to one side, thus allowing for removal of those restriction sites when used properly. This helps eliminate excess base pairs, or scars, from forming between DNA Parts. However, in order to ligate together properly, MoClo utilizes a set of 4-base pair fusion sites, which remain behind after ligation and thus generate 4-base pair scars between DNA parts in the final DNA sequence following ligation of two or more parts.
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<p dir="ltr"><a href="http://www.plosone.org/article/info%3Adoi%2F10.1371%2Fjournal.pone.0016765#pone.0016765-Engler1"<>Modular Cloning</a>, or MoClo, is a relatively new assembly method introduced in 2011 by Ernst Weber et al., whereby using Type IIS restriction sites allows the user to ligate up to six DNA parts together in a one-pot reaction. It is a method based on <a href="http://www.plosone.org/article/info%3Adoi%2F10.1371%2Fjournal.pone.0005553"<>Golden Gate Assembly</a>. Type IIS restriction enzymes cleave outside of their recognition site to one side, thus allowing for removal of those restriction sites when used properly. This helps eliminate excess base pairs, or scars, from forming between DNA Parts. However, in order to ligate together properly, MoClo utilizes a set of 4-bp fusion sites, which remain behind after ligation and thus generate 4-bp scars between DNA parts in the final DNA sequence following ligation of two or more parts.
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<h5>MoClo Overview</h5><ul>
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<h7><p>The MoClo system allows directional assembly of DNA parts through using BsaI and BbsI (also called BpiI), two Type IIS restriction enzymes that leave 4bp overhangs after they cut DNA. These four base pair overhangs, or fusion sites, created by either enzyme can be any 4 bases and thus fusion sites can be user-defined. The fusion sites are used to enable directional assembly of DNA Parts. By defining non-palindromic fusion sites that flank each DNA Part, we can ensure proper order of assembly by assigning the same fusion sites between the 3’ and 5’ ends of two DNA Parts that are meant to go next to one another (Fig. 1).</p>
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<p><center><img src="https://static.igem.org/mediawiki/2013/8/8f/MoClo_order.png" width="400px"></a></p></h7>
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<h3><b>Figure 1:</b> Directional Assembly of DNA Parts. Two basic DNA Parts (DNA Part 1 and 2) are each shown in green vectors to denote the chloramphenicol resistance cassette and each has two 4bp non-palindromic fusion sites flanking the DNA Part. The third vector is the Destination Vector for the final construct, which is orange to denote the kanamycin resistance cassette and contains the alpha fragment of <i>lacZ</i> for blue-white screening. The BsaI sites (red text) are shown in the DNA Part vectors and Destination Vector with the direction they cut (red arrow).</h3>
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<h5> MoClo Destination Vectors</h5><ul>
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<p> The MoClo system we're using has three levels of assembly where basic parts (Level 0) are linked together to form transcriptional units (Level 1), which are then linked together to form functional genetic circuits (Level 2). Each MoClo Level also requires Destination Vectors which act as the end carrier for the inserted DNA part(s). In our assembly, we utilize blue/white screening for each level along with different antibiotic resistance markers as a secondary selection method for screening our clones.</p>
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<p>We have converted the common BioBrick vectors pSB1C3, pSB1K3, and pSB1A2 into our MoClo Destination Vectors by inserting the alpha fragment of <i>lacZ</i> with flanking MoClo restriction and fusion sites into the cloning site (Fig. 2).</p>
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<div id="Parts">
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<p><center><img src="https://static.igem.org/mediawiki/2013/9/98/MoClo_DV.png" width="600px"></a></p></h7>
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<h9>MoClo Parts</h9>
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<h3><b>Figure 2:</b> Destination Vector Detail for MoClo Levels 0-2. The BsaI (in red) and BpiI (in purple) sites are interchanged between levels. The green backbone in Level 0 denotes chloramphenicol resistance, the orange for Level 1 is kanamycin, and the blue for Level 2 is ampicillin. The alpha <i>lacZ</i> fragment is in the cloning site for each level and the 4 blue N’s denote the fusion sites, to be designed by the user.</h3>
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<p dir="ltr">The MoClo system has three levels of assembly.
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<p dir="ltr">Level 0: Basic DNA Parts (ex: promoter, gene, etc.) are PCR amplified and cloned into MoClo destination vectors to form Level 0 Parts. The DNA parts within these Level 0 Parts are flanked by BsaI sites and two different 4pb-fusion sites.</p><br>
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<p><center><img src="https://static.igem.org/mediawiki/2012/d/d6/MoClo_details.png" width="575px"></a></p>
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<h3><b>Figure 1:</b> Generation of MoClo Fusion Sites using Type IIS Restriction Enzymes. The orange DNA sequence indicates the BpiI restriction site, the blue DNA sequence indicates the 4-bp MoClo fusion sites, and the bracketed names indicate either GFP and LacZ gene sequences. The black arrows over the orange DNA sequence indicates the BpiI direction, which impacts how the enzyme will cut the double stranded DNA sequence.</h3>
 
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<h5>MoClo Parts</h5>
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<h7><ul>
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<p>As mentioned above, our MoClo system has three levels of assembly.<p>
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<p>Level 0: Basic DNA Parts (ex: promoter, gene, etc.) are PCR amplified and cloned into MoClo destination vectors to form Level 0 Parts. During the PCR reaction, the correct fusion sites and BpiI sites are added to either side of the DNA sequence. The orientation of the BpiI sites is crucial, where the 3’ BpiI site is inverted while the 5’ BpiI site is not (Fig. 3). This PCR reaction is mixed with its matching Destination Vector in a MoClo reaction. After a transformed clone has been confirmed, this plasmid is now called a Level 0 Part and has the following order of DNA sequences: BsaI site-Fusion site 1-DNA Part-Fusion site 2-BsaI inverted (Fig. 3). Notice that BpiI is removed from the final product, thus requiring the Destination Vector to contain both BpiI and BsaI flanking the fusion sites (Fig. 3).</p><br>
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<p><center><img src="https://static.igem.org/mediawiki/2013/3/38/MoClo_L0PCR.png" width="550px"></a></p></h7>
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<h3><b>Figure 3:</b> Construction of a Level 0 MoClo Part. PCR primers are designed as shown in the top of the figure to include 2bp (NN), then the 6bp BpiI site (in purple), 2bp (NN), then the 4-bp fusion site (in blue), followed by 18-24bp of the DNA part of interest. Once amplified with high fidelity DNA polymerase, the PCR product is mixed with the Level 0 Destination Vector that has matching fusion sites in a MoClo reaction to create the final Level 0 MoClo Part shown in the final plasmid.</h3>
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<h7><p dir="ltr">Figure 1 shows how the Type IIS enzyme BpiI (yellow blocks in Figures 1 and 2) is used to generate Level 0 Parts using MoClo. Type IIS restriction enzymes recognize their site and then cut outside of it. BpiI (and BsaI shown as purple blocks in Figures 1 and 2) both leave 4bp overhangs behind after cutting (Figure 1). We refer to the 4bp overhangs as fusion sites and based our designs on the original fusion sites described by <a href="http://www.plosone.org/article/info%3Adoi%2F10.1371%2Fjournal.pone.0016765#pone.0016765-Engler1"<>Weber et al., 2011</a>. The orientation of BpiI and BsaI for the parts being ligated into the destination vectors face inwards while the BpiI and BsaI orientation is the opposite in the destination vector. This direction is shown in Figure 1 as the black arrows above the yellow BpiI blocks. This orientation guarantees that the BpiI sites are removed in the ligated Level 0 Part(Figure 1). The BsaI sites are likewise removed from Level 1 Parts (Figure 2).
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<p dir="ltr">Level 1: Up to six Level 0 Parts are ligated together to form Level 1 Parts. In our lab, Level 1 Parts most often result in complete transcriptional units (ex: promoter-RBS-gene-terminator). Level 1 Parts are flanked by BpiI sites (shown as yellow blocks in Figure 2) and two different 4pb-fusion sites.</p></ul>
 
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<p><center><img src="https://static.igem.org/mediawiki/2012/9/9b/MoClo00.png" width="700px"></a></p>
 
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<h3><b>Figure 2:</b> Generation of Level 0 and Level 1 MoClo Parts. PCR products are cloned into Level 0 destination vectors using the one-pot MoClo reaction with BpiI as the restriction enzyme. Level 1 composite parts are then made by mixing all four Level 0 parts together with a Level 1 destination vector and carrying out the MoClo reaction with BsaI as the restriction enzyme. Along with blue/white screening, chloramphenicol (CamR) is used to select Level 0 and kanamycin (KanR) is used to select Level 1 colonies.</h3>
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<p>Level 1: Up to six Level 0 Parts are ligated together to form Level 1 Parts. In our lab, Level 1 Parts most often result in complete transcriptional units (ex: promoter-RBS-gene-terminator). Level 1 Parts are flanked by BpiI sites and two different 4pb-fusion sites (Fig. 4).  
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<p><center><img src="https://static.igem.org/mediawiki/2013/3/37/MoClo_L1rxn.png" width="600px"></a></p></h7>
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<h3><b>Figure 4:</b> Construction of a Level 1 MoClo Part. Four basic DNA Parts (promoter, RBS, CDS, and terminator) are each shown in green vectors to denote the chloramphenicol resistance cassette and each has two 4bp non-palindromic fusion sites flanking the DNA Part. The fifth vector is the Destination Vector for the final construct, which is orange to denote the kanamycin resistance cassette and contains <i>lacZ</i> for blue-white screening. The BsaI sites (red text) are shown in the DNA Part vectors and Destination Vector with the direction they cut (red arrow). The 4bp fusion sites (blue text) shown in the five top plasmids indicate the fusion sites that will remain with either the DNA Parts or the Destination Vector after the BsaI digestion.</h3>
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<p dir="ltr">Level 2: Up to six Level 1 Parts are ligated together to form Level 2 Parts. More complex circuits, such as an inverter or NOR gate, can be built using Level 2 Parts. Like Level 0 Parts, Level 2 Parts are flanked by BsaI sites and two different 4pb-fusion sites.</h7></ul>
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<p>Level 2: Up to six Level 1 Parts are ligated together to form Level 2 Parts. More complex circuits, such as an inverter or NOR gate, can be built using Level 2 Parts. Like Level 0 Parts, Level 2 Parts are flanked by BsaI sites and two different 4pb-fusion sites.
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<h9>MoClo Simplified</h9>
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<h7><p dir="ltr">A more simplified way to look at MoClo is to focus on the fusion sites. To make this easier, we labeled our 4bp fusion sites A-H. This also allows for easier generation of images by removing the backbone and restriction site information.</p></ul></h7>
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<h3><b>Figure 3:</b> Levels 0 and 1 MoClo Part Generation Simplified. This figure illustrates how Level 0 and Level 1 MoClo parts are generated with a focus on the 4-bp fusion sites shown in circles labeled A-H. The BpiI and BsaI sites are not shown.</h3>
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<p><img src="https://static.igem.org/mediawiki/2012/2/2b/MoClo2.png" width="760px"></a></p>
 
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<p><h8>References</h8>
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<h3><b>Figure 4:</b> Level 2 Part Generation Simplified. This figure illustrates how Level 2 MoClo parts are generated from Level 1 parts with a focus on the 4-bp fusion sites shown in circles labeled A-H. The BpiI and BsaI sites are not shown.</h3>
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[1] Weber et al. (2011) "A Modular Cloning System for Standardized Assembly of Multigene Constructs." <i>PLoS ONE</i> 6(2): e16765. doi:10.1371/journal.pone.0016765<br>
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[2] Engler et al. (2009) "Golden Gate Shuffling: A One-Pot DNA Shuffling Method Based on Type IIs Restriction Enzymes." <i>PLoS ONE</i> 4(5): e5553. doi:10.1371/journal.pone.0005553<br>
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[3] Haddock, T., and Densmore, D. (2013) BBF RFC 94: The Modular Cloning Assembly: Standardized Assembly of Bacterial Transcriptional Units Using Type IIS Restriction Enzymes BsaI and BpiI.
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<h9>Our MoClo Contribution to iGEM</h9>
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<p dir="ltr"><h7>MoClo is a highly modular cloning system that we think would greatly improve the efficiency of genetic circuit generation for iGEM teams. We have designed our MoClo parts for easy, 4-way assembly of transcriptional units. In order to achieve this, our promoters are flanked by either A-B, E-B, F-B, or G-B fusion sites; our ribosomal binding sites are flanked by B-C fusion sites; our genes are flanked by C-D fusion sites; and our terminators are flanked by either D-E, D-F, D-G, or D-H fusion sites (Figure 4). By promoting this 4-way assembly, we have increased the usability of this system by keeping the number of destination vectors needed low and the PCR design stage is also simplified for the RBS and genes parts.
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We have submitted a <a href="https://2012.igem.org/Team:BostonU/MoClo"<>MoClo kit</a> of parts to the Registry so future iGEM teams can take advantage of this easy, efficient system. It is also our hope that future iGEM teams will help build upon this first attempt at generating a library of standard biological parts for the MoClo system.</h7>
 
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<h8>References</h8>
 
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[1] Weber et al. "A Modular Cloning System..." PLoS One 6(2) 2011
 
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Latest revision as of 02:56, 28 September 2013



Modular Cloning DNA Assembly

An Introduction to MoClo

    Modular Cloning, or MoClo, is a relatively new assembly method introduced in 2011 by Ernst Weber et al., whereby using Type IIS restriction sites allows the user to ligate up to six DNA parts together in a one-pot reaction. It is a method based on Golden Gate Assembly. Type IIS restriction enzymes cleave outside of their recognition site to one side, thus allowing for removal of those restriction sites when used properly. This helps eliminate excess base pairs, or scars, from forming between DNA Parts. However, in order to ligate together properly, MoClo utilizes a set of 4-base pair fusion sites, which remain behind after ligation and thus generate 4-base pair scars between DNA parts in the final DNA sequence following ligation of two or more parts.


MoClo Overview

    The MoClo system allows directional assembly of DNA parts through using BsaI and BbsI (also called BpiI), two Type IIS restriction enzymes that leave 4bp overhangs after they cut DNA. These four base pair overhangs, or fusion sites, created by either enzyme can be any 4 bases and thus fusion sites can be user-defined. The fusion sites are used to enable directional assembly of DNA Parts. By defining non-palindromic fusion sites that flank each DNA Part, we can ensure proper order of assembly by assigning the same fusion sites between the 3’ and 5’ ends of two DNA Parts that are meant to go next to one another (Fig. 1).

    Figure 1: Directional Assembly of DNA Parts. Two basic DNA Parts (DNA Part 1 and 2) are each shown in green vectors to denote the chloramphenicol resistance cassette and each has two 4bp non-palindromic fusion sites flanking the DNA Part. The third vector is the Destination Vector for the final construct, which is orange to denote the kanamycin resistance cassette and contains the alpha fragment of lacZ for blue-white screening. The BsaI sites (red text) are shown in the DNA Part vectors and Destination Vector with the direction they cut (red arrow).


MoClo Destination Vectors

    The MoClo system we're using has three levels of assembly where basic parts (Level 0) are linked together to form transcriptional units (Level 1), which are then linked together to form functional genetic circuits (Level 2). Each MoClo Level also requires Destination Vectors which act as the end carrier for the inserted DNA part(s). In our assembly, we utilize blue/white screening for each level along with different antibiotic resistance markers as a secondary selection method for screening our clones.

    We have converted the common BioBrick vectors pSB1C3, pSB1K3, and pSB1A2 into our MoClo Destination Vectors by inserting the alpha fragment of lacZ with flanking MoClo restriction and fusion sites into the cloning site (Fig. 2).



    Figure 2: Destination Vector Detail for MoClo Levels 0-2. The BsaI (in red) and BpiI (in purple) sites are interchanged between levels. The green backbone in Level 0 denotes chloramphenicol resistance, the orange for Level 1 is kanamycin, and the blue for Level 2 is ampicillin. The alpha lacZ fragment is in the cloning site for each level and the 4 blue N’s denote the fusion sites, to be designed by the user.


MoClo Parts

    As mentioned above, our MoClo system has three levels of assembly.

    Level 0: Basic DNA Parts (ex: promoter, gene, etc.) are PCR amplified and cloned into MoClo destination vectors to form Level 0 Parts. During the PCR reaction, the correct fusion sites and BpiI sites are added to either side of the DNA sequence. The orientation of the BpiI sites is crucial, where the 3’ BpiI site is inverted while the 5’ BpiI site is not (Fig. 3). This PCR reaction is mixed with its matching Destination Vector in a MoClo reaction. After a transformed clone has been confirmed, this plasmid is now called a Level 0 Part and has the following order of DNA sequences: BsaI site-Fusion site 1-DNA Part-Fusion site 2-BsaI inverted (Fig. 3). Notice that BpiI is removed from the final product, thus requiring the Destination Vector to contain both BpiI and BsaI flanking the fusion sites (Fig. 3).



    Figure 3: Construction of a Level 0 MoClo Part. PCR primers are designed as shown in the top of the figure to include 2bp (NN), then the 6bp BpiI site (in purple), 2bp (NN), then the 4-bp fusion site (in blue), followed by 18-24bp of the DNA part of interest. Once amplified with high fidelity DNA polymerase, the PCR product is mixed with the Level 0 Destination Vector that has matching fusion sites in a MoClo reaction to create the final Level 0 MoClo Part shown in the final plasmid.


    Level 1: Up to six Level 0 Parts are ligated together to form Level 1 Parts. In our lab, Level 1 Parts most often result in complete transcriptional units (ex: promoter-RBS-gene-terminator). Level 1 Parts are flanked by BpiI sites and two different 4pb-fusion sites (Fig. 4).



    Figure 4: Construction of a Level 1 MoClo Part. Four basic DNA Parts (promoter, RBS, CDS, and terminator) are each shown in green vectors to denote the chloramphenicol resistance cassette and each has two 4bp non-palindromic fusion sites flanking the DNA Part. The fifth vector is the Destination Vector for the final construct, which is orange to denote the kanamycin resistance cassette and contains lacZ for blue-white screening. The BsaI sites (red text) are shown in the DNA Part vectors and Destination Vector with the direction they cut (red arrow). The 4bp fusion sites (blue text) shown in the five top plasmids indicate the fusion sites that will remain with either the DNA Parts or the Destination Vector after the BsaI digestion.


    Level 2: Up to six Level 1 Parts are ligated together to form Level 2 Parts. More complex circuits, such as an inverter or NOR gate, can be built using Level 2 Parts. Like Level 0 Parts, Level 2 Parts are flanked by BsaI sites and two different 4pb-fusion sites.


References

[1] Weber et al. (2011) "A Modular Cloning System for Standardized Assembly of Multigene Constructs." PLoS ONE 6(2): e16765. doi:10.1371/journal.pone.0016765
[2] Engler et al. (2009) "Golden Gate Shuffling: A One-Pot DNA Shuffling Method Based on Type IIs Restriction Enzymes." PLoS ONE 4(5): e5553. doi:10.1371/journal.pone.0005553
[3] Haddock, T., and Densmore, D. (2013) BBF RFC 94: The Modular Cloning Assembly: Standardized Assembly of Bacterial Transcriptional Units Using Type IIS Restriction Enzymes BsaI and BpiI.