Team:UC Berkeley/GatewayOverview
From 2008.igem.org
(→Gateway in vivo) |
(→Genomic Based Gateway) |
||
Line 56: | Line 56: | ||
===Genomic Based Gateway=== | ===Genomic Based Gateway=== | ||
- | The [[Team:UC_Berkeley/GatewayGenomic|Genomic Based Gateway]] scheme involves placement of the assembly vector in the genome. The gene of interest from the entry vector can recombine with the genome to yield the desired product. Both the entry vector and assembly vector have inducible origins of replication which serve as mechanisms for positive selection. Although this is a viable scheme for Gateway and can readily incorporate the lysis device in place of mini-preps, it still requires transformation of the lysate in order to select for the desired product. In an effort to further optimize our Gateway schemes, we developed a [[Team:UC_Berkeley/GatewayPhagemid|Phagemid | + | The [[Team:UC_Berkeley/GatewayGenomic|Genomic Based Gateway]] scheme involves placement of the assembly vector in the genome. The gene of interest from the entry vector can recombine with the genome to yield the desired product. Both the entry vector and assembly vector have inducible origins of replication which serve as mechanisms for positive selection. Although this is a viable scheme for Gateway and can readily incorporate the lysis device in place of mini-preps, it still requires transformation of the lysate in order to select for the desired product. In an effort to further optimize our Gateway schemes, we developed a [[Team:UC_Berkeley/GatewayPhagemid|Phagemid Based Gateway]] scheme. |
==References== | ==References== |
Revision as of 10:08, 29 October 2008
Contents |
Why Use Gateway?
The first step of the layered assembly scheme involves the transfer of biobrick parts from an entry vector to a double antibiotic assembly vector. Traditionally, this would require a fairly work-intensive protocol requiring digestion, gel purification, ligation, transformation, and plasmid isolation. In addition to being more time-consuming, the aforementioned procedure is also suboptimal because it is difficult to scale-up.
The [http://www.invitrogen.com/site/us/en/home/Products-and-Services/Applications/Cloning/Gateway-Cloning.html| Gateway Cloning] approach developed by Invitrogen offers a more efficient and convenient alternative for parts transfer. Their procedure involves the enzyme-catalyzed exchange of parts flanked by specific recombination sites. Experimentally, it is a one-pot, room-temperature reaction where the plasmids, buffer, water and enzymes are added together. After the addition of another enzyme and a short incubation period to terminate the reaction, the entire mixture can be transformed directly. This one-pot approach with a fewer steps is much more suitable for large-scale experimentation.
Gateway is commonly used to facilitate the transfer of a single gene of interest from an entry clone to multiple destination vectors, as shown below. The efficiency and robustness of the Gateway mechanism are ideal for this application because the once the gene of interest is cloned and confirmed in the entry vector, subsequent transfers using Gateway need not be confirmed again. Thus, it is ideal for use in the first step of layered assembly where a part may be transferred to one or more of the double antibiotic vectors required for the subsequent assembly steps assembly.
Gateway Chemistry
The Natural Lambda Phage Recombination system
In general, Gateway reactions involve the attB, attP, attL, and attR recombination sites and the integrase (Int), excisionase (Xis), and integration host factor (ihf) enzymes. Int cooperatively binds with ihf (which is composed of A and B subunits) in order to catalyze both the integration and excision reactions in the natural lambda phage system shown below. Although int can independently catalyze both reactions, ihf greatly improves int's binding affinity for the att recombination sites by bending the DNA [6]. Although int performs both the forward and reverse reactions, the equilibrium heavily favors the reaction of attB and attP to produce attL and attR sites. Xis binds to the attR sire and serves to shift the equilibrium so that it favors the reverse reaction [5].
Invitrogen's adaptation
In the Invitrogen scheme, the recombination sites are found in pairs flanking sequences that are intended for transfer. The recombination pairs are directional and specificity is given by ten nucleotides in the core region of each site, as shown below.
The schematic below depicts the LR reaction, during which the attL sites recombine with attR to yield attB and attP sites. The BP reaction proceeds in the opposite direction yielding attL and attR sites.
Selection for Correct Clones
The above scheme employs both ccdB negative selection and antibiotic selection in order to yield >90% of colonies containing the desired expression clone. The entry and destination vectors contain different antibiotic resistances, so plating on the desired antibiotic (Ampicillin in case shown above) eliminates clones containing the entry vector or the by-product of the reaction. In addition, ccdB is a lethal gene, thereby eliminating colonies containing that contain the destination vector, which would otherwise survive on the antibiotic plate.
Animation source: http://www.bio.davidson.edu/courses/Molbio/MolStudents/spring2000/patton/gateway.htm
Gateway in vivo
Plasmid Based Gateway
We applied our ideas for facilitating the automation of synthetic biology to the first step of layered assembly--the LR gateway reaction used to move the gene of interest into one or more of the double-antibiotic assembly vectors. We began by attempting to reproduce a plasmid based Gateway reaction, which was similar to that of Invitrogen's Gateway scheme. Although we were successful in having a completely in vivo version of the Gateway reaction, there were two major drawbacks: we had not eliminated the need for laborious and expensive mini-preps and we had relatively high background from ccdB mutations (the ccdB gene is relatively unstable because of its toxicity).
We addressed the first drawback by creating a self-lysis device which allows the cell's contents, including the desired product, to be released when arabinose is added. This device was inserted into either the entry or assembly plasmid to facilitate the isolation of the reaction products.
The second issue was more complex and was resolved by using positive selection methods rather than ccdB negative selection. Efforts to incorporate positive selection for Gateway led to the development of the Genomic Based Gateway scheme.
Genomic Based Gateway
The Genomic Based Gateway scheme involves placement of the assembly vector in the genome. The gene of interest from the entry vector can recombine with the genome to yield the desired product. Both the entry vector and assembly vector have inducible origins of replication which serve as mechanisms for positive selection. Although this is a viable scheme for Gateway and can readily incorporate the lysis device in place of mini-preps, it still requires transformation of the lysate in order to select for the desired product. In an effort to further optimize our Gateway schemes, we developed a Phagemid Based Gateway scheme.
References
- http://www.bio.davidson.edu/courses/Molbio/MolStudents/spring2000/patton/gateway.htm
- http://tools.invitrogen.com/downloads/gateway-the-basics-seminar.html
- http://www.invitrogen.com/site/us/en/home/Products-and-Services/Applications/Cloning/Gateway-Cloning.html|Gateway
- https://commerce.invitrogen.com/index.cfm?fuseaction=iProtocol.unitSectionTree&treeNodeId=290D0521B5FFA1B782C62C0AB62FD7BC
- Cho, E et al. Interactions between Integrase and Excisionase in the Phage Lambda Excisive Nucleoprotein Complex. Journal of Bacteriology. September 2002; 184(18): 5200–5203. Available Online: http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=135313 (Accessed: 28 October 2008).
- Frumerie, C et al. Cooperative interactions between bacteriophage P2 integrase and its accessory factors IHF and Cox. Virology. 5 February 2005; 232(1):284-294. Available Online: http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B6WXR-4F29SN2-1&_user=4420&_rdoc=1&_fmt=&_orig=search&_sort=d&view=c&_version=1&_urlVersion=0&_userid=4420&md5=0f9e41ba422140f157a2b1f1fb60b140 (Accessed: 28 October 2008).