Team:BostonU/ChimeraExample
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<td scope="col"><center><capt>Figure 9: Flow Cytometry graph for pTet-pBad level 1 construct with RFP for three conditions: atc (red), arabinose (blue), atc and arabinose (purple)</capt></center></td> | <td scope="col"><center><capt>Figure 9: Flow Cytometry graph for pTet-pBad level 1 construct with RFP for three conditions: atc (red), arabinose (blue), atc and arabinose (purple)</capt></center></td> | ||
- | <td scope="col"><center><capt>Figure 10: Flow Cytometry graph for pBad-pTet level 1 construct with RFP for three conditions: atc (red), arabinose (blue), atc and arabinose (purple) </capt></center></td> | + | <td scope="col"><center><capt>Figure 10: Flow Cytometry graph for pBad-pTet level 1 construct with RFP for three conditions: atc (red), arabinose (blue), atc and arabinose (purple) </capt></center> |
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Revision as of 01:27, 17 October 2014
As described here , the tandem promoters were an integral part in designing the Chimera Workflow for building large devices and specifically, the priority encoder . In this page, we describe the detailed methodology that you could use to design, build and test tandem promoters. The same could be applied to any basic or complex device. Below, where we indicate "Step 1", those steps refer to steps outlined in the Chimera Workflow. |
Design
Step 2: In order to measure fluorescence with tandem repressible promoters, you will need a Test Device where the tandem promoters control the expression of a reporter fluorescent protein. One major element that must be considered when designing this Test Device is the testing strain. For this example, the testing strain you will use in this example is an E. coli DH5-alpha Pro strain where araC, tetR, and lacI are constitutively expressed in the genome. This impacts the Test Device design heavily, since the design becomes much more simplified since the Test Device does not need to include the expression of these repressor proteins. Note: Before beginning the flow setup, you should make sure you have chosen a fluorescent gene that you know how to test (refer to the Interlab Study page). Step 3: Once the basic parts are identified, you need to input the tandem promoter parts and Test Device that you want in your design into a Eugene file. Eugene will output all possible permutations of those parts. To obtain the final design of the desired constructs, add constraints to Eugene. Adding a few basic constraints greatly reduces the number of possible designs. This will help you decide which promoters you want to assemble in tandem and in what order. A more streamlined version of Eugene is also available, called miniEugene, which can also be used for this step. For the tandem promoters alone as parts, here are the design files. Eugene: Tandem Promoters Only miniEugene: Tandem Promoters Only Below is the output SBOL Visual graphic for the miniEugene file above, along with the miniEugene statistics for the file. Eugene: Test Device for Tandem Promoters miniEugene: Test Device for Tandem Promoters Below is the output SBOL Visual graphic for the miniEugene file above, along with the miniEugene statistics for the file. |
Build
Here is the Raven input file for generating the tandem promoters (Figure 4): Tandem Promoter Raven Here is the Raven input file for generating the tandem promoter Test Devices (Figure 5): Tandem Promoter Test Devices Raven Step 2: Following the assembly plan generated by Raven, the tandem promoters are cloned. This may involve PCR steps, restriction digests, and/or ligations depending on the assembly method the user selected. For the MoClo assembly, this involves running PCR reactions using oligos that can be designed by Raven and then cloning the new parts into destination vectors through a one-pot digestion-ligation reaction. Once the tandem promoters are complete, the Test Devices must also be built following the Raven assembly graph. Step 3: Any new constructs, including the tandem promoters and subsequent Test Devices, should be sequence verified prior to moving on to the Test stage. |
Test
Step 2: Once you have designed and built your new genetic parts, you need to test them for function. In this case, you would combine each tandem promoters with an RBS, a reporter gene, and a terminator to form a testing transcriptional unit (TU). After creating the TUs, you will follow a flow cytometry workflow to test the induction or repression of each promoter and also the promoters in tandem. The flow setup takes place over three days. Attached is a completed protocol for a flow cytometry tandem promoter experiment. On the first day, you will streak out the controls and your constructs onto plates with the correct antibiotic resistance. For controls, you will use J23104RM (positive RFP control), J23104GM (positive GFP control), COXGR (co-expression GFP RFP), COXRG (co-expression RFP GFP), and a strain control (Bioline or Pro strain). When testing inducible tandem promoters, it is advantageous to use the Pro strain because it contains araC, lacI, and tetR. This prevents you from having to build additional transcriptional units to express these genes. In the Pro strain, the tandem promoters will, by default, be in their off state. | |