Team:Cardiff Wales/Design

Design




Principles



Being one of the few iGEM teams that makes transgenic plants as part of our project, we needed to take into consideration the extra steps required to make genetically modified plants. More specifically, the transformation procedure was both modular and sequential, requiring transformation of E. coli, then Agrobacterium tumefaciens, followed by infiltration into Nicotiana benthamiana.

GoldenGate cloning:

As a team, we decided to use the efficient assembly allowed by the GoldenGate system, creating a range of parts that are assembled in a specific order. This relies on using Type IIS restriction enzymes that cut downstream of a recognition site and create sticky ends of the designer's choice. This allows a range of custom sticky ends to be created to allow the effective, clean ligation of different DNA sequences, with minimal additional DNA. This system requires the creation of DNA sequences that contain the BsmBIor Esp3Irecognition sites 5'- CGTCTC(N)1 | -3' and 3'- GCAGAG(N)5 | -5', where " | " is the site of endonuclease activity. For our project, these sequences were ordered as gBlocks from IDT. These were then set up in a simultaneous digest/ligation reaction to insert these parts into the level 0 acceptor plasmid, and iGEM plasmid backbone, pSB1C3. These sticky ends are created so that when the level 0 parts ligate into the pSB1C3 plasmid, the cut sites for another Type IIS restriction endonuclease, BsaI,is created. These are the sequences 5' - GGTCTC(N)1 | -3' and 3'- CCAGAG(N)5 | -5'. Following this, a combined reaction with several level 0 parts can be set up that, due to their custom sticky ends, can be simultaneously ligated into one specific order with very high efficiency. Following each digestion/ligation reaction, E. coli would be transformed and grown overnight on antibiotic containing plates.

Bacterial selection:

To detect which bacterial colonies had the desired insert, we used both negative and positive selection. Bacteria that had not taken up the plasmid, be it pSB1C3 or pGBA2 for a level 0 and level 1 reaction, respectively, would be killed by the antibiotic in the plates (either chloramphenicol for level 0 plates, or kanamycin for level 1 plates). The resulting colonies on the plates would either be blue, containing the original LacZ gene in the acceptor plasmid which breaks down X-gal, or white, where LacZ had been lost, so X-gal is not cleaved, and the colony remains colourless. Consequently, white colonies would be screened by colony PCR to detect the presence of the insert. Colonies identified as promising were then picked, grown in antibiotic-containing broth, and had plasmid DNA extracted for DNA sequencing. Following this, Agrobacterium tumefaciens were transformed with sequence-confirmed DNA, and grown on plates containing kanamycin and rifamycin.

Plant transformation:

A. tumefaciens colonies were subsequently picked, activated, and syringe-infiltrated by hand into around 50 day old Nicotiana benthamiana plants. We found the best transgene expression measuring reporter gene output 4 days post infiltration (DPI), following a heat shock at 37 degrees Celsius for 30 minutes at 2DPI. For more detailed, replicable protocols, please visit our protocols page.




Iterations



The core stuff:

Initially, we aimed to target the aphid bacterial symbiont, Buchnera aphidicola as an effective aphid insecticide. Very early discussions ruled out the possibility of using a protein based insecticide, due to potential restrictions implemented by plasmodesmata size. We then realised that a nucleic acid, namely an RNA, would not have this issue, so we turned to looking at these as insecticides. Seeing as we were targeting bacteria, we looked into producing a sgRNA to kill the bacteria using its own CRISPR defense system, but a quick bioinformatic search ruled this out too, as the bacteria lack a CRISPR system. Thus, we decided to express an siRNA, targeting aphid-encoded genes that are essential for the survival of the symbiont, in the hope that these could be stacked with siRNA constructs that are directly essential for the aphids own survival.

Sticky ends:

As we were using GoldenGate cloning, we had to design parts with sticky ends that are complementary, and so would ligate into the correct order. Seeing as we used some parts that were already in the registry, we had to design sticky ends that had not been used before. Typically, teams such as the Cardiff team from 2017, would use only 3 parts in level 1 constructs. These would usually be a promoter, coding sequence, and terminator. However, due to synthesis size limits, we had to create constructs using up to 5 level 0 parts. Whilst GoldenGate cloning reports that around 11 level 0 parts can be combined at once, it means that for each order a different set of sticky ends must be created and used. For example, the most 5' sequence of our constructs was the promoter, with the 5' sticky end having GAGG to ligate to the plasmid backbone, and its 3' end having TACT to ligate to the region of DNA to be second in position. In our case, this was either the OTMV enhancer, or the 5' sequence of our siRNAs. Visit our individual part pages to find out all the sequences.

From BsmBI to Esp3I:

Early on in the project, we found difficulty running the level 0 digestion and ligation reactions simultaneously due to the optimum temperature of the restriction endonuclease. Typically, GoldenGate reactions are with digestion and ligation occurring in the same PCR tube, running in a thermocycler. However, initially we were using the type IIS restriction enzyme, BsmBI, which has an optimum temperature of 55 degrees Celsius. Running a cycled reaction with T4 DNA ligase (with an optimum temperature of 16 degrees Celsius and a denaturation temperature of around 65 degrees Celsius) raised some red flags. We found our reaction efficiency to be very low, with some results running the two reactions separately, but much less efficiently. One team member discovered that BsmBI has an isoschizomer, a restriction endonuclease that cuts at the same region, called Esp3I that has an optimum temperature of 37 degrees Celsius, well within the temperature range that allows T4 ligase to maintain is form. Once we were using this enzyme for our reactions, nearly all of them worked first time, with nearly 100% of colonies appearing white after an overnight cycle.

Changes to GUS reagents:

Later on in the project, we found that our GUS staining solution assay was not giving the desired results. One of the researchers in the university, Dr. Scofield, allowed us to use some of his GUS staining solution, and gave us his modified protocol for GUS staining. We immediately found clearer and stronger GUS staining.




Experimental design



Please see the Experiments and Protocols pages for thorough and replicable experimental design. This section only provides a very brief overview.

Fluorescent proteins:

To visualise fluorescent proteins, we examined infiltrated plants 4DPI as whole leaves, cut from the parent plant, under a fluorescence microscope. Both eGFP and mCherry were visualised this way.

Beta-glucuronidase (GUS) expression:

GUS expression levels were analysed 4DPI through a staining assay. This involved cutting leaf discs from plats, lysing the leaf membranes with 90% acetone, washing with NaPO4 buffer, and staining overnight with staining solution. Following this, leaf discs were destained with ~100% ethanol.

siRNA expression:

Despite not being able to detect siRNAs, their presence in leaves was attempted to be detected using 'semi-quantitative' PCR methods, involving primer pairs that should anneal to the pre-siRNA, and amplify a region. Due to lack of time and resources, siRNA specific kits were not used, but could be in the future.



Toxicity assays:

We aimed to test the toxicity by allowing aphids to feed on the transgenic plants and measuring a change in birth or death rate over several generations. However, this was not achievable in the time scale, but could be with a one or two months more work. This was going to involve putting adult aphids (parents) on agar-supplied leaf discs, and taking off any nymphs onto another leaf disc (F1), then their offspring to another (F2), and so on for as many generations as possible, with the hope that we would see a gradual decline in aphid populations when feeding on the transgenic plants relative to the controls.