Introduction

‘Hello World!’ are the first words a programmer prints when learning a new programming language. In analogy to this our team decided to do a ‘Hello World’ project in order to familiarize ourselves with lab techniques that we used later on to construct plasmids. Specifically we were performing PCR with uracil-containing primers, purifying PCR products and ligating them by means of USER cloning (Nour-Eldin, H. H.).

Since we are working with many periplasmic proteins, we wanted to try to target proteins to the periplasm. To do this, we used periplasmic signal peptides from the TAT and Sec pathways, and with a translational fusion of the signal peptide to GFP, we expressed GFP in the periplasm. Simultaneously, we expressed RFP in the cytoplasm as a background color, inspired by Skoog, Karl, et al.

Methods

The overall goal was to test the twin arginine pathway (TAT) and whether this signal peptide could transport GFP SF into the periplasm. The reason why we choose to use GFP superfolder (SF) was that this have shown to fold faster than the E.coli transport system is at translocation, (Fisher, Adam C., and Matthew P. DeLisa.). This assure that the GFP will form it’s fluorophore before translocation to the more reductive periplasmic space. Thus not inactivated by the inhibition of fluorophore formation as seen in other oxidative compartments like ER (Aronson, Deborah E., Lindsey M. Costantini, and Erik L. Snapp.).

Construction of the plasmids was done with USER-cloning and assembled from 3 fragments. The starting point was a plasmid construct with RFP and GFP SF respectively. The RFP and GFP SF were amplified out with their associated RBS (the same in both cases).

The TAT signal peptide was bought as a gBlock from IDT. All fragments were assembled into an expression vector specially designed to have a tight on/off mechanism (BBa_K1067007). Primers were design by the program PHUSER (Olsen, Lars Rønn, et al.) so that we got a seamless assembly.

Caption

We followed this protocol to visualize GFP in the periplasm.

Results

Conclusions

Biobrick BBa_K1067009 successfully directs proteins to the periplasm in E. coli.

References

• Skoog, Karl, et al. "Sequential Closure of the Cytoplasm and Then the Periplasm during Cell Division in Escherichia coli." Journal of bacteriology 194.3 (2012): 584-586.
• Nour-Eldin, H. H., Geu-Flores, F., & Halkier, B. A. (2010). USER cloning and USER fusion: the ideal cloning techniques for small and big laboratories. In Plant Secondary Metabolism Engineering (pp. 185-200). Humana Press.
• Olsen, Lars Rønn, et al. "PHUSER (Primer Help for USER): a novel tool for USER fusion primer design." Nucleic acids research 39.suppl 2 (2011): W61-W67.
• Fisher, Adam C., and Matthew P. DeLisa. "Laboratory evolution of fast-folding green fluorescent protein using secretory pathway quality control." PLoS One 3.6 (2008): e2351.
• Aronson, Deborah E., Lindsey M. Costantini, and Erik L. Snapp. "Superfolder GFP is fluorescent in oxidizing environments when targeted via the Sec translocon." Traffic 12.5 (2011): 543-548.