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Contents 1 HokkaidoU Japan 1.1 GSK tag 1.2 Investigation of T3SS-injectable proteins 2 References

GSK tag

Glycogen Synthase Kinase 3β is known to be phosphorylated by several enzymes in eukaryotic cell. We used first 13 amino acid as a tag (GSK tag)[1]. Ninth amino acid, serine is phosphorylated in eukaryotic cell(Fig). This phosphorylation state could be detected by using phsopho-specific antibodies which bind to only phosphorylated GSK tag. This way it is possible to distinguish whether GSK tag has been it eukaryotic cell. So you can see proteins which were injected into cell and which were not. This was a vital ingredient in our experiments.

GSK tag was constructed by Julie Torruellas Garcia, Gregory V. Plano et al. We removed present Spe I site in the sequence by silent mutation.

Translation: M   S   G   R   P   R   T   T   S-p  F   A   E   S
Original   :ATG AGT GGT CGC CCT CGC ACT ACT  AGT TTC GCT GAA AGT
rm Spe I   :ATG AGT GGT CGC CCT CGC ACT ACA* AGT TTC GCT GAA AGT 

Phosphorylated Serine is shown as S-p.

GSK tag can be added to N terminus₁, C terminus₁, and anywhere in middle₂, of the protein. We opted to insert it between SlrP secretion tag and the protein we wanted to inject.

Using non-phosphospecific antibodies it is possible to check the total amount of expressed protein with the tag. Comparing it with the injected protein you can determine the efficiency of the injection.

By comparing the mass of the protein with GSK tag it is also possible to see if it had been modified in eucaryotic cell. It can be used alongside of TEV site and provide proof for successful TEV protease activity. An experiment we would like to try in the future.

Investigation of T3SS-injectable proteins

Here we will discuss the structure of proteins which are injected and which are not. We tried five different proteins: mnt repressor, RFP, GFP, Cre DNA recombinase, (CCR5) transmembrane, LacI and Luciferase. All were chosen from biobrick distribution. As these parts are widely used in iGEM studying them would have a bigger impact compared to exotic ones.

Our main concern was not with the size but the stability of proteins. Previous research show that proteins like Zinc-Fingers are very stable and couldn't be injected. Hight stability prevents unfolding by T3SS chaperons.

We showed that GFP can be injected into eucaryotic cells by confocal laser microscope imaging. Thus it can serve as a control. Next is RFG, a fluorescent protein but with different structure from GFP.

Name	Registry	2011 distribution	length (bp)	total molecular weight (kDa)
	Discription
mnt repressor	BBa_C0072	1-12L	288	42.1
	Discription
Gal4 DNA binding domain	BBa_K105007	3-9I	438	47.6
	Discription
RFP	BBa_J06504	1-13F	714	57.7
	Discription
GFP	BBa_E0040	1-14K	720	57.9
	Discription
Cre DNA recombinase	BBa_J61047	1-5D	1037	69.6
	Discription
CCR5	BBa_I712002	2-3D	1059	70.4
	Discription
LacI	BBa_I732100	2-10E	1086	71.4
	Discription
Luciferase	BBa_I712019	1-10H	1653	92.1
	Discription

References

• Julie Torruellas Garcia, Franco Ferracci, Michael W. Jackson,1 Sabrina S. Joseph, Isabelle Pattis, Lisa R. W. Plano, Wolfgang Fischer, and Gregory V. Plano. 2006. Measurement of Effector Protein Injection by Type III and Type IV Secretion Systems by Using a 13-Residue Phosphorylatable Glycogen Synthase Kinase Tag. Infect Immun.Vol.74:5645-57. PubMed
• JWensheng Luo and Michael S. Donnenberg. 2011. Interactions and Predicted Host Membrane Topology of the Enteropathogenic Escherichia coli Translocator Protein EspB. J. Bacteriol.Vol.193:2972–80. PubMed