Team:Slovenia/SafetyMechanismsTermination

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Termination

In order to terminate our system at the end of the therapy, we designed our therapeutic cells so that they would produce thymidine kinase.

Expression of thymidine kinase is not deleterious to cell growth.

The addition of the prodrug ganciclovir, which is converted into a toxic compound in cells producing thymidine kinase, efficiently initiates the apoptosis of therapeutic cells, making this mechanism virtualy free of leaky apoptosis.

The Thymidine kinase/Ganciclovir system in detail

Suicide gene therapy or gene-directed enzyme prodrug therapy (GDEPT) is widely used in cancer treatment. One of the most used GDEPT systems is the herpes simplex virus thymidine kinase (HSV-TK) with purine nucleoside analog ganciclovir (GCV) as a prodrug. Systemic administration of the prodrug ganciclovir induces apoptosis only in cells transfected with HSV-thymidine kinase while the untransfected cells survive. Unlike human thymidine kinase, HSV-thymidine kinase is able to phosphorylate ganciclovir to form ganciclovir-monophosphate, which is then phosphorylated to ganciclovir-diphosphate followed by ganciclovir-triphosphate. Ganciclovir-triphosphate is then incorporated into the DNA, which causes inhibition of DNA synthesis and subsequently leads to apoptosis (Ardiani et al., 2010). We used the HSV-thymidine kinase fused to mouse guanylate kinase (mGMK:TK30, BioBrick BBa_K404113, prepared by the Freiburg_Bioware team in 2010) in our system because it improves phosphorylation of ganciclovir-monophosphate to ganciclovir-diphosphate, thus preventing accumulation of ineffective intermediate products (i.e. GCV-MP, GCV-DP) due to the limited ability of the endogenous guanylate kinase (Figure 1).

We successfully implemented HSV-TK/GCV system to our cellular device to function as a controllable “safety switch”. This means that we can inactivate our cellular device whenever we want, after or even in the middle of therapy, simply by administering ganciclovir to the patient.

Figure 1. Mechanism of action of the HSV-TK/GCV system.

Following the BioBrick Standard Assembly technique we inserted the mouse guanylate kinase – thymidine kinase fusion gene (mGMK:TK30, (BBa_K404113)) under the control of the CMV promoter (Figure 2). HSV-TK mutant (TK30) contains six amino acid substitutions and shows enhanced sensitivity to ganciclovir (Kokoris et al., 1999).

Figure 2. Assembly of mGMK:TK30 (BBa_K404113) under the control of CMV promoter. Insert (mGMK:TK30, (BBa_K404113)) was digested with EcoRI and SpeI and pcDNA3 vector with EcoRI and XbaI, loaded on an agarose gel and the appropriate bands were purified. Vector and insert were ligated and transformed into E. coli strain DH5α. The DNA sequence of the resulting plasmid pPCMV_mGMK:TK30 was confirmed by DNA sequencing.

We transfected HEK293 cells with the pPCMV_mGMK:TK30 plasmid and monitored cell survival after the addition of ganciclovir. We daily observed cells with an light microscope and monitored the morphological signs of decreased viability. Additionally we stained cells with Hoechst and SytoxGreen514 dye to distinguish between live and dead cells with the help of a confocal microscope. We quantified viable cell numbers at different time points by cell counting and flow cytometry. For detailed protocols please refer to the "Experimental methods" section.

Results

We tested different amounts of transfected pPCMV_mGMK:TK30 DNA, different concentrations of ganciclovir and different time periods after the addition of ganciclovir to find the optimal conditions where our pCMV_mGMK:TK30-transfected cells would be most efficiently killed while the untransfected cells would be left unharmed. We monitored pPCMV_mGMK:TK30-transfected ganciclovir-treated cells under a light microscope and discovered that as little as 40 hours of incubation with higher concentrations of ganciclovir (>30 μg/ml) is enough to kill over 50 % of our pPCMV-mGMK:TK30-transfected cells. After 65 hours of incubation with ganciclovir there was a decrease in cell number and survival already at low concentration of ganciclovir (1 μg/ml). We showed that the HSV-TK/GCV system successfully kills cells even at low amounts of transfected mGMK:TK30 and upon addition of relatively low concentrations of ganciclovir (5 μg/ml).

We determined the number of viable cells after ganciclovir treatment by staining the cells with Trypan Blue (to distinguish live cells from the dead) and counting them. After 6 days of incubation with ganciclovir, the cytotoxic effect could be seen when only 1 μg/ml ganciclovir was added to pPCMV_mGMK:TK30 transfected cells while untransfected cells remained unharmed. The number of viable cells decreased to <10 % when 10 μg/ml ganciclovir was added. These results demonstrate that our safety mechanism is effective even at low doses of ganciclovir, when only therapeutic cells are killed while untransfected cells are left unharmed.

Figure 3. Cytotoxic effect of ganciclovir (GCV) on with mGMK:TK30 transfected cells. HEK293 cells were transfected with different amounts of plasmid PCMV_mGMK:TK30 and treated with ganciclovir (1, 10 and 30 mg/L). Cell survival was analysed after 6 days of incubation with GCV.

Cells stained with Hoechst and SytoxGreen514 dye that differentially stain live and dead cells (Figure 4) were imaged with a confocal microscope. Cell permeable Hoechst (depicted blue) binds to nucleic acids and therefore stains all cells in a culture. On the other hand cell impermeable SytoxGreen (depicted pink) cannot cross the membrane of live cells and therefore stains only dead cells. The cytotoxic effect of ganciclovir is evident at concentrations as low as 10 μg/ml and only a few viable cells were present upon addition of 100 μg/ml ganciclovir. On the other hand untransfected cells are not affected by ganciclovir. Moreover, cells expressing mGMK:TK30 (under CMV promoter) had no effect on cell survival if no ganciclovir was added.

References

Bauer, S., Groh, V., Wu, J., Steinle, A., Phillips, J.H., Lanier, L.L., Spies, T. (1999) Activation of NK Cells and T Cells by NKG2D, a receptor for Stress-Inducible MICA. Science 285, 727-729.

Borrego, F., Kabat, J., Kim, D.K., Lieto, L., Maasho, K., Peña, J., Solana, R., Coligan J.E. (2001) Structure and function of major histocompatibility complex (MHC) class I specific receptors expressed on human natural killer (NK) cells. Mol. Immunol. 38, 637-660.

Groh, V., Rhinehart, R., Secrist, H., Bauer., S., Grabstein, K.H., Spies, T. (1999) Broad tumor-associated expression and recognition by tumor-derived gd T cells of MICA and MICB. Proc. Natl. Acad. Sci. 96, 6879–6884.

Salih, H.R., Rammensee, H.G., Steinle, A. (2002) Cutting Edge: Down-Regulation of MICA on Human Tumors by Proteolytic Shedding. J Immunol. 169, 4098-4102.

Stenile, A., Li, P., Morris, D.L., Groh, V., Lanier, L.L., Strong, R.K., Spies, T. (2001) Interactions of human NKG2D with its ligands MICA, MICB, and homologs of the mouse RAE-1 protein family. Immunogenet. 53, 279-287.