Team:Freiburg/Content/Results/The combination
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<h2 id="Light-induced-receptor">Light Induced Receptor</h2> | <h2 id="Light-induced-receptor">Light Induced Receptor</h2> | ||
- | <p>For light induced gene transfer with our viral vector we | + | <p>For light induced gene transfer with our viral vector we cloned mCAT-1, the receptor our viral vector is specific for, into the response plasmid for the blue light system (plasmid p14ls_003 coding for mCAT-1-HA-P2A-mCherry under the control of the Gal4 upstream activating sequence and a minimal CMV promoter) or the red light system (p14rz_002 coding for mCAT-1-HA-P2A-mCherry under the control of the tet operon and a minimal CMV promoter). These P2A sequence between the mCAT-1-HA receptor and the mCherry reporter induces a co-translational self-cleavage, leaving behind the receptor-HA tag fusion and the cytosolic mCherry tag. The activation of gene expression was induced by illumination with 660 nm for the red light system (Fig. 1) and 465 nm for the blue light system (Figs. 2, 3). When the cells containing the light inducible receptor were not exposed to light (dark controls), no mCherry was detected in the cytosol, i.e. no receptor was expressed and transported to the cell surface. |
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Revision as of 01:44, 18 October 2014
The Combination
Our ultimate goal is to combine the spatial resolution of the light system with the specificity of our viral vector to generate patterns in a homogeneous cell culture. Since cells that are not illuminated with the inducing light should not express the mCAT-1 receptor, they should not get infected by viral particles.
Light Induced Receptor
For light induced gene transfer with our viral vector we cloned mCAT-1, the receptor our viral vector is specific for, into the response plasmid for the blue light system (plasmid p14ls_003 coding for mCAT-1-HA-P2A-mCherry under the control of the Gal4 upstream activating sequence and a minimal CMV promoter) or the red light system (p14rz_002 coding for mCAT-1-HA-P2A-mCherry under the control of the tet operon and a minimal CMV promoter). These P2A sequence between the mCAT-1-HA receptor and the mCherry reporter induces a co-translational self-cleavage, leaving behind the receptor-HA tag fusion and the cytosolic mCherry tag. The activation of gene expression was induced by illumination with 660 nm for the red light system (Fig. 1) and 465 nm for the blue light system (Figs. 2, 3). When the cells containing the light inducible receptor were not exposed to light (dark controls), no mCherry was detected in the cytosol, i.e. no receptor was expressed and transported to the cell surface.
Since our viral vector was not able to integrate into cells not expressing mCAT-1 on their surface, it was not able to infect non illuminated cells (Fig. 2-3). To mark cells that were targeted by viral particles we transduced the cells with our viral vector transferring a gene for EGFP as a cargo. In principle any gene of interest could be transferred light directed using The AcCELLerator.
As we know that the transient mCAT-1 receptor that was not linked to a light system needs 24 hours for expression in HEK293 cells, we determined the expression time of the receptor that was induced by blue light after illumination for five hours. We used a receptor that was labeled with both, mCherry and an HA-tag (p14ls_003), for analysis with Western blot and fluorescence microscopy. The results show that the receptor had an expression peak at 24 hours after beginning of illumination.
Pattern Generation
For generating pattern in homogenous cell layers we transfected HEK293T cells with the blue light system and the blue light induced receptor (p14ls_003). Dishes were covered with a photo mask preventing areas in the cell culture from light exposure. However, the blue light system is very sensitive to even low intensities of blue light. Due to scatterd light the receptor was activated in a huge area of the cell culture. Thus patterns were not visible to this time point due to by light scatter activated receptors (Fig.).