Contents |
The "SWITCH" Project
Proteins in medical treatments
In the past decade, proteins have gained increasing attention as therapeutic agents. Among them, monoclonal antibodies have gained a particular importance, since they present several advantages compared to standard drugs. Reduced risk of non-specific action, longer therapeutic effect and smaller risk of toxicity upon elimination are just several advantages monoclonal antibodies possess when used as drugs.
Problems with synthesis
Regardless all of their advantages, the monoclonal antibodies are sometimes challenging to produce. Absolute majority of them are synthesized by cells that are cultured in huge containers (dubbed “bioreactors”). In order to achieve a reasonable price of the final product, the antibody have to be synthesized at a high concentration. Unfortunately, many antibodies are toxic to the producing cells at high concentration, which means they get killed before a sufficient concentration final product is reached.
So far, this problem was solved by using cells that were designed to produce the desired protein only when they sensed a particular molecule. This way, cells first grew calmly and started to produce the desired protein only when they were present in sufficient numbers to reach the correct concentration of the final product. Unfortunately, this method has a couple of disadvantages. First, the “switch” molecule is often difficult and costly to remove. Second, redesigning cells so that they react to the “switch” molecule can disturb lots of pathway, which in turn decreases the efficiency of antibody production.
Cool solution
We thought that the best solution for this problem would be a simple switch, that would turn the synthesis of therapeutic protein on just by shining some light shined on the cell culture and that would affect no or almost no pathways. This way the cells will grow happily in darkness and start producing the toxic protein only when there are enough of them. With such a switch, there would be nothing to remove from the cell culture and no cell pathways will be disrupted, allowing any protein to be synthesized efficiently.
How are we going to do it: LovTAP protein
A really nice way to realize our idea would be to use the LovTAP protein. When illuminated with a blue light, LovTAP changes configuration and acts as a negative regulator of gene expression in bacteria, allowing to switch on and off protein production only by the light. Unfortunately, LovTAP does nothing in the mammalian cells, which are the ones used for the synthesis of the antibodies. We've decided to overcome this problem by attaching a VP16 viral promoter domain to the LovTAP protein, so that it will become a powerful positive regulator of gene expression in mammalian cells. If we transect the LovTAP-VP16 construct along with the gene of the protein we would like to synthesize, we could use it as the perfect light “switch”. It will turn on the protein production when some light will be shined on the cell and won't disturb any pathways.
Another approach: Melanopsin
An another nice tool to realize a light-induced switch would be to use a light receptor that already exists in mammalian cells, for instance melanopsin. This way, the receptor will sense the light and transmit a chemical signal to the rest of the cell in order to activate the production of the desired protein. Even though this switch is more complex then the previous one and will affect several pathways, it still eliminates the need for an activating molecule. In addition, it might be more efficient then the LovTAP-VP16 based switch, since it uses a protein that already exists in mammalian cells, and not a fusion protein.
CHO cells & Co
In order to check the validity of our ideas, we attempted to implement both light-induced switches in CHO cells. For the LovTAP-VP16 switch, we've transfected CHO cells with LovTAP-VP16 encoding plasmid along with a reporter plasmid containing a protein that fluoresces in red (dsRed). We can tell that the switch functions correctly if after illumination with blue light we can see a substantial increase in red fluorescence in the cells. For the Melanopsin - based switch, we will transfect a plasmid expressing a natural light receptor (Melanopsin), along with a reporter that would synthesize the green-fluorescent protein in response to the signaling pathway that is naturally triggered by Melanopsin. We can tell that the switch functions correctly in case we see a substantial increase in green fluorescence in cell culture after illumination with blue light.