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Team:MIT/Protein
From 2013.igem.org
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<h1>Overview of Protein-based Cell-Cell Communication</h1> | <h1>Overview of Protein-based Cell-Cell Communication</h1> | ||
| - | While miRNA are useful in their own respect, it’s not currently known how miR-451 is naturally targeted into exosomes, making it difficult to engineer a system of sending any generic RNA. Luckily, research has shown that proteins can be targeted into exosomes by using an oligomerizing protein domain called Acyl-TyA. By fusing our protein signal to an Acyl-TyA domain, it’s possible to target our signal protein into exosomes and send it to another cell to evoke a response. <br><br> | + | While miRNA are useful in their own respect, it’s not currently known how miR-451 is naturally targeted into exosomes, making it difficult to engineer a system of sending any generic RNA. Luckily, research has shown that proteins can be targeted into exosomes by using an oligomerizing protein domain called Acyl-TyA (Shen, 2011). By fusing our protein signal to an Acyl-TyA domain, it’s possible to target our signal protein into exosomes and send it to another cell to evoke a response. <br><br> |
Our goal is to use Acyl-TyA to target generic protein signals into exosomes which allow for cell-cell communication by facilitating the transfer of a signal protein from a sender cell to a receiver cell. The general procedure begins with creating an Acyl-TyA fusion protein and testing the signal’s function within single cells to determine whether the fusion was successful. Then, once the signal’s function is verified, we use Jurkat T cells to produce exosomes containing our signal and apply these exosomes to receiver cells—the signal would then enter the receiver cells via the exosomes and activate a specific receiver circuit. Finally, the signal producing Jurkat T cells are to be cocultured together with receiver cells to determine whether cell-cell communication has been achieved. | Our goal is to use Acyl-TyA to target generic protein signals into exosomes which allow for cell-cell communication by facilitating the transfer of a signal protein from a sender cell to a receiver cell. The general procedure begins with creating an Acyl-TyA fusion protein and testing the signal’s function within single cells to determine whether the fusion was successful. Then, once the signal’s function is verified, we use Jurkat T cells to produce exosomes containing our signal and apply these exosomes to receiver cells—the signal would then enter the receiver cells via the exosomes and activate a specific receiver circuit. Finally, the signal producing Jurkat T cells are to be cocultured together with receiver cells to determine whether cell-cell communication has been achieved. | ||
| - | + | <p> <p> | |
| + | Citations <br><br> | ||
| + | Shen, B et al. Protein targeting to exosomes/microvesicles by plasma membrane anchors. J Biol Chem. (2011) | ||
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Revision as of 02:19, 29 October 2013
Overview of Protein-based Cell-Cell Communication
While miRNA are useful in their own respect, it’s not currently known how miR-451 is naturally targeted into exosomes, making it difficult to engineer a system of sending any generic RNA. Luckily, research has shown that proteins can be targeted into exosomes by using an oligomerizing protein domain called Acyl-TyA (Shen, 2011). By fusing our protein signal to an Acyl-TyA domain, it’s possible to target our signal protein into exosomes and send it to another cell to evoke a response.Our goal is to use Acyl-TyA to target generic protein signals into exosomes which allow for cell-cell communication by facilitating the transfer of a signal protein from a sender cell to a receiver cell. The general procedure begins with creating an Acyl-TyA fusion protein and testing the signal’s function within single cells to determine whether the fusion was successful. Then, once the signal’s function is verified, we use Jurkat T cells to produce exosomes containing our signal and apply these exosomes to receiver cells—the signal would then enter the receiver cells via the exosomes and activate a specific receiver circuit. Finally, the signal producing Jurkat T cells are to be cocultured together with receiver cells to determine whether cell-cell communication has been achieved.
Citations
Shen, B et al. Protein targeting to exosomes/microvesicles by plasma membrane anchors. J Biol Chem. (2011)
