Difference between revisions of "Team:Slovenia/Part Collection"
| Line 95: | Line 95: | ||
--> | --> | ||
| − | <h5><span class="section"> </span>Touchpaint Collection</h5> | + | <h5 id="Touch"><span class="section"> </span>Touchpaint Collection</h5> |
<p>A <b>Touchpaint Collection</b> is a subset of the <b>Mechanosensing Collection</b> that enables to convert mechanical | <p>A <b>Touchpaint Collection</b> is a subset of the <b>Mechanosensing Collection</b> that enables to convert mechanical | ||
stimulus of mammalian cells into light. This set contains the parts to enhance the sensitivity of cells to mechanical stimulus and the luciferase | stimulus of mammalian cells into light. This set contains the parts to enhance the sensitivity of cells to mechanical stimulus and the luciferase | ||
| Line 108: | Line 108: | ||
--> | --> | ||
| − | <h4><span class="section"> </span>Orthogonal Protease Collection</h4> | + | <h4 id="Orthogonal"><span class="section"> </span>Orthogonal Protease Collection</h4> |
<p>Our <b>Orthogonal Protease Collection</b> (nominated for Best Collection) is composed of a set of site-specific proteases that recognize | <p>Our <b>Orthogonal Protease Collection</b> (nominated for Best Collection) is composed of a set of site-specific proteases that recognize | ||
different 7-aminoacid residue motif targets (PPVp, SuMMVp, SbMVp and TEVp). The proteases were tested and are deposited as single chain coding | different 7-aminoacid residue motif targets (PPVp, SuMMVp, SbMVp and TEVp). The proteases were tested and are deposited as single chain coding | ||
| Line 143: | Line 143: | ||
--> | --> | ||
| − | <h4><span class="section"> </span>Logic Collection</h4> | + | <h4 id="Logic"><span class="section"> </span>Logic Collection</h4> |
<p>Our <b>Logic Collection</b> is composed of sets of parallel, antiparallel and destabilized coiled coils in fusion with parts of split luciferase. | <p>Our <b>Logic Collection</b> is composed of sets of parallel, antiparallel and destabilized coiled coils in fusion with parts of split luciferase. | ||
These constructs represent a tool for constructing logic circuits in mammalian cells operating at the post-translational level. The input signals for our | These constructs represent a tool for constructing logic circuits in mammalian cells operating at the post-translational level. The input signals for our | ||
| Line 165: | Line 165: | ||
Myc:nLuc:GS6:TEVs:GS6:AP4 <a href="http://parts.igem.org/Part:BBa_K1965051">BBa_K1965051</a> | Myc:nLuc:GS6:TEVs:GS6:AP4 <a href="http://parts.igem.org/Part:BBa_K1965051">BBa_K1965051</a> | ||
--> | --> | ||
| − | <h4><span class="section"> </span>FastER Secretion Collection</h4> | + | <h4 id="FastER"><span class="section"> </span>FastER Secretion Collection</h4> |
<p>Our <b>FastER Secretion Collection</b> is composed of parts coding for the TagRFP reporter with different ER retention signals, attached to | <p>Our <b>FastER Secretion Collection</b> is composed of parts coding for the TagRFP reporter with different ER retention signals, attached to | ||
the reporter via a TEV cleavage site. In this way, a protein can aggregate in the ER and be secreted upon induction by proteolytic cleavage with one of | the reporter via a TEV cleavage site. In this way, a protein can aggregate in the ER and be secreted upon induction by proteolytic cleavage with one of | ||
Revision as of 14:53, 18 October 2016
Part Collections
Mechanosensing Collection
Our BioBricks can work together as a coordinated system, but can also be divided into four smaller collections as mentioned above.
Our Mechanosensing Collection is composed of mechanosensitive ion channels and coding parts for protein gas vesicles, which enhance the sensitivity of mammalian cells to ultrasound or other mechanical stimuli, as well as a calcium influx measurement device based on the formation of a complex between calmodulin and M13 peptide with split luciferase, which results in the luminescence upon calcium influx.
Touchpaint Collection
A Touchpaint Collection is a subset of the Mechanosensing Collection that enables to convert mechanical stimulus of mammalian cells into light. This set contains the parts to enhance the sensitivity of cells to mechanical stimulus and the luciferase reporter. While this collection has been used to draw on cells it has many other uses, such as detection of the shear flow, ultrasound and other types of direct and indirect mechanical stress.
Orthogonal Protease Collection
Our Orthogonal Protease Collection (nominated for Best Collection) is composed of a set of site-specific proteases that recognize different 7-aminoacid residue motif targets (PPVp, SuMMVp, SbMVp and TEVp). The proteases were tested and are deposited as single chain coding sequences and as split protein fragments for light- and chemically-inducible reconstitution. The collection also contains the corresponding cyclic luciferase reporters for each of the proteases. We determined that the new proteases are even more active than the TEVp that has been the standard in biotechnology for several decades. We demonstrated that the split versions of all four proteases can be activated by different external stimuli, such as small molecules or light, demonstrating the robustness and versatility of the system. These proteases have been used to design signaling pathways and logic circuits in mammalian cells operating at the post-translational level.
Logic Collection
Our Logic Collection is composed of sets of parallel, antiparallel and destabilized coiled coils in fusion with parts of split luciferase. These constructs represent a tool for constructing logic circuits in mammalian cells operating at the post-translational level. The input signals for our logic operations is proteolytic activity of selected orthogonal proteases, representing constitutive logic gates, or split TEV and PPV proteases on inducible systems, representing inducible logic gates.
FastER Secretion Collection
Our FastER Secretion Collection is composed of parts coding for the TagRFP reporter with different ER retention signals, attached to the reporter via a TEV cleavage site. In this way, a protein can aggregate in the ER and be secreted upon induction by proteolytic cleavage with one of our inducible split TEV proteases without having to wait for the transcription and translation of the protein.
