Difference between revisions of "Team:Slovenia/Implementation/Impact"
| (36 intermediate revisions by 5 users not shown) | |||
| Line 50: | Line 50: | ||
</a> | </a> | ||
<div class="ui vertical sticky text menu"> | <div class="ui vertical sticky text menu"> | ||
| − | <a class="item" href=" | + | <a class="item" href="//2016.igem.org/Team:Slovenia/Proof"> |
| + | <i class="chevron circle left icon"></i> | ||
| + | <b>Touch painting</b> | ||
| + | </a> | ||
| + | <a class="item" href="//2016.igem.org/Team:Slovenia/Implementation/Impact" style="color:#DB2828"> | ||
<i class="selected radio icon"></i> | <i class="selected radio icon"></i> | ||
| − | <b> | + | <b>Impact</b> |
</a> | </a> | ||
| − | <a class="item" href="# | + | <a class="item" href="#Mechanosensing" style="margin-left: 10%"> |
<i class="selected radio icon"></i> | <i class="selected radio icon"></i> | ||
| − | <b> | + | <b>Mechanosensing</b> |
</a> | </a> | ||
| − | <a class="item" href="# | + | |
| + | <a class="item" href="#protease" style="margin-left: 10%"> | ||
| + | <i class="selected radio icon"></i> | ||
| + | <b>Protease-based signaling</b> | ||
| + | </a> | ||
| + | |||
| + | <a class="item" href="#aplications" style="margin-left: 10%"> | ||
<i class="selected radio icon"></i> | <i class="selected radio icon"></i> | ||
| − | <b> | + | <b>Research applications</b> |
</a> | </a> | ||
| − | <a class="item" href=" | + | <a class="item" href="//2016.igem.org/Team:Slovenia/Parts"> |
<i class="chevron circle right icon"></i> | <i class="chevron circle right icon"></i> | ||
| − | <b> | + | <b>All parts</b> |
</a> | </a> | ||
| Line 73: | Line 83: | ||
<!-- menu goes here --> | <!-- menu goes here --> | ||
<!-- content goes here --> | <!-- content goes here --> | ||
| + | |||
<div class="main ui citing justified container"> | <div class="main ui citing justified container"> | ||
| − | <div class = "ui | + | <div> |
| − | + | <h1 class = "ui left dividing header"><span id="intro" class="section colorize"> </span>Impact</h1> | |
| − | <p>Foundational achievements of this project open several avenues for synthetic biology but also for other fields of science and for diverse applications. | + | <div class = "ui segment" style = "background-color: #ebc7c7; "> |
| − | + | <p><b><ul><li>Foundational achievements of this project open several avenues for synthetic biology but also for other fields of science and for diverse applications. | |
| + | <li>Several new valuable tools and collections of parts have been developed in the project, from a toolset of orthogonal proteases to an in vivo mechanosensing system, which could be further implemented with other settings and parts. | ||
| + | </ul></b></p> | ||
| + | </div> | ||
</div> | </div> | ||
| + | <div class = "ui segment"> | ||
| + | <h3><span id="Mechanosensing" class="section colorize">nbsp;</span>Mechanosensing - following the footsteps of Optogenetics</h3> | ||
| + | |||
| + | <p>The project was very successful in the implementation of designed mechanosensitive genetic circuits. | ||
| + | We have demonstrated cell activation by ultrasound, direct touch, and flow of liquid, which demonstrates that other direct or indirect | ||
| + | mechanical forces, such as the osmotic stress, pressure and others could be detected in this system. Mechano-sensing plays a very important | ||
| + | role in many biological senses, such as hearing, proprioception but also in senses that are developed only in some animals, such as the lateral | ||
| + | line of fish. It is likely that the systems based on our building modules might be able to detect gravity, acceleration and pressure. Delivery of the | ||
| + | mechano-sensing platform could be accomplished through viruses, which would probably be more appropriate for in vivo applications, where the focused | ||
| + | ultrasound will spatially limit the activation of targeted cells.</p> | ||
| + | |||
| + | </div> | ||
<div class = "ui segment"> | <div class = "ui segment"> | ||
| − | < | + | <h3><span id="protease" class="section colorize"> </span>Protease-based signaling</h3> |
<p>Although the specificity of viral proteases have been described before, this is the first time that functional split protease variants are produced and characterized. | <p>Although the specificity of viral proteases have been described before, this is the first time that functional split protease variants are produced and characterized. | ||
We envision that this toolset and moreover innovative synthetic protease-based signaling pathways will find their use for engineered cells. This system is based on modules | We envision that this toolset and moreover innovative synthetic protease-based signaling pathways will find their use for engineered cells. This system is based on modules | ||
which already enabled us the design of several two-input logic functions <i>in vivo</i>, which suggest that more complex circuits could readily be constructed. Additionally, | which already enabled us the design of several two-input logic functions <i>in vivo</i>, which suggest that more complex circuits could readily be constructed. Additionally, | ||
it is likely that the number of orthogonal proteases could be further expanded. Point mutations of known proteases, such as the TEVpE and TEVpH demonstrate that the recognition | it is likely that the number of orthogonal proteases could be further expanded. Point mutations of known proteases, such as the TEVpE and TEVpH demonstrate that the recognition | ||
| − | sites could further be engineered. We demonstrated by simulation that the activation of selected logic functions can be relatively fast, while the system needs to be reset to | + | sites could further be engineered. <br/> We demonstrated by simulation that the activation of selected logic functions can be relatively fast, while the system needs to be reset to |
the resting state considerably slowly, comparable to the transcriptional type of regulation, that is within hours. None of the active proteases was toxic to human cells, so | the resting state considerably slowly, comparable to the transcriptional type of regulation, that is within hours. None of the active proteases was toxic to human cells, so | ||
their implementation for signaling pathways does not seem to pose any problems to further developments. Release of proteins or peptides from cells has been demonstrated and | their implementation for signaling pathways does not seem to pose any problems to further developments. Release of proteins or peptides from cells has been demonstrated and | ||
| − | the capacity of the secretory machinery for secretion will have to be investigated in details in comparison to the secretion via exocytosis, which could however also be | + | the capacity of the secretory machinery for secretion will have to be investigated in details in comparison to the secretion via exocytosis, which could however also be triggered |
via influx of calcium, which is regulated by mechanosensors.<p> | via influx of calcium, which is regulated by mechanosensors.<p> | ||
</div> | </div> | ||
| Line 97: | Line 123: | ||
| − | |||
| − | |||
| − | |||
| − | |||
| − | |||
| − | |||
| − | |||
| − | |||
| − | |||
| − | + | ||
| + | |||
| + | |||
<div class = "ui segment"> | <div class = "ui segment"> | ||
| − | < | + | <h3><span id="aplications" class="section colorize">nbsp;</span>Research applications</h3> |
<ul> | <ul> | ||
<li>Following on the tracks of optogenetics such as investigation of cell activation including in vivo experiments</li> | <li>Following on the tracks of optogenetics such as investigation of cell activation including in vivo experiments</li> | ||
| Line 117: | Line 136: | ||
</ul> | </ul> | ||
| − | < | + | <h3>Potential therapeutic/diagnostic applications</h3> |
<ul> | <ul> | ||
<li>Ultrasound-regulated therapeutic activation of neuronal, immunological or other cells</li> | <li>Ultrasound-regulated therapeutic activation of neuronal, immunological or other cells</li> | ||
<li>Development of sensors of mechanical stress or shear forces in the tissue</li> | <li>Development of sensors of mechanical stress or shear forces in the tissue</li> | ||
| − | <li><i>In situ</i> production of bioactive peptides/proteins regulated by the ultrasound (e.g. insulin, | + | <li><i>In situ</i> production of bioactive peptides/proteins regulated by the ultrasound (e.g. insulin, neurotransmitters or other bioactive molecules)</li> |
<li>Complex signaling pathways and logic functions based on the proteolysis</li> | <li>Complex signaling pathways and logic functions based on the proteolysis</li> | ||
</ul> | </ul> | ||
| − | < | + | <h3>Envisioned long term applications</h3> |
<ul> | <ul> | ||
<li><b>Ultrasound-controlled therapeutic device</b></li> | <li><b>Ultrasound-controlled therapeutic device</b></li> | ||
| − | + | ||
| − | + | <div align = "clear:left"> | |
| − | + | <figure> | |
| − | + | <img class="ui medium image" src="https://static.igem.org/mediawiki/2016/3/35/T--Slovenia--6.3.3.a.png" > | |
| − | <div align = "left"> | + | <figcaption>Conceptual implementation of a therapeutic ultrasound-driven therapeutic device based on Sonicell</figcaption> |
| − | <img class="ui medium image" src=" | + | </figure> |
</div> | </div> | ||
| − | <li><b> | + | <li><b>Integrated electronic-biological devices</b></li> |
| − | <li><b>Introduction of new types of senses</b></li> | + | <li><b>Cell-based interface - such as a touchpad,</b> more tightly integrated than for example the <a href="http://duoskin.media.mit.edu/">Temporary Tatoos by the MIT Media Labs</a></li> |
| + | <li><b>Repair/enhancement of the sense of touch</b></li> | ||
| + | <li><b>Introduction of new types of senses, such as proprioreception, gravity, flow...</b></li> | ||
</ul> | </ul> | ||
| + | |||
| + | |||
</div> | </div> | ||
| − | |||
| − | |||
</div> | </div> | ||
</div> | </div> | ||
| Line 146: | Line 167: | ||
</div> | </div> | ||
</div> | </div> | ||
| + | <div> | ||
| + | <a href="//igem.org/Main_Page"> | ||
| + | <img border="0" alt="iGEM" src="//2016.igem.org/wiki/images/8/84/T--Slovenia--logo_250x250.png" width="5%" style = "position: fixed; bottom:0%; right:1%;"> | ||
| + | </a> | ||
| + | </div> | ||
</body> | </body> | ||
</html> | </html> | ||
Latest revision as of 14:35, 19 October 2016
Impact
nbsp;Mechanosensing - following the footsteps of Optogenetics
The project was very successful in the implementation of designed mechanosensitive genetic circuits. We have demonstrated cell activation by ultrasound, direct touch, and flow of liquid, which demonstrates that other direct or indirect mechanical forces, such as the osmotic stress, pressure and others could be detected in this system. Mechano-sensing plays a very important role in many biological senses, such as hearing, proprioception but also in senses that are developed only in some animals, such as the lateral line of fish. It is likely that the systems based on our building modules might be able to detect gravity, acceleration and pressure. Delivery of the mechano-sensing platform could be accomplished through viruses, which would probably be more appropriate for in vivo applications, where the focused ultrasound will spatially limit the activation of targeted cells.
Protease-based signaling
Although the specificity of viral proteases have been described before, this is the first time that functional split protease variants are produced and characterized.
We envision that this toolset and moreover innovative synthetic protease-based signaling pathways will find their use for engineered cells. This system is based on modules
which already enabled us the design of several two-input logic functions in vivo, which suggest that more complex circuits could readily be constructed. Additionally,
it is likely that the number of orthogonal proteases could be further expanded. Point mutations of known proteases, such as the TEVpE and TEVpH demonstrate that the recognition
sites could further be engineered.
We demonstrated by simulation that the activation of selected logic functions can be relatively fast, while the system needs to be reset to
the resting state considerably slowly, comparable to the transcriptional type of regulation, that is within hours. None of the active proteases was toxic to human cells, so
their implementation for signaling pathways does not seem to pose any problems to further developments. Release of proteins or peptides from cells has been demonstrated and
the capacity of the secretory machinery for secretion will have to be investigated in details in comparison to the secretion via exocytosis, which could however also be triggered
via influx of calcium, which is regulated by mechanosensors.
nbsp;Research applications
- Following on the tracks of optogenetics such as investigation of cell activation including in vivo experiments
- Investigation of the molecular mechanisms of mechanosensing
- Refactoring or rewiring of biologicals senses
Potential therapeutic/diagnostic applications
- Ultrasound-regulated therapeutic activation of neuronal, immunological or other cells
- Development of sensors of mechanical stress or shear forces in the tissue
- In situ production of bioactive peptides/proteins regulated by the ultrasound (e.g. insulin, neurotransmitters or other bioactive molecules)
- Complex signaling pathways and logic functions based on the proteolysis
Envisioned long term applications
- Ultrasound-controlled therapeutic device
- Integrated electronic-biological devices
- Cell-based interface - such as a touchpad, more tightly integrated than for example the Temporary Tatoos by the MIT Media Labs
- Repair/enhancement of the sense of touch
- Introduction of new types of senses, such as proprioreception, gravity, flow...
