Difference between revisions of "Team:Wageningen UR/Collaboration"

Line 14: Line 14:
 
<html>
 
<html>
 
<section id="delft">
 
<section id="delft">
<p>Our philosophy when it comes to collaboration is that “collaboration leads to codevelopment of the innovation and its full acceptance and use”. Based on this, we did not only collaborate with other iGEM teams, but also with students from the Design Academy Eindhoven. The students from the DAE helped us gain insight into how people perceive our project and synthetic biology in general, while the collaboration with iGEM teams helped us move forward in a scientific way.
+
<p>Our philosophy when it comes to collaboration is that “collaboration leads to development of the innovation and its full acceptance and use”. Based on this, we did not only collaborate with other iGEM teams, but also with students from the Design Academy Eindhoven. The students from the DAE helped us gain insight into how people perceive our project and synthetic biology in general, while the collaboration with iGEM teams helped us move forward in a scientific way.
 
We collaborated with two other iGEM teams: TU_Delft and Groningen. During this process, we also learned about their projects and helped each other out with some ideas. We even got some valuable input from both teams. Here’s what we have achieved in collaboration with them.</p>
 
We collaborated with two other iGEM teams: TU_Delft and Groningen. During this process, we also learned about their projects and helped each other out with some ideas. We even got some valuable input from both teams. Here’s what we have achieved in collaboration with them.</p>
  
  
 
<h1><b>Delft</b></h1>
 
<h1><b>Delft</b></h1>
<p> The team of TU Delft has been working on the creation of a biolaser. This is the name for a biosilica-covered cell expressing fluorescent proteins. The biosilica-layer is able to trap some of the photons sent out by fluorescing proteins that can then be used to excite other fluorescent proteins, leading to an increased overall fluorescence intensity in these cells.
+
<p> The team of TU Delft has been working on the creation of a biolaser in the form of a a biosilica-covered cell expressing fluorescent proteins. The biosilica-layer traps some of the photons sent out by fluorescent proteins that can be used to excite other fluorescent proteins. This leads to increased overall fluorescence intensity in the cells. We measured their strains in our plate reader.
Our task was to test eight different samples: three XXX and expression of GFP with five different promoters. As we ourselves have worked with the platereader extensively during our project to measure fluorescence of samples, we were more than willing to also test these samples, as it also added to our own expertise in handling the platereader.
+
During our own project, we have worked with the microplate reader extensively. Likewise, testing the samples from TU_Delft was not just beneficial for them, it also added to our own expertise in handling the microplate reader. We tested eight different constructs in a microplate reader: three different BioBricks for expression of fluorescent proteins and expression of GFP with five different promoters. In short, we are content with the results we got and the practice we had gotten through this collaboration, and we are happy about this opportunity to help another team.
The data has been processed by the team of TU Delft, after we have sent them the raw data. Still, as the curious scientists that we are, we had a look at the cells we worked with to get some preliminary results. While some samples did not show high levels of fluorescence, some showed a stunning green colour. Contempt with the results we got and the practice we had gotten through this collaboration, we were happy to have taken this opportunity to help another team.  
+
Moreover, the Delft team did some experiments for us. For our in vitro toxicity assay with fluorophore-filled vesicles, we were hoping for a picture proving that we were indeed able to encapsulate fluorophores in vesicles. The TU Delft team helped us by making some nice pictures of our vesicles using an electron microscope! The results can be found here.  
Moreover, the Delft team also did some test for us. For our in vitro toxicity assay with fluorophore-filled vesicles, we were longing for a picture proving that we were indeed able to encapsulate fluorophores in vesicles. The results can be found here.  
+
 
  
 
</p>
 
</p>
Line 29: Line 29:
 
<section id="groningen">
 
<section id="groningen">
 
<h1><b>Groningen</b></h1>
 
<h1><b>Groningen</b></h1>
<p> For the team of Groningen, we tested and improved their system CryptoGERM. This is a way of encrypting messages in spores, the messages being only decryptable with the belonging key, also in a spore.
+
<p> For Groningen iGEM team, we tested and improved their system CryptoGERM. CryptoGERM was developed to encrypt messages in the DNA of Bacillus subtilis spores, that can only be decoded using a key that is also in a spore.  
We received spores of Bacillus subtilis with a message encrypted in the genome. As we tested at an early stage, the key was not delivered in spores as well, but we could test our results on a webpage that was able to transform the sequence we obtained into a message for us to read.
+
We received a message to decrypt from Groningen. As we tested the system in an early stage, when it was not fully developed, we used a translator webpage instead of spores containing the key.  
The procedure seems to be easy:
+
The procedure is as follows:
1) Put spores to grow
+
1) Grow spores
2) PCR with the primers delivered with the spores
+
2) PCR the encoded message
3) Put PCR product to sequencing
+
3) Sequence the PCR product
Unfortunately, the first attempts of PCRing the fragment in question failed. We tried to perform colony PCR and tested different changes in the protocol: longer initial denaturation time, higher dilution of colony, adding of DMSO. However, we could not obtain a PCR fragment. So, we chose to first isolate the genomic sequence of the bacteria. After this, we obtained a nice and distinct band that we sent to sequencing. Thus, we proposed to change the protocol from simple colony PCR to PCR from the isolated genome.
+
Unfortunately, the first attempts of PCR amplifying the message failed. We tried to perform colony PCR and tested different adjustments of the protocol: longer initial denaturation time, less DNA as template, addition of DMSO. However, we could not obtain the correct PCR fragment. Subsequently, we tried to isolate the genomic sequence of the bacteria first. After doing this we obtained a nice PCR product that was sent for sequencing. Thus, we proposed to change the protocol from colony PCR to PCR from isolated and purified genomic DNA.
 +
 +
The sequence we obtained was entered into the supplied website , leaving us with the following message: …..
 +
 
  
 
</p>
 
</p>

Revision as of 12:34, 10 October 2016

Wageningen UR iGEM 2016

 

Our philosophy when it comes to collaboration is that “collaboration leads to development of the innovation and its full acceptance and use”. Based on this, we did not only collaborate with other iGEM teams, but also with students from the Design Academy Eindhoven. The students from the DAE helped us gain insight into how people perceive our project and synthetic biology in general, while the collaboration with iGEM teams helped us move forward in a scientific way. We collaborated with two other iGEM teams: TU_Delft and Groningen. During this process, we also learned about their projects and helped each other out with some ideas. We even got some valuable input from both teams. Here’s what we have achieved in collaboration with them.

Delft

The team of TU Delft has been working on the creation of a biolaser in the form of a a biosilica-covered cell expressing fluorescent proteins. The biosilica-layer traps some of the photons sent out by fluorescent proteins that can be used to excite other fluorescent proteins. This leads to increased overall fluorescence intensity in the cells. We measured their strains in our plate reader. During our own project, we have worked with the microplate reader extensively. Likewise, testing the samples from TU_Delft was not just beneficial for them, it also added to our own expertise in handling the microplate reader. We tested eight different constructs in a microplate reader: three different BioBricks for expression of fluorescent proteins and expression of GFP with five different promoters. In short, we are content with the results we got and the practice we had gotten through this collaboration, and we are happy about this opportunity to help another team. Moreover, the Delft team did some experiments for us. For our in vitro toxicity assay with fluorophore-filled vesicles, we were hoping for a picture proving that we were indeed able to encapsulate fluorophores in vesicles. The TU Delft team helped us by making some nice pictures of our vesicles using an electron microscope! The results can be found here.

Groningen

For Groningen iGEM team, we tested and improved their system CryptoGERM. CryptoGERM was developed to encrypt messages in the DNA of Bacillus subtilis spores, that can only be decoded using a key that is also in a spore. We received a message to decrypt from Groningen. As we tested the system in an early stage, when it was not fully developed, we used a translator webpage instead of spores containing the key. The procedure is as follows: 1) Grow spores 2) PCR the encoded message 3) Sequence the PCR product Unfortunately, the first attempts of PCR amplifying the message failed. We tried to perform colony PCR and tested different adjustments of the protocol: longer initial denaturation time, less DNA as template, addition of DMSO. However, we could not obtain the correct PCR fragment. Subsequently, we tried to isolate the genomic sequence of the bacteria first. After doing this we obtained a nice PCR product that was sent for sequencing. Thus, we proposed to change the protocol from colony PCR to PCR from isolated and purified genomic DNA. The sequence we obtained was entered into the supplied website , leaving us with the following message: …..