Difference between revisions of "Team:Aalto-Helsinki/Community"

m
 
(5 intermediate revisions by 2 users not shown)
Line 32: Line 32:
 
   <div style="height:100%">
 
   <div style="height:100%">
 
   <section class="collabphoto parallax" style="text-align:center">
 
   <section class="collabphoto parallax" style="text-align:center">
     <h2 class="title">
+
     <h2 class="title" style="padding-top: 0;">
 
     Community
 
     Community
 
     </h2>
 
     </h2>
Line 109: Line 109:
 
   <div class="block-wrapper-inner" style="padding-top: 15px;">
 
   <div class="block-wrapper-inner" style="padding-top: 15px;">
 
     <div class="container" style="width: 75%; font-family: robotolight; color: #4d4d33">
 
     <div class="container" style="width: 75%; font-family: robotolight; color: #4d4d33">
 +
    <br/>
 
     <br/>
 
     <br/>
 
     <h1 id="ZERO">
 
     <h1 id="ZERO">
Line 142: Line 143:
 
       <b>
 
       <b>
 
       <u>
 
       <u>
         1
+
         1</u>
      </u>
+
 
       </b>
 
       </b>
      part is on the registry’s list of well characterized parts.
+
      part is on the registry’s list of well characterized parts.
 
     </p>
 
     </p>
 
     <p class="justify" style="font-size:19px">
 
     <p class="justify" style="font-size:19px">
Line 154: Line 154:
 
     </p>
 
     </p>
 
     <p class="justify" style="font-size:19px">
 
     <p class="justify" style="font-size:19px">
       Having the BioBricks prefix, and thus the XbaI restriction site directly upstream of the protein coding sequence, would result in a T as the -3 base upstream of the start codon. It has been reported that in eukaryotic translation initiation, the -3 base is optimally an A or G (Kozak, 1996). This base is key in defining translation initiation, as changing it into a T or C increases sensitivity to differences in other bases upstream of the start codon. Cavener et al. (1991) on the other hand showed that yeast has a strong bias for A in this position. Because of this, protein-coding BioBricks would always require the direct fusion of a ribosome binding site upstream of the start codon in order for them to be usable within the context of the standard prefix and suffix. This, in turn, makes the use of non-BioBrick backbones difficult, as these promoters might already be suitable to clone a protein-coding sequence into them without any specific fusions.
+
       Having the mixed XbaI-SpeI restriction site resulting from the ligation of two biobricks directly upstream of the protein coding sequence would result in a T as the -3 base upstream of the start codon. It has been reported that in eukaryotic translation initiation, the -3 base is optimally an A or G (Kozak, 1996). This base is key in defining translation initiation, as changing it into a T or C increases sensitivity to differences in other bases upstream of the start codon. Cavener et al. (1991) on the other hand showed that yeast has a strong bias for A in this position. Because of this, protein-coding BioBricks would always require the direct fusion of a ribosome binding site upstream of the start codon in order for them to be usable within the context of the standard prefix and suffix. This, in turn, makes the use of non-BioBrick backbones difficult, as the promoters in these plasmids might already be suitable to clone a protein-coding sequence into them without any specific fusions. In addition, adaptation of <i>E. coli</i> biobricks for yeast, and variation in yeast ribosome binding sites, is made more difficult
 
     </p>
 
     </p>
 
     <p class="justify" style="font-size:19px">
 
     <p class="justify" style="font-size:19px">
       Particularly with the DNA synthesis deal iGEM has had with IDT in the last two years, and constantly lowering DNA synthesis costs, the importance of being able to obtain physical part copies from the registry is lower than ever before. For this reason, we find the requirements of the current assembly standard to be restrictive and limiting.
+
       Particularly with the DNA synthesis deal iGEM has had with IDT, and constantly lowering DNA synthesis costs, the importance of being able to obtain physical part copies from the registry is lower than ever before. For this reason, we find the requirements of the current assembly standard to be restrictive and limiting: assembling yeast biobricks with e.g. gBlock synthesis allows usage of the parts in much more suitable environments than the BioBricks context, which would require PCR modification.  
 
     </p>
 
     </p>
 
     <p class="justify" style="font-size:19px">
 
     <p class="justify" style="font-size:19px">
 
       Ultimately, we believe that the most important function of the parts registry is the sharing of information about different parts and their function, and increasing understanding of parts’ interaction to facilitate the predictable engineering of biological systems. This purpose is no longer served when the delivery of physical part copies becomes a priority and limitation in itself. The current requirements set limitations that prevent progression in the field of synthetic biology, as teams are discouraged from pushing into uncharted territory. Our team sees great potential in the use of yeast as a chassis in future projects, but current iGEM criteria set limitations to the convenience of its use.
 
       Ultimately, we believe that the most important function of the parts registry is the sharing of information about different parts and their function, and increasing understanding of parts’ interaction to facilitate the predictable engineering of biological systems. This purpose is no longer served when the delivery of physical part copies becomes a priority and limitation in itself. The current requirements set limitations that prevent progression in the field of synthetic biology, as teams are discouraged from pushing into uncharted territory. Our team sees great potential in the use of yeast as a chassis in future projects, but current iGEM criteria set limitations to the convenience of its use.
 
     </p>
 
     </p>
 +
  <br/>
 +
    <br/>
 +
 
     <p class="justify" style="font-size:19px">
 
     <p class="justify" style="font-size:19px">
 
       <b>
 
       <b>
Line 181: Line 184:
 
       ,  44(2), pp. 283-292
 
       ,  44(2), pp. 283-292
 
     </p>
 
     </p>
    </div>
 
    <br/>
 
    <br/>
 
    <br/>
 
    <br/>
 
 
   </div>
 
   </div>
 
   <div class="block-wrapper-inner" style="padding-top: 15px;">
 
   <div class="block-wrapper-inner" style="padding-top: 15px;">
Line 627: Line 625:
 
       </a>
 
       </a>
 
       <br/>
 
       <br/>
       <a href="" id="b">
+
       <a href="https://static.igem.org/mediawiki/2016/c/c5/InterLab_iGEM2016_Plate_Reader_Protocol_Updated_July.pdf" id="b">
 
       [2] Plate Reader Protocol
 
       [2] Plate Reader Protocol
 
       </a>
 
       </a>

Latest revision as of 09:51, 3 December 2016

Aalto-Helsinki

Community