Difference between revisions of "Team:TUDelft/Main-Measurement"

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<div class="collapsible-header">Perspectives for characterizing existing and future BioBricks</div>
 
<div class="collapsible-header">Perspectives for characterizing existing and future BioBricks</div>
 
     <div class="collapsible-body"><p>The nature of CINDY Seq is such that, in principle, it can be used to visualize any significant change in polymer length. As a result, this provides a promising outlook to characterize existing and future biobricks that involve the polymerization or degradation of coacervate-forming polymers (see Figure 3). Examples of such enzymes are: nucleases, proteases and amylases. Furthermore, it has been demonstrated that even the molecule ATP can form coacervates (<a href="#references">Jia et al. 2014</a>), so that one can even imagine to demonstrate energy consumption or ATP synthesis. </p>
 
     <div class="collapsible-body"><p>The nature of CINDY Seq is such that, in principle, it can be used to visualize any significant change in polymer length. As a result, this provides a promising outlook to characterize existing and future biobricks that involve the polymerization or degradation of coacervate-forming polymers (see Figure 3). Examples of such enzymes are: nucleases, proteases and amylases. Furthermore, it has been demonstrated that even the molecule ATP can form coacervates (<a href="#references">Jia et al. 2014</a>), so that one can even imagine to demonstrate energy consumption or ATP synthesis. </p>
<p>An obvious example of a BioBrick that can directly be characterised using the coacervation detection method is <a href="http://parts.igem.org/Part:BBa_K1923001:Design">BBa_K1923001</a>, encoding for a variant of Cas13a closely related to the one we have used in our project. With the coacervation detection method any crRNA and RNA target combination can be tested, for activating Cas13a, and even binary tests for off-target effects can be done by introducing mutations in the target RNA.</p>
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<p>An obvious example of a BioBrick that can directly be characterised using the coacervation detection method is <a href="http://parts.igem.org/Part:BBa_K1923001:Design" target="_blank">BBa_K1923001</a>, encoding for a variant of Cas13a closely related to the one we have used in our project. With the coacervation detection method any crRNA and RNA target combination can be tested, for activating Cas13a, and even binary tests for off-target effects can be done by introducing mutations in the target RNA.</p>
 
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         <img class="responsive-img" src="https://static.igem.org/mediawiki/2017/1/19/Polymerizationdegradation.png"/></div>
 
         <img class="responsive-img" src="https://static.igem.org/mediawiki/2017/1/19/Polymerizationdegradation.png"/></div>

Revision as of 23:49, 1 November 2017

One of the main aims within our project was to develop a detection method to detect the presence of specific RNA sequences without the use of any complicated laboratory equipment. Furthermore, this method should be cheap and widely available to everyone. We indeed succeeded in developing such a method and this page is dedicated to describe how this novel measurement method was implemented in our project. It is based on structures called 'coacervates'.

Coacervates are polymer-rich regions in solutions of mutually attractive polymers. The process of mutually attractive polymers phase-separating into a polymer-rich and polymer-poor phase is known as coacervation. This process can under some circumstances be observed by the naked eye, as coacervates generally cause solutions to be more turbid. A key physical property of coacervates is that they require polymers of a certain length to form. In general, only polymers that are ‘long enough’ form coacervates.

Figure 1: Schematic description of coacervation. Long, mutually attractive polymers can phase separate into dense, polymer-rich regions known as coacervates, and a polymer-poor region consisting of the solvent.

The underlying reason for this can be explained theoretically and experimentally. These latter facts directly imply that (changes in) polymer length can be visualized to the naked eye, which we utilized to design a novel detection method coined CINDY Seq. However, as we will argue in greater detail below, the method has potential to serve as a far broader method to characterize existing and future BioBricks, and the activity of many enzymes that show synthesis or degradation of any (coacervating) polymer.