Difference between revisions of "Team:London Biohackspace/Design"

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<h3>Miraculin expression</h3>
 
<h3>Miraculin expression</h3>
<p>is a protein found naturally in the fruits of the Miracle Berry plant Synsepalum dulcificum and has been found to make sour foods taste sweeter. The taste altering property of Miraculin therefore means it has potential use as an artificial sweetener and makes for a healthier alternative to natural sugars found in most products.</p>
+
<p>Miraculin is a protein found naturally in the fruits of the Miracle Berry plant Synsepalum dulcificum and has been found to make sour foods taste sweeter. The taste altering property of Miraculin therefore means it has potential use as an artificial sweetener and makes for a healthier alternative to natural sugars found in most products. We have designed a yeast strain expressing the miraculin protein which will create a beer with this interesting falvour additive.</p>
  
 
<h3>Lycopene biosynthesis</h3>
 
<h3>Lycopene biosynthesis</h3>
<p>Lycopene is a carotenoid compound that can be found in tomatoes and many other red fruits. We have designed a yeast strain containing the three enzymes responsible for the biosynthesis of lycopene which will create red pigmented beer. Research into the nutritional value of lycopene also suggests that it acts as an antioxidant and therefore has a number of health benefits when consumed as part of a balanced diet.</p>
+
<p>Lycopene is a carotenoid compound that can be found in tomatoes and many other red fruits. We have designed a yeast strain expressing the three enzymes (CrtE, CrtB, CrtI) responsible for the biosynthesis of lycopene which will create red pigmented beer. Research into the nutritional value of lycopene also suggests that it acts as an antioxidant and therefore has a number of health benefits when consumed as part of a balanced diet.</p>
  
<h3>Beta-ionone (Raspberry ketone) biosynthesis</h3>
+
<h3>Beta-ionone biosynthesis</h3>
<p>Beta-ionone is a flavour compound found in raspberry plants that will confer and gives adistinctly derives from the precursor lycopene.  </p>
+
<p>Raspberry ketone is a flavour compound found in raspberry plants that has a distinctly raspberry-like flavour.  to and gives adistinctly derives from the precursor lycopene.  </p>
  
 
<h3>ATF1 overexpression</h3>
 
<h3>ATF1 overexpression</h3>
Line 71: Line 71:
  
 
<h3>Filtration method for competent cells preparation</h3>
 
<h3>Filtration method for competent cells preparation</h3>
<p>An easy, cheap and automated (convenient) method for preparing competent cells in a community lab without a -80 freezer.</p>
+
<p>An easy, cheap and automated (convenient) method for preparing competent cells in a community lab without a -80 freezer. <a href="/Team:London_Biohackspace/protocols/filtercomp">More...</a></p>
  
<h3>SPLiCE vector assembly</h3>
+
<h3>SLPiCE vector assembly</h3>
<p>An easy and cheap method for assembling vectors without the need for expensive purified restriction enzymes and ligases. A great method for community labs to lower the cost of constructing vectors.</p>
+
<p>We have developed an easy and cheap method for assembling vectors without the need for expensive purified restriction enzymes and ligases. A great method for community labs to lower the cost of constructing vectors. <a href="/Team:London_Biohackspace/protocols/egassembly">More...</a></p>
  
 
<h3>RNA interference based regulation</h3>
 
<h3>RNA interference based regulation</h3>
<p>set of genetic parts that will allow users to modify the expression levels of these genes via RNA interference so that the strains can be tuned.</p>
+
<p>We have developed a set of genetic parts that will allow users to modify the expression levels of genes inserted into yeast via RNA interference so that the novel brewing strains can be tuned. <a href="/Team:London_Biohackspace/experiments/rna-based-regulation">More...</a></p>
  
 
<h3>Creating Leucine auxotrophic S. cerevisiae strains</h3>
 
<h3>Creating Leucine auxotrophic S. cerevisiae strains</h3>
<p>protocols for producing auxotroph mutants of existing brewing strains in order to subsequently add new genes - The first step in creating novel brewing yeast strains is to modify an existing strain that has either been purchased from a home brew supplier or isolated from a bottle of beer so that it becomes auxotrophic for a particular key nutrient.  This is an essential step as it provides a means to select subsequent strains that have been further genetically modified.  The SYNBIO Brewery DIY-Brewkit will contain genes part that creates auxotrophic mutants lacking the ability to synthesize uracil and leucine that are key amino acids required for protein synthesis.  These mutant strains will therefore only grow on a media containing uracil or leucine or via further genetic modification which restores the strains ability to synthesize these amino acids.</p>
+
<p>We have developed protocols for producing auxotroph mutants of existing brewing strains. The first step in creating novel brewing yeast strains is to modify an existing strain that has either been purchased from a home brew supplier or isolated from a bottle of beer so that it becomes auxotrophic for a particular key nutrient.  This is an essential step as it provides a means to select subsequent strains that have been further genetically modified.  We have designed a set of genes parts that enable the user to create auxotrophic mutants lacking the ability to synthesize uracil and leucine that are key amino acids required for protein synthesis.  These mutant strains will therefore only grow on a media containing uracil or leucine or via further genetic modification which restores the strains ability to synthesize these amino acids.</p>
  
  

Revision as of 01:18, 19 September 2015

The Motivation

We want to introduce a whole new group of people to the DIYBio community using the exciting products of synthetic biology. The DIYBio community is still a nascent one, and we believe it has the potential to become a big thing (hopefully a really big thing). The SynBio Brewery DIY Brew Kit is therefore designed to get members of the home-brewing and micro-brewing community interested in DIYBio and synthetic biology - who better to get involved, than people that are already familiar with manipulating biology to do their bidding?

What is the Synbio Brewery DIY-Brewkit

The SynBio Brewery DIY-Brewkit is a package containing everything an established home-brewer or micro-brewer needs to start making beer with a synbio twist. Each basic package contains six GM brewing yeast strains - each of which adds one novel property to the beer brewed with it. We hope brewers will start to experiment with different combinations and quantities of our yeast strains to produce truly unique beers. Each kit also contains a simple explanation of what each strain does and the science behind it as well as resources to help the brewers dig deeper into how to go about making new strains themselves as DIY-biologists. More about the design of the kit.

The Strains

We have designed a number of strains as a starting point for the yeast library that brewers can use to easily enhance the flavour, smell, colour and nutritional content of their beer:

Miraculin expression

Miraculin is a protein found naturally in the fruits of the Miracle Berry plant Synsepalum dulcificum and has been found to make sour foods taste sweeter. The taste altering property of Miraculin therefore means it has potential use as an artificial sweetener and makes for a healthier alternative to natural sugars found in most products. We have designed a yeast strain expressing the miraculin protein which will create a beer with this interesting falvour additive.

Lycopene biosynthesis

Lycopene is a carotenoid compound that can be found in tomatoes and many other red fruits. We have designed a yeast strain expressing the three enzymes (CrtE, CrtB, CrtI) responsible for the biosynthesis of lycopene which will create red pigmented beer. Research into the nutritional value of lycopene also suggests that it acts as an antioxidant and therefore has a number of health benefits when consumed as part of a balanced diet.

Beta-ionone biosynthesis

Raspberry ketone is a flavour compound found in raspberry plants that has a distinctly raspberry-like flavour. to and gives adistinctly derives from the precursor lycopene.

ATF1 overexpression

OneProt2 expression

Community resources for growing the brew kit yeast library

We have great hope that brewers and already established members of the DIYBio community will want to create new strains of yeast and add to our open source strain library. TO facilitate this, we have designed a set of genetic parts and protocols to enable the community to more easily produce new and interesting yeast strains from existing commercially available brewing strains. Additionally, these open-source tools for working with yeast are primarily designed to work in a community lab setting, thus we hope to lower the entry barrier for new and existing community labs looking to participate in iGEM as well as making it easier for community labs to share resources.

Filtration method for competent cells preparation

An easy, cheap and automated (convenient) method for preparing competent cells in a community lab without a -80 freezer. More...

SLPiCE vector assembly

We have developed an easy and cheap method for assembling vectors without the need for expensive purified restriction enzymes and ligases. A great method for community labs to lower the cost of constructing vectors. More...

RNA interference based regulation

We have developed a set of genetic parts that will allow users to modify the expression levels of genes inserted into yeast via RNA interference so that the novel brewing strains can be tuned. More...

Creating Leucine auxotrophic S. cerevisiae strains

We have developed protocols for producing auxotroph mutants of existing brewing strains. The first step in creating novel brewing yeast strains is to modify an existing strain that has either been purchased from a home brew supplier or isolated from a bottle of beer so that it becomes auxotrophic for a particular key nutrient. This is an essential step as it provides a means to select subsequent strains that have been further genetically modified. We have designed a set of genes parts that enable the user to create auxotrophic mutants lacking the ability to synthesize uracil and leucine that are key amino acids required for protein synthesis. These mutant strains will therefore only grow on a media containing uracil or leucine or via further genetic modification which restores the strains ability to synthesize these amino acids.