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<h2> Ethanol </h2> | <h2> Ethanol </h2> | ||
− | <P> During the fermentation process, yeast in kombucha produce ethanol, the type of alcohol present in beer, wine, and other alcoholic beverages. This presents a challenge to kombucha brewers who wish to market their product as a non-alcoholic beverage. If the alcohol content of a manufacturer’s kombucha exceeds 0.5% at any point during production, the manufacturer may not market their beverage as non-alcoholic and must be regulated as a producer of alcoholic beverages.<sup>1</sup> One way to tackle this problem with synthetic biology is to ferment with yeast that produce less ethanol. However, this may be impractical. Some bacteria in the | + | <P> During the fermentation process, yeast in kombucha produce ethanol, the type of alcohol present in beer, wine, and other alcoholic beverages. This presents a challenge to kombucha brewers who wish to market their product as a non-alcoholic beverage. If the alcohol content of a manufacturer’s kombucha exceeds 0.5% at any point during production, the manufacturer may not market their beverage as non-alcoholic and must be regulated as a producer of alcoholic beverages.<sup>1</sup> One way to tackle this problem with synthetic biology is to ferment with yeast that produce less ethanol. However, this may be impractical. Some bacteria in the brew oxidize ethanol produced by the yeast to produce acetic acid, which is a major component of the beverage’s distinctive, tart flavor. </p> |
<p>Another approach is to increase the rate at which the bacteria convert the ethanol to acetic acid. Two enzymes are responsible for this process: an alcohol dehydrogenase and an aldehyde dehydrogenase.<sup>2</sup> Using Golden Gate assembly, we plan to assemble a construct containing the coding sequences for these genes and insert the construct into <i>Gluconacetobacter hansenii</i>, an acetic acid-producing bacterium similar to those found in kombucha. Then, we plan to recapitulate kombucha with both the transformed and control <i>Ga. hansenii</i> to evaluate the ethanol content over the course of the fermentation with gas chromatography-mass spectrometry. We also plan to determine whether increasing the acetic acid production will lead to a pH change that could affect the flavor of the beverage by testing the pH and observing the cultures for visible differences. If we are able to create a microbial community that results in a lower ethanol content within the kombucha during fermentation, kombucha brewers could use the modified bacterium to help ensure the ethanol content of their product stays below the legal limit. | <p>Another approach is to increase the rate at which the bacteria convert the ethanol to acetic acid. Two enzymes are responsible for this process: an alcohol dehydrogenase and an aldehyde dehydrogenase.<sup>2</sup> Using Golden Gate assembly, we plan to assemble a construct containing the coding sequences for these genes and insert the construct into <i>Gluconacetobacter hansenii</i>, an acetic acid-producing bacterium similar to those found in kombucha. Then, we plan to recapitulate kombucha with both the transformed and control <i>Ga. hansenii</i> to evaluate the ethanol content over the course of the fermentation with gas chromatography-mass spectrometry. We also plan to determine whether increasing the acetic acid production will lead to a pH change that could affect the flavor of the beverage by testing the pH and observing the cultures for visible differences. If we are able to create a microbial community that results in a lower ethanol content within the kombucha during fermentation, kombucha brewers could use the modified bacterium to help ensure the ethanol content of their product stays below the legal limit. | ||
</p> | </p> |
Revision as of 19:14, 19 October 2016
Project Description
Gold Medal Part Characterization
The characterization of the BioBrick P-atp2 from the BIT-China-2015 team was done to see if P-atp2 could be utilized as a basic pH sensor. The results are found here and on the iGEM Registry page under experience, BBa_K1675021
Our Project
Kombucha is a beverage made when a symbiotic community of bacteria and yeast ferments sugared tea. Although kombucha has been consumed for thousands of years in the East, the drink has enjoyed a recent surge in popularity.1 Several kombucha breweries operate in Austin, Texas, our team’s hometown. The role microbes play in the production of the beverage has led our team to wonder if synthetic biology could allow us to create “designer kombucha” with enhanced properties, such as more appealing flavors or additional nutrients. In order to do so, our team attempted to isolate the strains responsible for the fermentation of kombucha, identify them, genetically modify them, and add the individual strains into tea media to recreate the drink. We additionally considered potential applications of the ability to genetically modify the microbial population of kombucha, such as reducing the ethanol content of the beverage and improving taste with brazzein, a sweet-tasting protein. In consideration of Human Practices, we reached out to the Austin kombucha community to learn more about what kombucha brewers and consumers would want in a customizable kombucha. Through this interaction, we learned that many kombucha consumers and manufacturers value the traditional, all-natural process of producing the beverage, and that many in the industry would be apprehensive of kombucha made with genetically modified organisms. Though we hope increased public awareness of synthetic biology may someday make a genetically modified kombucha marketable, the current attitudes of kombucha consumers have led us to consider methods of creating designer kombucha that rely only on natural genetic variation.
References
Click the images below to learn more about our project!
Kombucha Strains
Conjugation
Recapitulation
Ethanol
Brazzein
pH Sensors