Difference between revisions of "Team:Austin UTexas/Results"

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<u>Approach</u>
 
<u>Approach</u>
<p> Two potential ways to reduce ethanol content over the course of the fermentation are to reduce the rate at which yeast produce ethanol or increase the rate at which acetic acid bacteria convert the ethanol to acetic acid. The first of these methods is the most direct approach, and was the first method considered. We considered UV mutagenizing <i>Lachancea fermentati</i>, a yeast our lab has isolated from kombucha, and then screening for ethanol production using a pH indicator, bromothymol blue, in media (<b>Figure 1</b>). Bromothymol blue is blue at basic pH, turns green around pH 7, and turns yellow around pH 6, and has been used previously to screen for fermentation rate among <i>Saccharomyces cerevisiae</i> colonies.<sup>#</sup> During anaerobic respiration, both ethanol and CO2 are produced, and CO2 reacts with water to form carbonic acid, lowering the pH of the plate and changing the color of the indicator. A variety of problems with this approach led us to abandon it. It is likely that <i>L. fermentati</i> produce other acidic metabolic products, so pH would not necessarily correspond to amount of ethanol produced. This assay also relies on distinguishing differences in color in the agar to tell the difference in ethanol production between two colonies, a process that would be somewhat subjective. Additionally, the ethanol produced is necessary for the production of acetic acid, so slowing the rate of ethanol production would likely have slowed the production of the beverage and could have thrown off the flavor. For all these reasons, attempting to decrease the rate of ethanol production by <i>L. fermentati</i> does not seem like a good approach to lowering the ethanol content during the fermentation.</p>
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<p>Two potential ways to reduce ethanol content over the course of the fermentation are to reduce the rate at which yeast produce ethanol or increase the rate at which acetic acid bacteria convert the ethanol to acetic acid. The first of these methods is the most direct approach, and was the first method considered. We considered UV mutagenizing <i>Lachancea fermentati</i>, a yeast our lab has isolated from kombucha, and then screening for ethanol production using a pH indicator, bromothymol blue, in media (<b>Figure 1</b>). Bromothymol blue is blue at basic pH, turns green around pH 7, and turns yellow around pH 6, and has been used previously to screen for fermentation rate among <i>Saccharomyces cerevisiae</i> colonies.<sup>9</sup> During anaerobic respiration, both ethanol and CO2 are produced, and CO2 reacts with water to form carbonic acid, lowering the pH of the plate and changing the color of the indicator. A variety of problems with this approach led us to abandon it. It is likely that <i>L. fermentati</i> produce other acidic metabolic products, so pH would not necessarily correspond to amount of ethanol produced. This assay also relies on distinguishing differences in color in the agar to tell the difference in ethanol production between two colonies, a process that would be somewhat subjective. Additionally, the ethanol produced is necessary for the production of acetic acid, so slowing the rate of ethanol production would likely have slowed the production of the beverage and could have thrown off the flavor. For all these reasons, attempting to decrease the rate of ethanol production by <i>L. fermentati</i> does not seem like a good approach to lowering the ethanol content during the fermentation.</p>
<p>We next considered increasing the rate at which acetic acid bacteria in kombucha convert ethanol to acetic acid. Increasing this rate would utilize more ethanol as it is produced, ideally lowering the ethanol content throughout the course of the fermentation. Two enzymes facilitate steps in this pathway.<sup>#</sup> An alcohol dehydrogenase (PQQ-ADH) enzyme facilitates the conversion of ethanol to acetaldehyde, and a membrane-bound aldehyde dehydrogenase (ALDH) facilitates the conversion of acetaldehyde to acetic acid. In order to increase the rate at which ethanol is converted into acetic acid, we propose using Golden Gate Assembly to create a genetic construct in which expression of PQQ-ADH and ALDH is governed by a Tac-promoter (pTac), a hybrid promoter which is inhibited except in the presence of allolactose.  The construct would be transformed into electrocompetent <i>Escherichia coli</i> and transferred to <i>Gluconacetobacter hansenii</i> via conjugation.</p>
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<p>We next considered increasing the rate at which acetic acid bacteria in kombucha convert ethanol to acetic acid. Increasing this rate would utilize more ethanol as it is produced, ideally lowering the ethanol content throughout the course of the fermentation. Two enzymes facilitate steps in this pathway.<sup>6</sup> An alcohol dehydrogenase (PQQ-ADH) enzyme facilitates the conversion of ethanol to acetaldehyde, and a membrane-bound aldehyde dehydrogenase (ALDH) facilitates the conversion of acetaldehyde to acetic acid. In order to increase the rate at which ethanol is converted into acetic acid, we propose using Golden Gate Assembly to create a genetic construct in which expression of PQQ-ADH and ALDH is governed by a Tac-promoter (pTac), a hybrid promoter which is inhibited except in the presence of allolactose.  The construct would be transformed into electrocompetent <i>Escherichia coli</i> and transferred to <i>Gluconacetobacter hansenii</i> via conjugation.</p>
 
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<u>Identifying genes of interest</u>
 
<u>Identifying genes of interest</u>
 
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In order to design a construct increasing expression of PQQ-ADH and ALDH in <i>Ga. hansenii</i>, it was necessary to find the genome of the ATCC strain and identify the coding sequences for these genes. The whole genome shotgun sequence for our organism, ATCC 53582, is published on NCBI<sup>1</sup> with annotations regarding the functions of specific sequences. Coding sequences are annotated with proposed gene products. Though there are several aldehyde dehydrogenase genes annotated in the genome, there is only one which is described as membrane-bound, matching the description from Mamlouk and Gullo (2013). There are additionally multiple alcohol dehydrogenases. A known amino acid sequence for a homologous PQQ-ADH in ,i.Comamonas testosteroni</i> was compared against sequences in the <i>Ga. hansenii</i> genome using BLAST (<b>Table 1</b>). One ADH enzyme found in the <i>Ga. hansenii</i> genome sequence matches the <i>C. testosteroni</i> sequence with a query cover value of 94% and an E value of 0 (third line of <b>Table 1</b>).</p>
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In order to design a construct increasing expression of PQQ-ADH and ALDH in <i>Ga. hansenii</i>, it was necessary to find the genome of the ATCC strain and identify the coding sequences for these genes. The whole genome shotgun sequence for our organism, ATCC 53582, is published on NCBI<sup>1</sup> with annotations regarding the functions of specific sequences. Coding sequences are annotated with proposed gene products. Though there are several aldehyde dehydrogenase genes annotated in the genome, there is only one which is described as membrane-bound, matching the description from Mamlouk and Gullo.<sup>6</sup> There are additionally multiple alcohol dehydrogenases. A known amino acid sequence for a homologous PQQ-ADH in ,i.Comamonas testosteroni</i> was compared against sequences in the <i>Ga. hansenii</i> genome using BLAST (<b>Table 1</b>). One ADH enzyme found in the <i>Ga. hansenii</i> genome sequence matches the <i>C. testosteroni</i> sequence with a query cover value of 94% and an E value of 0 (third line of <b>Table 1</b>).</p>
 
<p><u>Creation of Golden Gate parts</u>
 
<p><u>Creation of Golden Gate parts</u>
 
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Revision as of 02:52, 19 October 2016

Results


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