Difference between revisions of "Team:Washington/Auxin"

 
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                 <li>Aptamer                                
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                                 <a href="https://2015.igem.org/Team:Washington/Aptamer#Introduction">Introduction</a>
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                                 <a href="https://2015.igem.org/Team:Washington/Aptazyme#Introduction">Introduction</a>
 
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                                 <a href="https://2015.igem.org/Team:Washington/Aptamer#Methods">Methods</a>
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                                 <a href="https://2015.igem.org/Team:Washington/Aptamer#Results">Results</a>
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                                 <a href="https://2015.igem.org/Team:Washington/Aptamer#Conclusion">Conclusion</a>
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                                 <a href="https://2015.igem.org/Team:Washington/Aptazyme#Conclusion">Conclusion</a>
 
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                             <a href="https://2015.igem.org/Team:Washington/Paper_Device#Methods">Methods</a>
 
                             <a href="https://2015.igem.org/Team:Washington/Paper_Device#Methods">Methods</a>
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                                <a href="https://2015.igem.org/Team:Washington/Design">Design</a>
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                                <a href="https://2015.igem.org/Team:Washington/Paper_Device#Results">Results</a>
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                                <a href="https://2015.igem.org/Team:Washington/Paper_Device#Conclusion">Conclusion</a>
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                 <h2>
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                 <h1 align = "center">
                     <div id="Introduction">Introduction: Auxin-IAA Pathway</div>
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                     <div id="Introduction">Introduction: Auxin Pathway</div>
                 </h2>
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                 </h1>
                 <h2> Prior CRISPR transcriptional factors </h2>
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                 <h2>CRISPR Transcriptional Factors</h2>
 
                  
 
                  
                 <p>CRISPR transcriptional factors enable scientists to make targeted changes in gene expression through the use of gRNA. The gRNA attaches to the CRISPR associated protein, and guide it to a specific DNA locus based on the sequence of the gRNA.  The CRISPR proteins we used were obtained from the Klavins lab, and are designed so that they do not cleave the DNA strands themselves, but will instead bind tightly and prevent access to the gene by other proteins. This effectively disables transcription and translation of the targeted gene.  CRISPR transcriptional factors were first developed by Perez-Pinera et al. in 2013.</p>
+
                 <p align = "justify"> CRISPR transcriptional factors enable scientists to make targeted changes in gene expression through the use of a guide RNA (gRNA). The gRNA attaches to the CRISPR protein, and guides it to a specific DNA locus based on the sequence of the gRNA.  The CRISPR proteins we used known as dCas9 were obtained from the Klavins lab, and are designed so that they do not cleave the DNA strands themselves, this dead CRISPR will instead bind tightly and prevent access to the gene by other proteins. This effectively disables transcription and translation of the targeted gene.  CRISPR transcriptional factors were first developed by Perez-Pinera et al. in 2013. </p>
                <p> Auxin is a class of plant hormone that is involved in developmental and behavioral signalling.  This type of molecule serves as a good proof-of-concept for the detection of small-molecules by our model system. This is because our Auxin can pass through the cell membrane and bind to an F-box protein (AFB2) and a degron (deg1), which will then target our dCas9 protein for degradation.  Indole-3-acetic acid (IAA) is the specific Auxin molecule that we are using in our model system.</p>
+
  
                 <h2>
+
                 <h2>Auxin Background</h2>
                    <div id="Methods">Auxin Design:</div>
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                </h2>
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<p>The pathway relies on several components. Firstly, a dead-CRISPR transcription factor fused to a degron domain and a repressor domain. Along with a guide RNA designed to target and upstream activating site. Combined the dCas9 complex along with the guide RNA will suppress the expression of beta-galactosidase.<img src="https://static.igem.org/mediawiki/2015/8/81/Igem_auxin_2.jpeg" align="right"> However, in the presence of IAA and an F-Box protein, the dCas9 complex will be degraded and beta-galactosidase will be expressed. Thus, causing another small molecule X-Gal to be converted into indigo and appear blue, a color response. The system is designed to produce a response (a color response in our case) to the presence of the small molecule indole-3-acetic acid.</p>
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<img src="https://static.igem.org/mediawiki/2015/8/8b/Auxin_washington_design.jpeg" height="200" width="1089">
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<p>(1) dCas9-deg1-MXI1 binds to a guide RNA which targets a sequence of a LacZ promoter causing the expression of beta-galactosidase to be suppressed. </p>
+
              <p align = "justify" > Auxin is a class of plant hormone that is involved in developmental and behavioral signalling.  This type of molecule serves as a good proof-of-concept for the detection of small-molecules by our model system. This is because Auxin can pass through the cell membrane and bind to an F-box protein (AFB2) and a degron (deg1), which will then target our dCas9 protein for degradation. Additionally, auxin is orthogonal to the biochemical machinery of the yeast, allowing for uninterrupted signal processing. Indole-3-acetic acid (IAA) is the specific Auxin molecule that we are using in our model system.</p>
<p>(2) Auxin binds to both AFB2 (which also helps recruit the ubiquitin ligase) and deg1 simultaneously bringing the two into close proximity allowing the ubiquitin ligase to ubiquitinate the dCas9 construct. </p>
+
<p>(3) LacZ expression is no longer suppressed allowing beta galactosidase to be produced and in the presence of x-gal, indigo is then formed. </p>
+
  
<p>The CRISPR transcriptional factor is an optimal method for sensing molecules because the components can be optimized and substituted.  In this case, the AFB2 protein serves as the F-box and the Deg1 protein serves as the degron. </p>
+
                <h2> Model System Design </h2>
  
 +
<p align = "justify">  The pathway relies on several components. A dead-CRISPR transcription factor (dCas9) is  fused to a degron domain (Deg1) and a strong repressor domain (MXI1). Along with a guide RNA designed to target an a promoter region for a signal response. Combined, the dCas9 complex along with the guide RNA will suppress the expression of lacZ. However, in the presence of IAA and an F-Box protein (AFB2), the dCas9 complex will be degraded and lacZ will be expressed leading to the production of beta-galactosidase. Thus, causing another small molecule X-gal to be converted into indigo when cleaved by beta-galactosidase and appear blue. The system is designed to produce a response (a color response in our case) to the presence of the small molecule indole-3-acetic acid. </p>
  
                <h2>Test Strip Design</h2>
+
<p align = "center"> <img src="https://static.igem.org/mediawiki/2015/8/8b/Auxin_washington_design.jpeg" height="200" width="900"> </p>
                <p>The design for the yeast biosensor needs to create an ideal environment for the culture.</p>
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<img src="https://static.igem.org/mediawiki/2015/0/02/Igem_auxin_test_strip.jpeg" height="300" width="626">
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                <p>The base of the test strip, chromatography paper, The PDMS is ideal for a test strip because it is manufactured rapidly at a low cost.  The PDMS window allows small molecule-gasses to permeate but not foreign contaminants.  The one-way valve would most likely have a connection to a small pipette that could deposit medium evenly across the yeast cells.  The chromatography paper spreads the test solution evenly so that different sections of the yeast media have the same concentration of test solution.  In this way, the indigo color will be even and predictable in the yeast section.  A section of the strip will have yeast that constitutively expresses indigo as a control to ensure that the rehydration is functional.
+
</p>
+
  
                <h2>Lateral Flow Test Strip Background</h2>
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<p style="font-size:12px" align = "justify">(1) dCas9-deg1-MXI1 binds to a guide RNA which targets a sequence of a lacZ promoter causing the expression of beta-galactosidase to be supprefont size = 2ssed. (2) Auxin binds to both AFB2 (which also helps recruit the ubiquitin ligase)  and deg1 simultaneously bringing the two into close proximity allowing the ubiquitin ligase to ubiquitinate the dCas9 construct. (3) lacZ expression is no longer suppressed allowing beta galactosidase to be produced and in the presence of X-gal, indigo is then formed. </p>
                 <p>In a typical lateral flow assay, there are enzymes in the test strip that are in a dried salt and sugar mix. </p>
+
 
 +
<p align = "center"> <img src="https://static.igem.org/mediawiki/2015/8/81/Igem_auxin_2.jpeg"> </p>
 +
 
 +
          <h2>
 +
                 <div id="Methods"> Methods </div>
 +
          </h2>
 +
 
 +
<p align = "justify"> Since the system requires 4 components (AFB2, dCas9-deg1-MXI1, lacZ, gRNA) to be transformed into a single cell, our team decided to integrate each component into the yeast genome sequentially using a "cassette". A genomic integration has the advantage that cells are less likely to loose the genetic information once acquired into the cells genome. This saves time and effort and by-passes and potential problem with multiple dropout media for marker selections during each sequential transformation. The Klavins Lab at the University of Washington, allowed us access to their genetically modified Saccharomyces Cerevisiae strain that has a partially deleted uracil, histidine, leucine and tryptophan autotrophic gene, making the strain incapable of surviving without the aforementioned amino acids. With our strain selected we proceeded to sequentially transform each component of auxin detection pathway. </p>
 +
 
 +
<p align = "justify"> Each of the 4 genetic components of our system were contained within plasmids containing an ampicillin resistance marker and were cloned and amplified in E.Coli. Furthermore, each the component's plasmid also contained a different yeast autotrophic selection marker as followed: AFB2 Leucine, dCas9 Tryptophan, lacZ Uracil, gRNA Histidine. The plasmid is digested with PME1 creating the gene cassette which, is then transformed into our yeast strain and each autotrophic marker-gene construct would then integrate into the yeast genome. A sequential transformation was carried out in which a component was transformed and the new strain grown on selective (amino acid drop-out) media and then transformed with another component and grown on a different selective media sequentially until all 4 components were successfully integrated. The final strain could then be grown on a selective media with all 4 amino acid removed which, acts as a final check to ensure all components have been integrated into the genome. </p> 
 +
 
 +
<p align = "justify"> X-gal assays were run as followed. An aliquot of an overnight culture was diluted and incubated at 30C for 5 hours, for cultures containing the gRNA, auxin was added to the aliquot. After 5 hours, the cultures were pelleted and lysed and X-gal was added. The subsequent lysate was incubated at 37C. Blue color begins to show faintly after 30 minutes to 1 hour. A much deeper blue that is much easier to visualize was seen after 8-24 hours either at room temperature or in an incubator. </p>
 +
 
 +
<p style="font-size:12px" align = "center"> <img src="https://static.igem.org/mediawiki/2015/thumb/f/f4/AUXIN_TWO_SAMPLEs_bGAL_and_bGAL%2BgRNA.jpeg/320px-AUXIN_TWO_SAMPLEs_bGAL_and_bGAL%2BgRNA.jpeg"> </p>
 +
 
 +
<p style="font-size:12px" align = "center"> Two cell lysates in vials in which X-gal has been converted into indigo after a 24 hour incubation. Top vial shows that the system responds to the presence of auxin and produces beta-galactosidase. Bottom vial lacks cells that lack the gRNA and therefore does not require auxin for beta-galactosidase to be produced.</p>
 +
 
 +
<p style="font-size:12px" align = "center"> <img src="https://static.igem.org/mediawiki/2015/thumb/2/22/AUXIN_TWO_SAMPLES_one_with_and_one_without_auxin.jpeg/180px-AUXIN_TWO_SAMPLES_one_with_and_one_without_auxin.jpeg"> </p>
 +
 
 +
<p style="font-size:12px" align = "center"> Two cell lysates that contain X-gal and were incubated overnight at 37C. In the top sample auxin was not added to the pre-lysed culture and in bottom sample auxin was added. The top sample with auxin does not produces beta-galactosidase and X-gal does not turn into indigo while the bottom sample with auxin turns indigo. </p>
  
                <p>While the sample fluid dissolves the salt-sugar matrix, it dissolves the particles and the sample and enzymes and salt and sugar mix. The analyte binds to the particles while traveling to the third capillary bed. This material has one or more areas (often stripes) where a third molecule has been placed by the manufacturer. By the time the sample mix reaches these strips, the analyte has been bound to the enzyme and the third 'capture' molecule binds the complex, and changes color. The color increases as enzyme-analyte-third molecules accumulate.
 
</p>
 
              <h2>Saccharomyces Cerivisiae Background</h2>
 
                <p>The type of cell that was engineered is Saccharomyces Cerivisiae, commonly known as baker’s yeast.  This cell has an activity > 0 for pH from 2.1 to 7 (Arroyo et al. 2009).  The activity is above 0 and increasing from 12°C to 36°C (Arroyo et al. 2009).  The wild type Saccharomyces Cerivisiae is not known to be mutagenic.  Another crucial characterization for test strip media is longevity.  S. Cerivisiae can live for approximately 20 to 120 hours (Minois et al. 2004).  In a dehydrated dormant state, however, the yeast can survive for years (Fabrizio & Longo 2003).  The genome of this model organism has been sequenced, it is easy to obtain in the lab, and the genomic structure is easy to modify.
 
</p>
 
 
                 <h2>
 
                 <h2>
                     <div id="Future_Direction">Future Direction</div>
+
                     <div id="Results"> Results </div>
 
                 </h2>
 
                 </h2>
  
<h2>Troubleshoot guide-RNA (or not)</h2>
+
<p align = "justify" > The transformation of the lacZ gene containing a uracil marker proved successful as yeast cells grew on plates or in liquid media lacking uracil. Furthermore, X-gal assays further showed that a constitutively expressing lacZ gene was successfully transformed and integrated into our yeast strain's genome. The transformation and genomic integration of the gRNA, the dCas9 construct and the AFB2 sequences was partially successful. Cell growth on plates lacking uracil and histidine showed that the cells did contain the both a lacZ gene containing a uracil marker as well as a gRNA gene containing a histidine marker. However cell (containing both the lacZ and gRNA genes) cultures were assayed in parallel in which one culture had auxin added while another lacked auxin yet both assays turned blue on occasion while other times only culture that had auxin turned blue and those lacking it remaining colorless (white). It is suspected that this was caused by an integration of the correct autotrophic marker but not the correct construct. </p>
  
<p>At this point in time, the cells containing the F-Box, dCas9-degron-inhibitor construct, the guide RNA, and the beta-galactosidase construct convert X-Gal into indigo in the presence of auxin. However, during certain runs of our experiment without auxin, indigo was still formed. We are currently examining this issue.</p>
+
                <h2>
 +
                    <div id="Conclusion">Conclusion</div>
 +
                </h2>
 +
 
 +
<p align = "justify"> The system that our team developed does indeed work as expected albeit a few oddities. There is a visible signal, in the form of an indigo dye that is produced in response to the presences of a small molecule auxin. With this success in a liquid culture lysate we can now apply our system to a portable paper device. </p>
 +
 
 +
                <h2>
 +
                    <div id="Future_Direction">Future Direction</div>
 +
                </h2>
 
   
 
   
 
<h2>Introduce high-resolution, easily-quantifiable response gradient using ONPG</h2>
 
<h2>Introduce high-resolution, easily-quantifiable response gradient using ONPG</h2>
<p>ONPG is a molecule used in a liquid assay and can be measured quantitatively with very high-resolution. This works by using a response factor that is able to dissolve in liquid solution and is thus measurable via photospectroscopy. Using this method, our team can precisely measure the impact of varying concentrations of small molecules on our system. We can then use the measured, overall response of our system to predict the amount of analyte present.</p>
+
 
 +
<p align = "justify">ONPG is a molecule used in a liquid assay and can be measured quantitatively with very high-resolution. This works by using a response factor that is able to dissolve in liquid solution and is thus measurable via photospectroscopy. Using this method, our team can precisely measure the impact of varying concentrations of small molecules on our system. We can then use the measured, overall response of our system to predict the amount of analyte present.</p>
  
 
<h2>Alternatively, use a quicker and easily  visible response factor</h2>
 
<h2>Alternatively, use a quicker and easily  visible response factor</h2>
<p>Currently, the response time of our system utilizing beta-galactosidase to cleave x-gal is somewhat lengthy. By switching over to a rapidly produced, colored signal  response that is visible to the naked eye we hope to make the system easier to use. Colored response signals such as RFP are great because they can be visualized without the need for lab instruments.  </p>
 
 
<h2>Find or design a protein similar to AFB2 that can target other toxins/small molecules<h2>
 
<p>The limitations of our model system is that only Auxin like molecules can be detected. However, with future advancements in the field of protein engineering perhaps more complex molecules can be detected using our system. </p>
 
  
 +
<p align = "justify">Currently, the response time of our system utilizing beta-galactosidase to cleave X-gal is somewhat lengthy taking at least 30 minutes to produce a response. By switching over to a rapidly produced, colored signal  response that is visible to the naked eye we hope to make the system easier to use. Colored response signals such as RFP are great because they can be visualized without the need for lab instruments.  </p>
 +
 +
<h2>Find or design a protein similar to AFB2 that can target other toxins/small molecules </h2>
 +
<p align = "justify">The limitations of our model system is that only Auxin like molecules can be detected. However, with future advancements in the field of protein engineering perhaps more complex molecules can be detected using our system. </p>
  
 +
         
 +
<br><br></br></br>
 
              
 
              
 
             </div>
 
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Latest revision as of 03:33, 19 September 2015



Introduction: Auxin Pathway

CRISPR Transcriptional Factors

CRISPR transcriptional factors enable scientists to make targeted changes in gene expression through the use of a guide RNA (gRNA). The gRNA attaches to the CRISPR protein, and guides it to a specific DNA locus based on the sequence of the gRNA. The CRISPR proteins we used known as dCas9 were obtained from the Klavins lab, and are designed so that they do not cleave the DNA strands themselves, this dead CRISPR will instead bind tightly and prevent access to the gene by other proteins. This effectively disables transcription and translation of the targeted gene. CRISPR transcriptional factors were first developed by Perez-Pinera et al. in 2013.

Auxin Background

Auxin is a class of plant hormone that is involved in developmental and behavioral signalling. This type of molecule serves as a good proof-of-concept for the detection of small-molecules by our model system. This is because Auxin can pass through the cell membrane and bind to an F-box protein (AFB2) and a degron (deg1), which will then target our dCas9 protein for degradation. Additionally, auxin is orthogonal to the biochemical machinery of the yeast, allowing for uninterrupted signal processing. Indole-3-acetic acid (IAA) is the specific Auxin molecule that we are using in our model system.

Model System Design

The pathway relies on several components. A dead-CRISPR transcription factor (dCas9) is fused to a degron domain (Deg1) and a strong repressor domain (MXI1). Along with a guide RNA designed to target an a promoter region for a signal response. Combined, the dCas9 complex along with the guide RNA will suppress the expression of lacZ. However, in the presence of IAA and an F-Box protein (AFB2), the dCas9 complex will be degraded and lacZ will be expressed leading to the production of beta-galactosidase. Thus, causing another small molecule X-gal to be converted into indigo when cleaved by beta-galactosidase and appear blue. The system is designed to produce a response (a color response in our case) to the presence of the small molecule indole-3-acetic acid.

(1) dCas9-deg1-MXI1 binds to a guide RNA which targets a sequence of a lacZ promoter causing the expression of beta-galactosidase to be supprefont size = 2ssed. (2) Auxin binds to both AFB2 (which also helps recruit the ubiquitin ligase) and deg1 simultaneously bringing the two into close proximity allowing the ubiquitin ligase to ubiquitinate the dCas9 construct. (3) lacZ expression is no longer suppressed allowing beta galactosidase to be produced and in the presence of X-gal, indigo is then formed.

Methods

Since the system requires 4 components (AFB2, dCas9-deg1-MXI1, lacZ, gRNA) to be transformed into a single cell, our team decided to integrate each component into the yeast genome sequentially using a "cassette". A genomic integration has the advantage that cells are less likely to loose the genetic information once acquired into the cells genome. This saves time and effort and by-passes and potential problem with multiple dropout media for marker selections during each sequential transformation. The Klavins Lab at the University of Washington, allowed us access to their genetically modified Saccharomyces Cerevisiae strain that has a partially deleted uracil, histidine, leucine and tryptophan autotrophic gene, making the strain incapable of surviving without the aforementioned amino acids. With our strain selected we proceeded to sequentially transform each component of auxin detection pathway.

Each of the 4 genetic components of our system were contained within plasmids containing an ampicillin resistance marker and were cloned and amplified in E.Coli. Furthermore, each the component's plasmid also contained a different yeast autotrophic selection marker as followed: AFB2 Leucine, dCas9 Tryptophan, lacZ Uracil, gRNA Histidine. The plasmid is digested with PME1 creating the gene cassette which, is then transformed into our yeast strain and each autotrophic marker-gene construct would then integrate into the yeast genome. A sequential transformation was carried out in which a component was transformed and the new strain grown on selective (amino acid drop-out) media and then transformed with another component and grown on a different selective media sequentially until all 4 components were successfully integrated. The final strain could then be grown on a selective media with all 4 amino acid removed which, acts as a final check to ensure all components have been integrated into the genome.

X-gal assays were run as followed. An aliquot of an overnight culture was diluted and incubated at 30C for 5 hours, for cultures containing the gRNA, auxin was added to the aliquot. After 5 hours, the cultures were pelleted and lysed and X-gal was added. The subsequent lysate was incubated at 37C. Blue color begins to show faintly after 30 minutes to 1 hour. A much deeper blue that is much easier to visualize was seen after 8-24 hours either at room temperature or in an incubator.

Two cell lysates in vials in which X-gal has been converted into indigo after a 24 hour incubation. Top vial shows that the system responds to the presence of auxin and produces beta-galactosidase. Bottom vial lacks cells that lack the gRNA and therefore does not require auxin for beta-galactosidase to be produced.

Two cell lysates that contain X-gal and were incubated overnight at 37C. In the top sample auxin was not added to the pre-lysed culture and in bottom sample auxin was added. The top sample with auxin does not produces beta-galactosidase and X-gal does not turn into indigo while the bottom sample with auxin turns indigo.

Results

The transformation of the lacZ gene containing a uracil marker proved successful as yeast cells grew on plates or in liquid media lacking uracil. Furthermore, X-gal assays further showed that a constitutively expressing lacZ gene was successfully transformed and integrated into our yeast strain's genome. The transformation and genomic integration of the gRNA, the dCas9 construct and the AFB2 sequences was partially successful. Cell growth on plates lacking uracil and histidine showed that the cells did contain the both a lacZ gene containing a uracil marker as well as a gRNA gene containing a histidine marker. However cell (containing both the lacZ and gRNA genes) cultures were assayed in parallel in which one culture had auxin added while another lacked auxin yet both assays turned blue on occasion while other times only culture that had auxin turned blue and those lacking it remaining colorless (white). It is suspected that this was caused by an integration of the correct autotrophic marker but not the correct construct.

Conclusion

The system that our team developed does indeed work as expected albeit a few oddities. There is a visible signal, in the form of an indigo dye that is produced in response to the presences of a small molecule auxin. With this success in a liquid culture lysate we can now apply our system to a portable paper device.

Future Direction

Introduce high-resolution, easily-quantifiable response gradient using ONPG

ONPG is a molecule used in a liquid assay and can be measured quantitatively with very high-resolution. This works by using a response factor that is able to dissolve in liquid solution and is thus measurable via photospectroscopy. Using this method, our team can precisely measure the impact of varying concentrations of small molecules on our system. We can then use the measured, overall response of our system to predict the amount of analyte present.

Alternatively, use a quicker and easily visible response factor

Currently, the response time of our system utilizing beta-galactosidase to cleave X-gal is somewhat lengthy taking at least 30 minutes to produce a response. By switching over to a rapidly produced, colored signal response that is visible to the naked eye we hope to make the system easier to use. Colored response signals such as RFP are great because they can be visualized without the need for lab instruments.

Find or design a protein similar to AFB2 that can target other toxins/small molecules

The limitations of our model system is that only Auxin like molecules can be detected. However, with future advancements in the field of protein engineering perhaps more complex molecules can be detected using our system.