Difference between revisions of "Team:HKUST-Rice/Description"
Stephanieyiu (Talk | contribs) |
|||
| Line 56: | Line 56: | ||
<h1 style="line-height: 110%;">Potassium Sensor</h1> | <h1 style="line-height: 110%;">Potassium Sensor</h1> | ||
<p><i>KdpFABC</i> transporter is a high affinity K<sup>+</sup> uptake system (Siebers, A. & Altendorf, K., 1988). The promoter upstream of <i>kdpFABC</i> operon, | <p><i>KdpFABC</i> transporter is a high affinity K<sup>+</sup> uptake system (Siebers, A. & Altendorf, K., 1988). The promoter upstream of <i>kdpFABC</i> operon, | ||
| − | <i>kdpFp</i>, works under low K<sup>+</sup> | + | <i>kdpFp</i>, works under low K<sup>+</sup> concentrations (Polarek, J. W., et al., 1992; Walderhaug, M. O., et al., 1992). The goal is to characterize |
| − | <i>kdpFp</i> and build a device which is able to sense different concentration of K<sup>+</sup> and express different | + | <i>kdpFp</i> and build a device which is able to sense different concentration of K<sup>+</sup> and express different levels of GFP accordingly.<br><br> |
<img src= "https://static.igem.org/mediawiki/2015/b/b4/Team-HKUST-Rice-KdpdF_promoter_1.JPG" style="width: 300px; height: auto; float: center;"></p> | <img src= "https://static.igem.org/mediawiki/2015/b/b4/Team-HKUST-Rice-KdpdF_promoter_1.JPG" style="width: 300px; height: auto; float: center;"></p> | ||
<p class="link"><a class=" learn" href="https://2015.igem.org/Team:HKUST-Rice/Potassium_Sensor"> Learn more ... </a></p> | <p class="link"><a class=" learn" href="https://2015.igem.org/Team:HKUST-Rice/Potassium_Sensor"> Learn more ... </a></p> | ||
| Line 64: | Line 64: | ||
<td style= "padding: 20px; vertical-align: text-top;"> | <td style= "padding: 20px; vertical-align: text-top;"> | ||
<h1 style="line-height: 110%;">Phosphate Sensor</h1> | <h1 style="line-height: 110%;">Phosphate Sensor</h1> | ||
| − | <p><i>phoAp</i> and <i>phoBRp</i> | + | <p><i>phoAp</i> and <i>phoBRp</i> promoters (Hsieh, Y. J., & Wanner, B. L., 2010) are cross-regulated by <i>phoB</i> and <i>phoR</i>, and are |
| − | usually repressed under high phosphate | + | usually repressed under high phosphate concentrations. <i>phoR</i> behaves as an activator as well as an inactivator for <i>phoB</i>. |
| − | When phosphate is limited, <i>phoR</i> will phosphorylate <i>phoB</i> and the phosphorylated <i>phoB</i> will directly | + | When phosphate is limited, <i>phoR</i> will phosphorylate <i>phoB</i> and the phosphorylated <i>phoB</i> will directly activate the |
| − | + | <i>phoAp</i> and <i>phoBRp</i> promoters. <br> | |
<img src= "https://static.igem.org/mediawiki/2015/7/7f/Team-HKUST-Rice-Pphoa_characterization.JPG" style="width: 300px; height: auto; float: center;"></p> | <img src= "https://static.igem.org/mediawiki/2015/7/7f/Team-HKUST-Rice-Pphoa_characterization.JPG" style="width: 300px; height: auto; float: center;"></p> | ||
<p class="link"><a class=" learn" href="https://2015.igem.org/Team:HKUST-Rice/Phosphate_Sensor"> Learn more ... </a></p> | <p class="link"><a class=" learn" href="https://2015.igem.org/Team:HKUST-Rice/Phosphate_Sensor"> Learn more ... </a></p> | ||
| Line 74: | Line 74: | ||
<td style= "padding: 20px; vertical-align: text-top;"> | <td style= "padding: 20px; vertical-align: text-top;"> | ||
<h1>Nitrate Sensor</h1> | <h1>Nitrate Sensor</h1> | ||
| − | <p><i>yeaRp</i> promoter (Lin, et al, 2007)is normally cross-regulated by the Nar two-component regulatory system (T.Nohno, | + | <p><i>yeaRp</i> promoter (Lin, et al, 2007) is normally cross-regulated by the Nar two-component regulatory system (T.Nohno, |
et,al. , 1989) and <i>NsrR</i>, a regulatory protein. When there is nitrate and nitrite, it will be converted into nitric oxide. | et,al. , 1989) and <i>NsrR</i>, a regulatory protein. When there is nitrate and nitrite, it will be converted into nitric oxide. | ||
| − | The nitric oxide will bind to <i>NsrR</i> and relieve the repression on the <i> | + | The nitric oxide will bind to <i>NsrR</i> and relieve the repression on the <i>yeaRp</i> promoter. As a result, any |
genes that are downstream of the <i>yeaRp</i> promoter will be expressed.</font><br> | genes that are downstream of the <i>yeaRp</i> promoter will be expressed.</font><br> | ||
<img src= "https://static.igem.org/mediawiki/2015/0/09/Team-HKUST-Rice-Pyear_characterization.JPG" style="width: 300px; height: auto; float: center;"></p> | <img src= "https://static.igem.org/mediawiki/2015/0/09/Team-HKUST-Rice-Pyear_characterization.JPG" style="width: 300px; height: auto; float: center;"></p> | ||
| Line 89: | Line 89: | ||
<h1>Signal Co-expression</h1> | <h1>Signal Co-expression</h1> | ||
<p>In order to characterize the output difference between a single expression system and co-expression | <p>In order to characterize the output difference between a single expression system and co-expression | ||
| − | from | + | from one vector, we will be constructing several inducible systems that give off fluorescence output and compare the dose |
response of the individual systems in the two scenarios.<br><br>As part of the expression platform, we also aim to construct a | response of the individual systems in the two scenarios.<br><br>As part of the expression platform, we also aim to construct a | ||
3-input AND logic gate using toehold switches (Green, A. A., et al., 2014) to integrate the input signals detected from the three | 3-input AND logic gate using toehold switches (Green, A. A., et al., 2014) to integrate the input signals detected from the three | ||
Revision as of 06:39, 30 August 2015
Scroll down to learn more
Project
Overview
Nitrogen (N), Phosphorus (P), and potassium (K) are three macronutrients for plants, and deficiencies in any of these can lead to plant diseases. By creating a biological sensor that can quickly provide soil status to plant owners, we can prevent plant diseases due to the lack of nutrients. In view of this, our team is constructing a biological sensor in E. coli, which can detect NPK levels in the surrounding environment and give responses in the form of colors. In addition, we are characterizing the effects of a dual output system, in contrast to a single output system, in order to anticipate the expression of multiple outputs in a single system.
Potassium SensorKdpFABC transporter is a high affinity K+ uptake system (Siebers, A. & Altendorf, K., 1988). The promoter upstream of kdpFABC operon,
kdpFp, works under low K+ concentrations (Polarek, J. W., et al., 1992; Walderhaug, M. O., et al., 1992). The goal is to characterize
kdpFp and build a device which is able to sense different concentration of K+ and express different levels of GFP accordingly. |
Phosphate SensorphoAp and phoBRp promoters (Hsieh, Y. J., & Wanner, B. L., 2010) are cross-regulated by phoB and phoR, and are
usually repressed under high phosphate concentrations. phoR behaves as an activator as well as an inactivator for phoB.
When phosphate is limited, phoR will phosphorylate phoB and the phosphorylated phoB will directly activate the
phoAp and phoBRp promoters. |
Nitrate SensoryeaRp promoter (Lin, et al, 2007) is normally cross-regulated by the Nar two-component regulatory system (T.Nohno,
et,al. , 1989) and NsrR, a regulatory protein. When there is nitrate and nitrite, it will be converted into nitric oxide.
The nitric oxide will bind to NsrR and relieve the repression on the yeaRp promoter. As a result, any
genes that are downstream of the yeaRp promoter will be expressed. |
Signal Co-expression
In order to characterize the output difference between a single expression system and co-expression
from one vector, we will be constructing several inducible systems that give off fluorescence output and compare the dose
response of the individual systems in the two scenarios.
As part of the expression platform, we also aim to construct a
3-input AND logic gate using toehold switches (Green, A. A., et al., 2014) to integrate the input signals detected from the three
(N, P and K) promoters.
Reference: