Difference between revisions of "Team:HKUST-Rice/Potassium Sensor"

 
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<div id= "page_title"><h1>Potassium Sensor - <i>P<sub>kdpF</sub></i></h1></div>
 
<div id= "page_title"><h1>Potassium Sensor - <i>P<sub>kdpF</sub></i></h1></div>
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                 <a href="https://2015.igem.org/Team:HKUST-Rice/Modeling"><img src="https://static.igem.org/mediawiki/2015/7/7a/HKUST-Rice15_rightarrow.png">
 
                 <a href="https://2015.igem.org/Team:HKUST-Rice/Modeling"><img src="https://static.igem.org/mediawiki/2015/7/7a/HKUST-Rice15_rightarrow.png">
<p style="color:#5570b0; font-size: 130%"> Potassium sensor - Modelling </p></a>
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<p style="color:#5570b0; font-size: 130%"> Potassium sensor - Modeling </p></a>
 
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<h1>Potassium as a Macro-nutrient</h1>
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<h1><i>E. coli</i> that glows in paucity of K<sup>+</sup> - at a glance</h1>
<p>Potassium is an essential plant macronutrient as it has numerous important roles in plants including osmoregulation,
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<table>
CO<sub>2</sub> regulation, starch and protein synthesis. The deficiency of K<sup>+</sup> ion will result
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<tr>
in abnormalities in plant growth and metabolism. It is fundamental to determine its concentration in soil in order to provide
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<td style="width:48.5%">
the proper amount of additional potassium that must be added to the plant by any particular fertilizers.  
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<figure>
<p>Our aim is to engineer a potassium sensor that can detect a range of K<sup>+</sup> concentration in the soil to ensure
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<img  src="https://static.igem.org/mediawiki/2015/4/42/Team_HKUST-Rice_2015_potassium_figure_1.png "style="width:100%;">
the suitable soil condition for the plant. We utilized <i>P<sub>kdpF</sub></i>, a promoter located upstream of <i>KdpFABC</i> operon
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</figure>
in <I>Escherichia coli (E. coli)</I> which works under low [K<sup>+</sup>] condition. We put it upstream of a GFP reporter so as to
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</td>
characterize the promoter activity.</p>
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<img style="width:90%" src="https://static.igem.org/mediawiki/2015/f/f5/Introduction.jpg" alt="image caption">
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<figure>
</div>
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<img id="Kgraph" src="https://static.igem.org/mediawiki/2015/9/90/HKUST-Rice15_%28log_10%29_RPU_of_kdpFp--15%2CT_G-_in_DH10B_-RPU-.png" style="width:100%">
                </div>
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<br>
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<p style="font-size:110%; padding-left:2%; padding-right: 2% ; height'90px';"><strong>A.</strong> <i>E. coli</i> engineered with <a href="http://parts.igem.org/Part:BBa_K1682009"target="_blank">BBa_K1682009</a> functions as a potassium biosensor. High concentrations of K<sup>+</sup> indirectly represses the promoter <i>K<sub>kdpF</sub></i> and decreases the expression of GFP.</p>
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<td style="width:48.5%">
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<p style="font-size:110%; padding-left:2;height:'90px'; padding-right: 2%"  ><strong>B.</strong> The potassium sensing promoter <a href="http://parts.igem.org/Part:BBa_K1682004"target="_blank">BBa_K1682004</a> can detect a gradient of K<sup>+</sup> concentrations</strong> and its activities were reported in Relative Promoter Units (RPU).</p>
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<p><ul style="text-align:left; font-size:1.5em; line-height= 1.5em; font-family: 'Helvetica Neue', Helvetica, sans-serif;"><li>K<sup>+</sup> is an essential plant macronutrient and plays vital role for maintaining high crop yield.</li>
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<li>Our biosensor <a href="http://parts.igem.org/wiki/index.php?title=Part:BBa_K1682009">BBa_K1682009</a> monitors K<sup>+</sup> concentration.</li>
 +
<li>Activity of K<sup>+</sup> sensing promoter (<a href="http://parts.igem.org/wiki/index.php?title=Part:BBa_K1682004">BBa_K1682004</a>) was measured in Relative Promoter Unit. It can be reliably reused.</ul></p>
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<div class="project_row">
 
<hr class="para">
 
<hr class="para">
<h1>Endogenous K sensing system</h1>
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<h1><i>P<sub>kdpF</sub></i> and our engineered K<sup>+</sup> sensor BBa_K1682009 - the full story</h1>
<p>The potassium ion uptake in <i>E. coli</i> is regulated by several systems under different conditions.  
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<p>Potassium is an essential plant macronutrient as it is required for photosynthesis, osmoregulation, stomatal control, sugar and protein synthesis. (IPNI, 1998) The deficiency of K<sup>+</sup> ion will result in abnormalities in plant growth and metabolism. Our aim is to engineer a potassium sensor in <i>Escherichia coli</i> and detect the lack of K<sup>+</sup> in soil. To this end, we engineered <i>P<sub>kdpF</sub></i>, a promoter activated under low [K<sup>+</sup>] condition, and fused it with <i>gfp</i> (<i>gfpmut3b</i>).</p>
The potassium ion transporters, Trk and Kup are constitutively expressed (Epstein & Kim, 1971) while KdpFABC, another
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transporter is activated under limited potassium ion concentration (Laimins et al., 1981). <i>kdpFABC</i> operon is controlled by
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<hr class="para">
the KdpDE two-component system (TCS) (Polarek, 1992; Walderhaug, 1992).</p>
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<p  class="subTitle">Endogenous potassium sensing system in <i>E. coli</i></p>
<div class="project_image">
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<img style="width:80%;" src="https://static.igem.org/mediawiki/2015/8/85/Team_HKUST-Rice_2015_potassium_figure_2.png" alt="image caption">
<img style="width:55%; height:300px; float:right; padding-left:2%" src="https://static.igem.org/mediawiki/2015/b/b0/HKUST-Rice15_Kmechanism.jpg" alt="image caption">
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<p style="font-size:110%; padding-left:6%;"><strong>Figure 1. The Kdp K<sup>+</sup> uptake system in <i>E. coli</i>.</strong></p>
</div>
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<p>The TCS consists of KdpD which is a membrane-bound
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sensor kinase and KdpE which is the cytoplasmic response regulator. KdpD is stimulated by both intracellular and extracellular
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potassium ion concentration (Jung, 2000; Jung, 2001; Roe, 2000; Yan, 2011a; Laermann, 2013). The autophosphorylation of KdpD
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transfers a phosphoryl group to the KdpE upon low potassium concentration (Voelkner, 1993; Puppe, 1996; Jung, 1997a; Jung, 2000).
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<br><br>Under an increase in potassium ion concentration, KdpD phosphatase activity will be enhanced, causing a decrease in phospho-KdpE
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and <i>kdpFABC</i> expression. Phosphorylated KdpE activates <i>kdpFABC</i> operon (Zhang, 2014a; Laermann, 2013).</p>
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<p>The <I>P<sub>kdpF</sub></I> we adopted is upstream of the <i>kdpFABC</i> operon with -28 position of transcription
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<p><i>E. coli</i> has multiple native K<sup>+</sup> sensing and uptake systems that we could put to use. Among them, we chose the KdpDE two-component system (TCS). It contains a membrane-bound kinase KdpD and a cytoplasmic response regulator KdpE. Stimulated by low K<sup>+</sup> concentration, both extracelluarly and intracellularly, KdpD transphosphorylates KdpE using its own phosphate. The phospho-KdpE is then capable of activating expression of the <i>kdpFABC</i> operon, which codes for a transporter complex that is activated by low K<sup>+</sup> concentration. Apart from that, <i>E. coli</i> also has constitutively expressed Trk and Kup transporters for K<sup>+</sup> uptake.
start site relative to start the first gene, <i>kdpF</i>. The -10 and -35 box elements of have been mapped are TACCCT and TTGCGA respectively (Sugiura et al., 1992). The transcription factor, phosphorylated KdpE, binds to the <i>P<sub>kdpF</sub></i> at binding site located from -71 to -55 site with reference to the transcription start site to initiate the transcription of downstream gene (Sugiura et al., 1992; Narayanan et al., 2012).</p>
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<div class="project_row">
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<hr class="para">
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<h1>Design of K<sup>+</sup> sensing Device</h1>
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<p>As our potassium-sensing device, we obtained the promoter, <i>P<sub>kdpF</sub></i>, and then combined it with a downstream GFP generator, BBa_E0240, using BioBrick RFC 10 standard so that the promoter activity in different potassium level can be detected and characterized.</p>
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<img style="width:50%" src="https://static.igem.org/mediawiki/2015/b/be/HKUST-Rice15_Kconstruct.jpg" alt="image caption">
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<p class="subTitle">EcoRI Illegal Site</p>
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<p>In order to make our promoters, <i>P<sub>kdpF</sub></i>, compatible with Biobrick RFC 10 standard and so that readily accessible to the whole iGEM community, we have to remove the EcoRI illegal site from -18 to -12 position within. We removed the illegal site by mutating the thymine at -15 position with reference to the transcription start site to guanine, cytosine and adenine to give rise to 3 promoter mutants. We expected that the four promoters would differ in activity  because of the difference in binding energy between the promoter and RNA polymerase due to the base-pair changes (Brewster, 2012). Therefore, we characterized all of the promoters to compare their strengths by means of their respective fluorescence levels and RPU measurements so as to obtain a more comprehensive knowledge in the activity and working range of the four  promoters. For convenience, we denote them as <i>P<sub>kdpF</sub></i>(A)/A-mutant, <i>P<sub>kdpF</sub></i>(G)/G-mutant and <i>P<sub>kdpF</sub></i>(C)/C-mutant respectively in the following context.</p>
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<p  class="subTitle">Interference from other Endogenous Systems</p>
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<p>Another concern is the masking of <i>P<sub>kdpF</sub></i> activity by other native constitutive potassium transport systems in <i>E.coli</i>.
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Other than the inducible KdpFABC system(K<sub>M</sub>= 2 µM), <i>E. coli</i> has Trk and Kup systems which are constitutively expressed, low-affinity
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potassium transport systems (K<sub>M</sub>= 1.5 mM) (Epstein & Kim, 1971). A study has found that the expression level of <i>KdpFABC</i> is generally
+
                                        higher in a strain without Trk and Kup system (Laimins et al., 1981). It is due to the fact that <i>E. coli</i> uses the two saturable transporters,
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Trk and Kup, under normal physiological conditions to uptake extracellular potassium ion. Only at a very low concentration of
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potassium ion, that these two systems can no longer satisfy the need of potassium ion of <i>E. coli</i>, the <i>P<sub>kdpF</sub></i> will be
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activated and drive the expression of KdpFABC complex to uptake more K<sup>+</sup>. As the result, the activity of <i>P<sub>kdpF</sub></i> may be
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masked by Trk and Kup system and cannot be truly reflected (Laermann et al., 2013). We decided to measure the activity of <i>P<sub>kdpF</sub></i> in <i>E.coli</i> TK2240 (kdp+ Δtrk Δkup) strain, which is a strain defectve in Trk and Kup system. Such that we are able to characterize <i>P<sub>kdpF</sub></i> promoter in a more accurate manner.</p>
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</div>
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<div class="project_row">
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<hr class="para">
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<h1 id="results">Measurement and Characterization</h1>
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<p>In order to assemble a device that can be widely used by all iGEM community, we characterized <i>P<sub>kdpF</sub></i> promoter by using Relative
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Promoter Unit (RPU). Additionally, we intended to find the comparison of the activities between different promoters, thus, we also
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measured Relative Fluorescence Unit (RFU) of the four potassium promoters.</p>
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<p  class="subTitle">Relative promoter unit measurement</p>
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<div class="project_image">
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<img id="Kgraph" src="https://static.igem.org/mediawiki/2015/9/90/HKUST-Rice15_%28log_10%29_RPU_of_kdpFp--15%2CT_G-_in_DH10B_-RPU-.png" alt="image caption">
+
</div>
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<p class="PICdescription"><b>Figure  . Relative promoter unit (RPU) of <i>P<sub>kdpF</sub></i>[-15,T>G] across different concentration of K<sup>+</sup>. </b>The measurement
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of the activity of G mutant was carried out using fluorescence-activated cell sorting. The strength of the promoter is presented in
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relative to the strength of standard reference promoter.  Error bar are represented as SEM.</p>
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<p>From the lowest concentration of potassium ion to 0.025 mM, the strength of the G mutant promoter was found to be about 0.5 RPU and
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decreasing when concentration increased. After the concentration of potassium ion at 0.025 mM, there was no significant change on the
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RPU values. Strength of G mutant <i>P<sub>kdpF</sub></i> at the lowest concentration was about 1.5 times higher than those after 0.025 mM.</p>
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<p>High concentration of potassium ion could repress the expression of <i>P<sub>kdpF</sub></i>, due to satisfaction of potassium ion by constitutively
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expressed low-affinity K<sup>+</sup> transporter system, Trk and Kup(Laermann et al., 2013). Therefore the activity of <i>P<sub>kdpF</sub></i> promoter,
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that is represented by the relative fluorescence intensity, at high concentration of potassium ion, should be low and it is shown in our
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experiments. </p>
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<p  class="subTitle">Relative fluorescence measurement</p>
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<div class="project_image">
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<img id="Kgraph3" style="float:left" src="https://static.igem.org/mediawiki/2015/a/a6/HKUST-Rice15_RFU_of_4_kdpFp_in_DH10B_diff-K%2B-.png" alt="image caption">
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<img id="Kgraph3" style="float:right" src="https://static.igem.org/mediawiki/2015/0/04/HKUST-Rice15_GFP_syn_rate_of_4_kdpFp_in_DH10B.png" alt="image caption">
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</div>
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<p class="PICdescription"><b>Figure  . Activity of <i>P<sub>kdpF</sub></i> in <i>E. coli</i> DH10B in different K<sup>+</sup> concentrations.</b> Pair graph
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representing the activity of different <i>P<sub>kdpF</sub></i>. Fluorescence/absorbance versus [K<sup>+</sup>] plot is shown on the left while the GFP synthesis
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rate versus [K<sup>+</sup>] plot is on the right. A, T(wild type), C, and G represent A mutant, wild type promoter, C mutant and G mutant respectively.
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Error bar are represented as SEM.</p>
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<p>Both C and G mutants similarly expressed higher fluorescence intensity compared to the wild type and the A mutant. A higher level of potassium ion
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inside K minimal medium repressed the expression level of <i>P<sub>kdpF</sub></i>, which was shown by lower fluorescence intensity of all promoters at higher
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concentration of potassium ion. The expression level of both C and G mutant promoters were significantly higher than the wild type one, while A mutant was always the lowest.</p>
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<p>The fluorescence intensity decreases over the concentration of potassium ion in K minimal medium. After several trials, we found the dynamic range
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of our promoters. It is between 0 to 0.1 mM of potassium ion in K minimal medium. Thus, we characterized our promoters at those range of concentrations
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(0 to 0.2 mM).
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</p>
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<p>We observed that the fluorescence intensity expressed by C and G mutants are always at around similar values since the binding affinity might be
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the same with reference to the energy matrix (Brewster, 2012). Moreover, both of them are always higher than the one expressed by the wild type promoter.
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Meanwhile, the fluorescence intensity expressed by A mutant is lower than the the one expressed by the wild-type promoter. Also, the relationship of
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relative fluorescence intensity and K<sup>+</sup> concentration of all the promoters are  coherent with the previous RPU measurement of G mutant.
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</p>
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<div class="project_image">
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<img id="Kgraph" src="https://static.igem.org/mediawiki/2015/1/18/HKUST-Rice15_RFU_of_4_kdpFp_at_0_-K%2B-.png" alt="image caption">
+
</div>
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<p class="PICdescription"><b>Figure  . The activities of <i>P<sub>kdpF</sub></i> in the medium containing no potassium ion.</b>A fluorescence/absorbance plot was obtained from measuring the relative fluorescence level exhibited by the promoters, <i>P<sub>kdpF</sub></i> and its 3
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mutants (A, C and G), in DH10B cells in 0 mM K minimal medium. The expression level of both C and G mutants are significantly higher than the expression
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level of wild-type promoter and A mutant promoter. There was no significant difference between the activity of G mutant and C mutant promoters,
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as well as between wild type promoter and A mutant. Error bars are represented as SEM.
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</p>
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<p>We also would like to make a clear comparison between the expression level of the different mutant promoters. We tried to make a comparison
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of the expression of all the promoters at the lowest level of potassium ion, that is no potassium ion in K minimal medium. From the graph that we
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obtained, we observed that the expression level of both C and G mutants are about 2 times higher than the wild type promoter and A mutant. These
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results demonstrate our former experiments that the relative fluorescence intensity level of both C and G mutants are always higher than both
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wild type promoter and A mutant.
+
 
</p>
 
</p>
 +
<p style = "font-size:110%">*The above text is our summarized understanding on K<sup>+</sup>-sensing system using information from EcoCyc. (Keseler et al., 2013). Please refer to our references section below for a full list of references cited.</p>
 
 
<div class="project_image">
+
<hr class="para">
<img id="Kgraph2" src="https://static.igem.org/mediawiki/2015/2/2b/HKUST-Rice15_RFU_of_kdpFp_in_DH10B_and_TK2240.png" alt="image caption">
+
</div>
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<p class="PICdescription"><b>Figure  . Comparison between the activities of <i>P<sub>kdpF</sub></i>[-15, T>G] in DH10B and TK2240 strain. </b>Error bars are represented as SEM.
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</p>
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<p>At the concentration of potassium ion lower than 0.0125 mM, the fluorescence intensity expressed by G mutant in DH10B was significantly greater than the one in TK2240 strain. The fluorescence intensity expressed by G mutant in DH10B strain decreased over the concentration, while the one in TK2240 remained the same. Starting from the concentration of potassium ion at 0.0125 mM onwards, the difference of GFP expressed by both strains was not significant. After passing the concentration of potassium ion at 0.05 mM, the expression level of <i>P<sub>kdpF</sub></i> in TK2240 strain exceeded the one in the DH10B strain.</p>
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<p>We did another relative fluorescence measurement using TK2240 to observe a more accurate  activity of <i>P<sub>kdpF</sub></i>. The TK2240 strain is defective
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in <i>trk</i> and <i>kup</i> gene. The only gene which could respond to potassium ion in TK2240 strain is only <i>kdp</i> gene. Therefore the expression of <i>kdp</i> gene
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would not be masked by the saturable low-affinity K<sup>+</sup> transporter system. We were expecting that the activity of <i>P<sub>kdpF</sub></i> in TK2240 are
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higher than that in DH10B. The fact mentioned earlier corresponds to the graph at higher concentration of potassium ion, although the expression
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level in DH10B is higher than in TK2240 at low concentration of potassium ion.
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</p>
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<p>We could observe the difference of the fluorescence intensity expressed by both strains at the concentration of potassium ion lower than 0.0125 mM.
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The fluorescence intensity expressed by G mutant in DH10B strain decreases over the concentration, while the one in TK2240 remains the same. Since
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TK2240 has a greater need of KdpFABC complex to help scavenge the external K<sup>+</sup>, so what might have caused this would be TK2240 spend too much energy
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at that stage to make KdpFABC complex and thus spare less energy on producing GFP.
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</p>
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<p>At higher concentration of potassium ion, starting from 0.0125 mM onwards, the difference of fluorescence intensity expressed by both strains
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is not significant anymore. Both strains show decrease in fluorescence intensity over the increasing concentration of potassium ion in K minimal medium.
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</p>
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<p>After passing the concentration of potassium ion at 0.05 mM, the fluorescence intensity expressed by TK2240 strain exceeds the one in the DH10B
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strain due to the constant need of potassium ion of the cells and in TK2240, there is only KdpFABC transporter system that can satisfy this need of <i>E. coli</i>.</p>
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<p  class="subTitle">Considerations for replicating the experiments</p>
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<p>a. OD<sub>600</sub>= 0.4 referring to mid log phase of <i>E. coli</I> in K minimal medium<br>
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                                        b. Dilution has always been done to make the OD<sub>600</sub> values of start culture around the same before subculturing in different concentration of K<sup>+</sup>.</p>
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<div class="project_row">
 
<div class="project_row">
<hr class="para">
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<class="subTitle">Design and Testing of potassium sensing Device</p>
<h1 id="results">Future Plan</h1>
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<div class="project_image" style="padding-top:0">
<p>In the interest of providing an efficient and accessible device that can identify the concentration of K+ ion into real field, we had a future plan on optimizing the device prepared using a paper-based cell-free transcription-translation (TX-TL) system for our construct.</p>
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<img style="width:80%" src="https://static.igem.org/mediawiki/2015/d/d8/HKUST_Rice15_potassium_figure_int.png" alt="image caption">
</div>
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<p style="font-size:110%; padding-left:6%;"><strong>Figure 2. Construction and Testing of <i>P<sub>kdpF</sub></i>.</strong> A) Positions of base substitutions to standardize <i>P<sub>kdpF</sub></i> into RFC10 format. B) Single time point transfer curve for <i>P<sub>kdpF</sub></i> variants along a gradient of [K<sup>+</sup>]. C) Relative GFP synthesis rate calculated from 3 measurement time points. Error bar present SEM from 3 biological replicates.</p></div>
<div class="project_row">
+
<p>To construct a potassium-sensing device, we cloned the promoter upstream of <i>kdpFABC</i> operon, <i>P<sub>kdpF</sub></i></a>, and fused it with a translation unit for GFP reporter <a href="http://parts.igem.org/Part:BBa_E0240"target="_blank">BBa_E0240</a> in BioBrick RFC10 standard. The promoter activity can then be reported by the GFP level under different K<sup>+</sup> concentrations.</p>
<hr class="para">
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<h1 id="results">References</h1>
+
<p>However, <i>P<sub>kdpF</sub></i> contains an illegal <i>EcoR</i>I site that prohibits standard assembly. We tackled this by constructing and testing 3 mutated versions with A (<a href ="http://parts.igem.org/wiki/index.php?title=Part:BBa_K1682002"target="_blank">BBa_K1682002</a>), C (<a href ="http://parts.igem.org/wiki/index.php?title=Part:BBa_K1682003"target="_blank">BBa_K1682003</a>), or G (<a href ="http://parts.igem.org/wiki/index.php?title=Part:BBa_K1682004"target="_blank">BBa_K1682004</a>) substituting the orignal T. Our results showed that all 3 variants are functional and sense [K<sup>+</sup>] from 0 to 0.1 mM. The C and G mutants had higher maximum promoter activities than the WT or A mutant. <i>P<sub>kdpF</sub></i>[-15,T>G] performed well in both strength and reliablity and was therefore used in subsequent experiments.</p>
<p>Brewster, R. C., Jones, D. L., & Phillips, R. (2012). Tuning promoter strength through RNA polymerase binding site design in <i>Escherichia coli</i>.</p>
+
<hr class="para">
<p>Epstein, W., & Kim, B. S. (1971). Potassium transport loci in <i>Escherichia coli</i> K-12. <i>Journal of Bacteriology, 108</i>(2), 639-644.</p>
+
<p>Jung, K., Tjaden, B., & Altendorf, K. (1997). Purification, reconstitution, and characterization of KdpD, the turgor sensor of <i>Escherichia coli.</i> <i>Journal of Biological Chemistry, 272</i>(16), 10847-10852. </p>
+
<p>Jung, K., Veen, M., & Altendorf, K. (2000). K+ and ionic strength directly influence the autophosphorylation activity of the putative turgor sensor KdpD of <i>Escherichia coli</i>. <i>Journal of Biological Chemistry, 275 </i>(51), 40142-40147. </p>
+
<p>Jung, K., Krabusch, M., & Altendorf, K. (2001). Cs+ Induces the kdp operon of <i>Escherichia coli</i> by Lowering the Intracellular K+ Concentration. <i>Journal of bacteriology, 183</i>(12), 3800-3803. </p>
+
<p>Laermann, V., Ćudić, E., Kipschull, K., Zimmann, P., & Altendorf, K. (2013). The sensor kinase KdpD of <i>Escherichia coli</i> senses external K+. <i>Molecular microbiology, 88</i>(6), 1194-1204. </p>
+
<p>Laimins, L. A., Rhoads, D. B., & Epstein, W. (1981). Osmotic control of kdp operon expression in <i>Escherichia coli. Proceedings of the National Academy of Sciences, 78 </i>(1), 464-468. </p>
+
<p>Narayanan, A., Paul, L. N., Tomar, S., Patil, D. N., Kumar, P., & Yernool, D. A. (2012). Structure-function studies of DNA binding domain of response regulator KdpE reveals equal affinity interactions at DNA half-sites. <i>PloS one, 7</i>(1), e30102. </p>
+
<p>Polarek, J. W., Williams, G., & Epstein, W. (1992). The products of the kdpDE operon are required for expression of the Kdp ATPase of <i>Escherichia coli. Journal of bacteriology, 174 </i>(7), 2145-2151. </p>
+
<p>Roe, A. J., McLaggan, D., O’Byrne, C. P., & Booth, I. R. (2000). Rapid inactivation of the <i>Escherichia coli</i> Kdp K+ uptake system by high potassium concentrations. <i>Molecular microbiology, 35</i>(5), 1235-1243. </p>
+
<p>Sugiura, A., Nakashima, K., Tanaka, K., & Mizuno, T. (1992). Clarification of the structural and functional features of the osmoregulated kdp operon of <i>Escherichia coli. Molecular microbiology, 6</i>(13), 1769-1776. </p>
+
<p>Voelkner, P., Puppe, W., & Altendorf, K. (1993). Characterization of the KdpD protein, the sensor kinase of the K+‐translocating Kdp system of <i>Escherichia coli. European Journal of Biochemistry, 217</i>(3), 1019-1026. </p>
+
<p>Walderhaug, M. O., Polarek, J. W., Voelkner, P., Daniel, J. M., Hesse, J. E., Altendorf, K., & Epstein, W. (1992). KdpD and KdpE, proteins that control expression of the kdpABC operon, are members of the two-component sensor-effector class of regulators. <i>Journal of bacteriology, 174</i>(7), 2152-2159. </p>
+
<p>Yan, H., Fukamachi, T., Saito, H., & Kobayashi, H. (2011). Expression and activity of Kdp under acidic conditions in <i>Escherichia coli. Biological and Pharmaceutical Bulletin, 34</i>(3), 426-429. </p>
+
<p>Zhang, L., Jiang, W., Nan, J., Almqvist, J., & Huang, Y. (2014). The <i>Escherichia coli</i> CysZ is a pH dependent sulfate transporter that can be inhibited by sulfite. <i>Biochimica et Biophysica Acta (BBA)-Biomembranes, 1838</i>(7), 1809-1816. </p>
+
</div>
+
 
</div>
 
</div>
 +
 +
<div class="project_row">
 +
<p  class="subTitle">Relative Promoter Unit Measurement of <i>P<sub>kdpF</sub></i>[-15,T>G]</p>
 +
<div class="project_image">
 +
<img id="Kgraph" src="https://static.igem.org/mediawiki/2015/9/90/HKUST-Rice15_%28log_10%29_RPU_of_kdpFp--15%2CT_G-_in_DH10B_-RPU-.png" alt="image caption">
 +
<p style="font-size:110%; padding-left:6%;"><strong>Figure 3. Relative promoter units (RPU) of <i>P<sub>kdpF</sub></i>[-15,T>G] under different [K<sup>+</sup>].</strong> Error bar present SEM from 3 independent experiments on different days.</p></div>
 +
<p>We decided to report the promoter activites of <i>P<sub>kdpF</sub></i>[-15,T>G] in Relative Promoter Units (RPU) because this will allow future users to compare its promoter strength with that from another promoter, and perhaps, further improve this part. The activities of <i>P<sub>kdpF</sub></i>[-15,T>G] in different [K<sup>+</sup>] were measured and compared to that by <a href="http://parts.igem.org/Part:BBa_I20260"target="_blank">BBa_I20260</a> following a modified protocol from Kelly et. al (2009) (see below), and was found to be ~0.5 RPU at 0 mM K<sup>+</sup> and ~0.13 RPU 0.025 mM K<sup>+</sup>. From 0 - 0.4 mM K<sup>+</sup>, there is a 3.8 fold change in RPU.</p>
 +
<hr class="para">
 +
</div>
 +
 +
<div class="project_row">
 +
<p  class="subTitle">Interference from other Endogenous Systems</p>
 +
<div class="project_image">
 +
<img style="width:80%" src="https://static.igem.org/mediawiki/2015/4/40/HKUST_Rice15_Comparison_of_kdpFp_in_E_2.png" alt="image caption">
 +
<p style="font-size:110%; padding-left:6%;"><strong>Figure 4. Comparison between the activities of <i>P<sub>kdpF</sub></i>[-15, T>G] in DH10B and TK2240 strain. </strong> Error bar present SEM from 3 biological replicates.</p>
 +
</div>
 +
<div class="des">
 +
<p>The low-affinity K<sup>+</sup> transport systems Trk and Kup native to <i>E. coli</i> are constitutively expressed (Epstein & Kim, 1971). Laermann et al. (2013) discovered that knocking out the two systems in the strain TK2240 <i>(kdp+ Δtrk Δkup)</i> will result in a increase in expression of the <i>kdpFABC</i> system. We repeated that comparison using DH10B with our <i>P<sub>kdpF</sub></i>[-15,T>G] promoter but obtained different results - below 0.0125 mM K<sup>+</sup>, the activity of the promoter in DH10B was significantly greater than that in TK2240. Only when [K<sup>+</sup>] > 0.05mM would we be able to observe stronger promoter activities in TK2240. We are uncertain about what causes the discrepancies in the comparisons.</p>
 +
</div>
 +
</div>
 +
 +
<div class="project_row">
 +
<hr class="para">
 +
<h1>Future Plan</h1>
 +
<p>In the interest of providing an efficient and accessible device that can identify the [K<sup>+</sup>] into real field, we plan to optimize our construct in a device using a paper-based cell-free transcription-translation (TX-TL) system.</p>
 +
</div>
 +
 +
<div class="project_row">
 +
<hr class="para">
 +
<h2>Materials and Methods</h2>
 +
<p>Please refer to <a href ="https://2015.igem.org/Team:HKUST-Rice/Protocol">our protocol page for the materials and methods used in characterization.</a></p>
 +
</div>
 +
 +
<div class="project_row">
 +
<hr class="para">
 +
<h2>References</h2>
 +
<p style="font-size:125%">Kelly, J. R., Rubin, A. J., Davis, J. H., Ajo-Franklin, C. M., Cumbers, J., Czar, M. J., ... & Endy, D. (2009). Measuring the activity of BioBrick promoters using an in vivo reference standard. <i>Journal of biological engineering</i>, 3(1), 4.
 +
<br><br>International Plant Nutrition Institute. (1998). Functions of Potassium in Plants. <i>Better Crops</i>, 82(3).
 +
<br><br>Keseler et al. (2013), EcoCyc: fusing model organism databases with systems biology, <i>Nucleic Acids Research</i> 41: D605-12.</p>
 +
<h2>References on potassium uptake and regulation systesm in <i>E. coli</i></h2>
 +
<p style="font-size:125%">Epstein, W., & Kim, B. S. (1971). Potassium transport loci in <i>Escherichia coli</i> K-12. <i>Journal of Bacteriology, 108</i>(2), 639-644.
 +
<br><br>Jung, K., Tjaden, B., & Altendorf, K. (1997). Purification, reconstitution, and characterization of KdpD, the turgor sensor of <i>Escherichia coli.</i> <i>Journal of Biological Chemistry, 272</i>(16), 10847-10852.
 +
<br><br>Jung, K., Veen, M., & Altendorf, K. (2000). K<sup>+</sup> and ionic strength directly influence the autophosphorylation activity of the putative turgor sensor KdpD of <i>Escherichia coli</i>. <i>Journal of Biological Chemistry, 275 </i>(51), 40142-40147.
 +
<br><br>Jung, K., Krabusch, M., & Altendorf, K. (2001). Cs+ Induces the kdp operon of <i>Escherichia coli</i> by Lowering the Intracellular K<sup>+</sup> Concentration. <i>Journal of bacteriology, 183</i>(12), 3800-3803.
 +
<br><br>Laermann, V., Ćudić, E., Kipschull, K., Zimmann, P., & Altendorf, K. (2013). The sensor kinase KdpD of <i>Escherichia coli</i> senses external K<sup>+</sup>. <i>Molecular microbiology, 88</i>(6), 1194-1204.
 +
<br><br>Laimins, L. A., Rhoads, D. B., & Epstein, W. (1981). Osmotic control of kdp operon expression in <i>Escherichia coli. Proceedings of the National Academy of Sciences, 78 </i>(1), 464-468.
 +
<br><br>Narayanan, A., Paul, L. N., Tomar, S., Patil, D. N., Kumar, P., & Yernool, D. A. (2012). Structure-function studies of DNA binding domain of response regulator KdpE reveals equal affinity interactions at DNA half-sites. <i>PloS one, 7</i>(1), e30102.
 +
<br><br>Polarek, J. W., Williams, G., & Epstein, W. (1992). The products of the kdpDE operon are required for expression of the Kdp ATPase of <i>Escherichia coli. Journal of bacteriology, 174 </i>(7), 2145-2151.
 +
<br><br>Roe, A. J., McLaggan, D., O’Byrne, C. P., & Booth, I. R. (2000). Rapid inactivation of the <i>Escherichia coli</i> Kdp K<sup>+</sup> uptake system by high potassium concentrations. <i>Molecular microbiology, 35</i>(5), 1235-1243.
 +
<br><br>Sugiura, A., Nakashima, K., Tanaka, K., & Mizuno, T. (1992). Clarification of the structural and functional features of the osmoregulated kdp operon of <i>Escherichia coli. Molecular microbiology, 6</i>(13), 1769-1776.
 +
<br><br>Voelkner, P., Puppe, W., & Altendorf, K. (1993). Characterization of the KdpD protein, the sensor kinase of the K<sup>+</sup>‐translocating Kdp system of <i>Escherichia coli. European Journal of Biochemistry, 217</i>(3), 1019-1026.
 +
<br><br>Walderhaug, M. O., Polarek, J. W., Voelkner, P., Daniel, J. M., Hesse, J. E., Altendorf, K., & Epstein, W. (1992). KdpD and KdpE, proteins that control expression of the kdpABC operon, are members of the two-component sensor-effector class of regulators. <i>Journal of bacteriology, 174</i>(7), 2152-2159.
 +
<br><br>Yan, H., Fukamachi, T., Saito, H., & Kobayashi, H. (2011). Expression and activity of Kdp under acidic conditions in <i>Escherichia coli. Biological and Pharmaceutical Bulletin, 34</i>(3), 426-429.
 +
<br><br>Zhang, L., Jiang, W., Nan, J., Almqvist, J., & Huang, Y. (2014). The <i>Escherichia coli</i> CysZ is a pH dependent sulfate transporter that can be inhibited by sulfite. <i>Biochimica et Biophysica Acta (BBA)-Biomembranes, 1838</i>(7), 1809-1816. </p>
 +
 
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{{HKUST-Rice Directory}}

Latest revision as of 02:27, 19 September 2015



Potassium Sensor - PkdpF

E. coli that glows in paucity of K+ - at a glance


A. E. coli engineered with BBa_K1682009 functions as a potassium biosensor. High concentrations of K+ indirectly represses the promoter KkdpF and decreases the expression of GFP.

B. The potassium sensing promoter BBa_K1682004 can detect a gradient of K+ concentrations and its activities were reported in Relative Promoter Units (RPU).

  • K+ is an essential plant macronutrient and plays vital role for maintaining high crop yield.
  • Our biosensor BBa_K1682009 monitors K+ concentration.
  • Activity of K+ sensing promoter (BBa_K1682004) was measured in Relative Promoter Unit. It can be reliably reused.


PkdpF and our engineered K+ sensor BBa_K1682009 - the full story

Potassium is an essential plant macronutrient as it is required for photosynthesis, osmoregulation, stomatal control, sugar and protein synthesis. (IPNI, 1998) The deficiency of K+ ion will result in abnormalities in plant growth and metabolism. Our aim is to engineer a potassium sensor in Escherichia coli and detect the lack of K+ in soil. To this end, we engineered PkdpF, a promoter activated under low [K+] condition, and fused it with gfp (gfpmut3b).


Endogenous potassium sensing system in E. coli

image caption

Figure 1. The Kdp K+ uptake system in E. coli.

E. coli has multiple native K+ sensing and uptake systems that we could put to use. Among them, we chose the KdpDE two-component system (TCS). It contains a membrane-bound kinase KdpD and a cytoplasmic response regulator KdpE. Stimulated by low K+ concentration, both extracelluarly and intracellularly, KdpD transphosphorylates KdpE using its own phosphate. The phospho-KdpE is then capable of activating expression of the kdpFABC operon, which codes for a transporter complex that is activated by low K+ concentration. Apart from that, E. coli also has constitutively expressed Trk and Kup transporters for K+ uptake.

*The above text is our summarized understanding on K+-sensing system using information from EcoCyc. (Keseler et al., 2013). Please refer to our references section below for a full list of references cited.


Design and Testing of potassium sensing Device

image caption

Figure 2. Construction and Testing of PkdpF. A) Positions of base substitutions to standardize PkdpF into RFC10 format. B) Single time point transfer curve for PkdpF variants along a gradient of [K+]. C) Relative GFP synthesis rate calculated from 3 measurement time points. Error bar present SEM from 3 biological replicates.

To construct a potassium-sensing device, we cloned the promoter upstream of kdpFABC operon, PkdpF, and fused it with a translation unit for GFP reporter BBa_E0240 in BioBrick RFC10 standard. The promoter activity can then be reported by the GFP level under different K+ concentrations.

However, PkdpF contains an illegal EcoRI site that prohibits standard assembly. We tackled this by constructing and testing 3 mutated versions with A (BBa_K1682002), C (BBa_K1682003), or G (BBa_K1682004) substituting the orignal T. Our results showed that all 3 variants are functional and sense [K+] from 0 to 0.1 mM. The C and G mutants had higher maximum promoter activities than the WT or A mutant. PkdpF[-15,T>G] performed well in both strength and reliablity and was therefore used in subsequent experiments.


Relative Promoter Unit Measurement of PkdpF[-15,T>G]

image caption

Figure 3. Relative promoter units (RPU) of PkdpF[-15,T>G] under different [K+]. Error bar present SEM from 3 independent experiments on different days.

We decided to report the promoter activites of PkdpF[-15,T>G] in Relative Promoter Units (RPU) because this will allow future users to compare its promoter strength with that from another promoter, and perhaps, further improve this part. The activities of PkdpF[-15,T>G] in different [K+] were measured and compared to that by BBa_I20260 following a modified protocol from Kelly et. al (2009) (see below), and was found to be ~0.5 RPU at 0 mM K+ and ~0.13 RPU 0.025 mM K+. From 0 - 0.4 mM K+, there is a 3.8 fold change in RPU.


Interference from other Endogenous Systems

image caption

Figure 4. Comparison between the activities of PkdpF[-15, T>G] in DH10B and TK2240 strain. Error bar present SEM from 3 biological replicates.

The low-affinity K+ transport systems Trk and Kup native to E. coli are constitutively expressed (Epstein & Kim, 1971). Laermann et al. (2013) discovered that knocking out the two systems in the strain TK2240 (kdp+ Δtrk Δkup) will result in a increase in expression of the kdpFABC system. We repeated that comparison using DH10B with our PkdpF[-15,T>G] promoter but obtained different results - below 0.0125 mM K+, the activity of the promoter in DH10B was significantly greater than that in TK2240. Only when [K+] > 0.05mM would we be able to observe stronger promoter activities in TK2240. We are uncertain about what causes the discrepancies in the comparisons.


Future Plan

In the interest of providing an efficient and accessible device that can identify the [K+] into real field, we plan to optimize our construct in a device using a paper-based cell-free transcription-translation (TX-TL) system.


References

Kelly, J. R., Rubin, A. J., Davis, J. H., Ajo-Franklin, C. M., Cumbers, J., Czar, M. J., ... & Endy, D. (2009). Measuring the activity of BioBrick promoters using an in vivo reference standard. Journal of biological engineering, 3(1), 4.

International Plant Nutrition Institute. (1998). Functions of Potassium in Plants. Better Crops, 82(3).

Keseler et al. (2013), EcoCyc: fusing model organism databases with systems biology, Nucleic Acids Research 41: D605-12.

References on potassium uptake and regulation systesm in E. coli

Epstein, W., & Kim, B. S. (1971). Potassium transport loci in Escherichia coli K-12. Journal of Bacteriology, 108(2), 639-644.

Jung, K., Tjaden, B., & Altendorf, K. (1997). Purification, reconstitution, and characterization of KdpD, the turgor sensor of Escherichia coli. Journal of Biological Chemistry, 272(16), 10847-10852.

Jung, K., Veen, M., & Altendorf, K. (2000). K+ and ionic strength directly influence the autophosphorylation activity of the putative turgor sensor KdpD of Escherichia coli. Journal of Biological Chemistry, 275 (51), 40142-40147.

Jung, K., Krabusch, M., & Altendorf, K. (2001). Cs+ Induces the kdp operon of Escherichia coli by Lowering the Intracellular K+ Concentration. Journal of bacteriology, 183(12), 3800-3803.

Laermann, V., Ćudić, E., Kipschull, K., Zimmann, P., & Altendorf, K. (2013). The sensor kinase KdpD of Escherichia coli senses external K+. Molecular microbiology, 88(6), 1194-1204.

Laimins, L. A., Rhoads, D. B., & Epstein, W. (1981). Osmotic control of kdp operon expression in Escherichia coli. Proceedings of the National Academy of Sciences, 78 (1), 464-468.

Narayanan, A., Paul, L. N., Tomar, S., Patil, D. N., Kumar, P., & Yernool, D. A. (2012). Structure-function studies of DNA binding domain of response regulator KdpE reveals equal affinity interactions at DNA half-sites. PloS one, 7(1), e30102.

Polarek, J. W., Williams, G., & Epstein, W. (1992). The products of the kdpDE operon are required for expression of the Kdp ATPase of Escherichia coli. Journal of bacteriology, 174 (7), 2145-2151.

Roe, A. J., McLaggan, D., O’Byrne, C. P., & Booth, I. R. (2000). Rapid inactivation of the Escherichia coli Kdp K+ uptake system by high potassium concentrations. Molecular microbiology, 35(5), 1235-1243.

Sugiura, A., Nakashima, K., Tanaka, K., & Mizuno, T. (1992). Clarification of the structural and functional features of the osmoregulated kdp operon of Escherichia coli. Molecular microbiology, 6(13), 1769-1776.

Voelkner, P., Puppe, W., & Altendorf, K. (1993). Characterization of the KdpD protein, the sensor kinase of the K+‐translocating Kdp system of Escherichia coli. European Journal of Biochemistry, 217(3), 1019-1026.

Walderhaug, M. O., Polarek, J. W., Voelkner, P., Daniel, J. M., Hesse, J. E., Altendorf, K., & Epstein, W. (1992). KdpD and KdpE, proteins that control expression of the kdpABC operon, are members of the two-component sensor-effector class of regulators. Journal of bacteriology, 174(7), 2152-2159.

Yan, H., Fukamachi, T., Saito, H., & Kobayashi, H. (2011). Expression and activity of Kdp under acidic conditions in Escherichia coli. Biological and Pharmaceutical Bulletin, 34(3), 426-429.

Zhang, L., Jiang, W., Nan, J., Almqvist, J., & Huang, Y. (2014). The Escherichia coli CysZ is a pH dependent sulfate transporter that can be inhibited by sulfite. Biochimica et Biophysica Acta (BBA)-Biomembranes, 1838(7), 1809-1816.