Potassium as a Macro-nutrient

Potassium is an essential plant macronutrients as it has numerous important roles in plants including osmoregulation, CO₂ regulation, starch synthesis and protein synthesis. Hence, the deficiency of K+ ion will result in abnormalities in plant growth and metabolism. It is fundamental to determine its concentration in soil in order to provide the proper amount of additional potassium that must be added to the plant by any particular fertilizers.

Our aim is to engineer a Potassium sensor that can detect a range of K+ concentration in the soil to ensure the suitable soil condition for the plant fitness. We utilized PKdpF, a promoter located upstream of KdpFABC operon in Escherichia coli which works under low [K⁺] condition. We put it upstream of a GFP reporter so as to characterize the promoter activity. For simplification, PKdpF will be called potassium promoter in the following context.

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Endogenous K sensing system

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The potassium ion uptake in Escherichia coli is regulated by several systems under different conditions. The potassium ion transporters, Trk and Kup are constitutively expressed (reference?) while KdpFABC, another transporter is activated under limited potassium ion concentration (reference?) and controlled by the KdpDE two-component system (TCS) (Polarek, 1992; Walderhaug, 1992). The TCS consists of KdpD which is a membrane-bound sensor kinase and KdpE which is the cytoplasmic response regulator. The autophosphorylation of KdpD transfers a phosporyl group to the KdpE upon low potassium concentration (Voelkner, 1993; Puppe, 1996; Jung ,1997a; Jung, 2000). Phosphorylated KdpE activates kdpFABC operon.

KdpDE TCS is stimulated by both intracellular and extracellular potassium ion concentration (Jung ,2000; Jung, 2001; Roe, 2000; Yan, 2011a; Laermann, 2013). The intracellular and extracellular potassium ion concentration shows an inverse correlation to KdpDE phosphorylation. Under an increase in potassium ion concentration, KdpD phosphatase activity will be enhanced, causing a decrease in phospho-KdpE and kdpFABC expression. Decreasing potassium ion concentration shows the other way around (Zhang, 2014a; Laermann, 2013).

KdpFABC transporter, which depends on ATP, is a high affinity P-Type ATPase potassium ion uptake system (Siebers, 1988; Siebers 1989). The KdpFABC transporter is specific to potassium ion (Km= 10 μM), magnesium ion (Km= 80 μM), as well as other particular substrates (Siebers, 1988). The KdpFABC complex consists of kdpA, kdpB, kdpC, and kdpF subunits. The kdpA subunit controls the binding as well as transportation of substrate and kdpB subunit pairs the energy. The kdpC subunit keeps kdpA and kdpB together (Buurman95). In addition, the kdpF gene encodes a small polypeptide which stabilize the KdpFABC complex (Altendorf98, Gassel99).

Design of K+ sensing Device

As our potassium-sensing device, we adopt the promoter kdpFp from kdpFABC operon with -28 position of transcription start site relative to start the first gene, kdpF. The -10 and -35 box elements have been mapped which are TACCCT and TTGCGA respectively (Sugiura et al., 1992). The transcription factor, phosphorylated KdpE, binds to the kdpFp at binding site located from -71 to -55 site with reference to the transcription start site (Sugiura et al., 1992; Narayanan et al., 2012). We then combined the promoter 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.

Illegal Site <-- how to make it a small title?

In order to make our promoters, kdpFp, compatible with Biobrick RFC 10 standard, it should not contain any of the illegal sites (as they belong to the prefix and suffix). However, the promoter contains an EcoRI illegal site from -18 to -12 position. To make the potassium promoter readily accessible to the whole iGEM community, we removed that illegal site by mutating the thymine at -15 position to guanine, cytosine and adenine to give rise to 3 promoter mutants. Also, by removing the illegal site, different mutants of this promoter with different activity levels can be generated. We can choose the one with desirable activity to fit our need.

Apart from the wild-type kdpFp (containing illegal site), We designed another 3 mutants which have one base-pair at -15 position with reference to the transcription start site, changed from thymine (T) to either cytosine (C), guanine (G) or adenine (A). For convenience, we denote them as kdpFp(A)/A-mutant, kdpFp(G)/G-mutant and kdpFp(C)/C-mutant respectively. All the mutants, thereby, have their illegal site removed. However, we are expecting different activity from the four promoters due to their difference in binding energy between the promoter and RNA polymerase because of the base-pair changes (Brewster, 2012). Therefore, we characterized all of the promoters later to compare their strength by the mean of fluorescence level and RPU measurements so as to obtain a more comprehensive knowledge in the activity and working range of the 4 kdpFp promoters.

Interference from other Endogenous Systems <-- this one too

Another concern is the masking of activity of kdpFp by other native constitutive potassium transport systems of E.coli. Other than the inducible KdpFABC system(Km=2uM), E. coli has Trk and Kup systems which are constitutively expressed, low-affinity potassium transport systems (Km=1.5mM) (reference?). A study has found that the expression level of KdpFABC is generally higher in a strain without Trk and Kup system (Laimins et al., 1981). It is due to the fact that E. coli uses the two saturable transporters, Trk and Kup, under normal physiological conditions to uptake extracellular potassium ion. Therefore, only at a very low concentration of intracellular potassium, these two systems can no longer satisfy the need of potassium ion of E. coli. Hence, the kdpFp will be activated and drive the expression of KdpFABC complex to uptake more K+. As the result, the activity of kdpFp may be masked. The activity of this promoter cannot be truly reflected over a range of K+ concentration in the presence of these 2 systems (Laermann et al., 2013).

We decided to measure the activity of kdpFp in E.coli TK2240 (kdp+ Δtrk Δkup) strain, which is a strain defectve in Trk and Kup system. Such that we are able to characterize kdpFp promoter in a more accurate manner.