Team:Warsaw/Project
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<p> We concluded that quantities of observed species change according to these equations: | <p> We concluded that quantities of observed species change according to these equations: | ||
<img src="https://static.igem.org/mediawiki/2014/3/34/Warsaw_dpmrnaprmb.gif" alt="Equation 1" /> | <img src="https://static.igem.org/mediawiki/2014/3/34/Warsaw_dpmrnaprmb.gif" alt="Equation 1" /> | ||
- | <img src="https://static.igem.org/mediawiki/2014/ | + | <img src="https://static.igem.org/mediawiki/2014/1/1f/Mrnapmra2.gif" alt="Equation 2" /> |
<img src="https://static.igem.org/mediawiki/2014/3/33/Warsaw_eq3.gif" alt="Equation 3" /> | <img src="https://static.igem.org/mediawiki/2014/3/33/Warsaw_eq3.gif" alt="Equation 3" /> | ||
<img src="https://static.igem.org/mediawiki/2014/5/52/Warsaw_eq4.gif" alt="Equation 4" /> | <img src="https://static.igem.org/mediawiki/2014/5/52/Warsaw_eq4.gif" alt="Equation 4" /> | ||
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<img src="https://static.igem.org/mediawiki/2014/4/48/Warsaw_eq6.gif" alt="Equation 6" /> | <img src="https://static.igem.org/mediawiki/2014/4/48/Warsaw_eq6.gif" alt="Equation 6" /> | ||
<img src="https://static.igem.org/mediawiki/2014/3/3b/Warsaw_eq7.gif" alt="Equation 7" /> | <img src="https://static.igem.org/mediawiki/2014/3/3b/Warsaw_eq7.gif" alt="Equation 7" /> | ||
- | <img src="https://static.igem.org/mediawiki/2014/ | + | <img src="https://static.igem.org/mediawiki/2014/c/c1/Mrnarp2.gif" alt="Equation 8" /> |
<img src="https://static.igem.org/mediawiki/2014/c/c3/Warsaw_eq9.gif" alt="Equation 9" /> | <img src="https://static.igem.org/mediawiki/2014/c/c3/Warsaw_eq9.gif" alt="Equation 9" /> | ||
where: | where: |
Revision as of 21:22, 16 October 2014
The Project
Background
Lanthanides are a series of fifteen chemical elements with atomic numbers 57 through 71, from lanthanum through lutetium. All but one of the lanthanides are f-block elements, corresponding to the filling of the 4f electron shell (lutetium is a d-block element). The presence of f orbitals is responsible for their unique properties such as strong paramagnetism. They are required in a variety of modern technologies, such as electronics, aviation (eg. jet engines) and superconductors In spite of their name 'rare earths metals' their deposits on Earth are not scarce but very dispersed. Hence, there are only a few places (eg. China) where their concentration is high enough to be exploited on a commercial scale. Due to that situation the lanthanides market is not getting any better, especially taking into account that demand on these metals is still on increase. Other problems with lanthanides avaibility are their difficult extraction from the ore. Most of lanthanides appear together and very similar physical properties make extraction and purification difficult. Despite heavy costs and technical difficulties lanthanides are usually purified by ion-exchange chromatography.Proof of concept
In 2013 group of prof. He from the University of Chicago published paper in Journal of American Chemical Society (J. Am. Chem. Soc. 2013 Feb 13;135(6):2037-9) in which they described thr devised lanthanide detecting system. To accomplish this, they engineered two-component system from Salmonella enterica creating the first bacteria capable of detecting lanthanides. These findings inspired us to create our bioremediating system. A general scheme of PmrA-PmrB system.Detailed explanation
In initial plans, our project would consist of two parts, first being lanthanide detecting system in BioBrick standard, much like the one constructed by group of prof. He and the second being lanthanide binding system, which would bind lanthanides much more effectively than the detecting system. Both of these systems would be based on PmrA-PmrB two-component system, native to Salmonella enterica. This system consists of two proteins, PmrA and PmrB. PmrB is a transmembrane kinase with iron (III) binding tag on it's extracellular loop. When iron (III) is bound to this tag, PmrB gains kinase activity and phosphorylates PmrA. PmrA is a transctriptoral factor and, upon activation, binds to pmrC promoter and induces expression of CheZ, a chemotaxis protein. So much for native systems.Design
Detecting system Our detecting system was planned as follows: Iron binding tag would be replaced with lanthanide binding tag (of which a various collection can be find in literature) and a reporter protein would be inserted downstream of pmrC. Thus, in the presence of lanthanides, fluorescence of GFP should be observed. Binding system Binding system would be more tricky. PmrA-PmrB would stay the same, with LBT (lanthanide binding tag) instead of iron binding tag. The difference would be downstream the pmrC promoter. First of all, we must have some sort of binding agent. We were planning to use some sort of small protein (like ubiquitin) or structurised peptide as a structural basis and fuse it with LBT. Another problem would be with pmrC. pmrC, even induced by PmrA, is a very weak promoter. So, even in the presence of lanthanides, expression of binding agent would be poor. To overcome that, we planned to use some genetic device to boost the expression from upon the pmrC. Our first idea was to put two subsequent inverters (based on different proteins, eg. tetR and lacI), which should fix the problem. Expression of binding agent would be high in the presence of lanthanides and low in absence.Binding agent expression | ||||||||
Lanthanide presence | pmrC | pmrC-inverter1 | pmrC-inverter1-inverter2 | |||||
none | zero (very low) | high | low | |||||
present | low | low | high |
Project goals
- Construction of lanthanide sensor in BioBrick standard
- Cloning of PmrA/PmrB parts into pSB1C3 in BioBrick standard
- Construction of lanthanide sensoring system with other LBT described in literature with their deposition in the Registry
- Construction of lanthanide binding system
Modelling
Two-component systems are the most prevalent mechanism of transmembrane signal transduction. They control gene expression thus make bacteria respond to environmental changes and drive pathongen-host interactions. A typical TCS consists of a membrane-bound histidine kinase and a partner response regulator protein. The pmrA/pmrB system implemented this year by our team also belongs to this class. pmrB is histidine kinase and pmrA is response regulator which when bound to pmrC promoter strongly enhances expression. In order to get better understanding of the system and to prevent any problems before starting the wet lab stage we decided to create precise model of this signaling pathway. Other two component systems were successfully modeled before, but not the pmrA/pmrB.
The modelWhen designing our model we assumed the following pathway:
- lanthanide ion binds to the pmrB protein which leads to its autophosphorylation,
- phosphorylated pmrB transphers its phosphate group onto pmrA
- phosphorylated pmrA binds to pmrC and allows expression of reporter GFP protein
- dephosphorylated pmrB induces pmrA dephoshporylation Additionally for model to work properly feedback loop in which phoshporylated pmrA induces pmrA expression is needed.
The model diagram looks as follows:
We concluded that quantities of observed species change according to these equations: where:
- mRNApmrB is concentration of pmrB mRNA, the same goes for mRNApmrA and mRNARP,
- L is lanthanide concentration,
- RP is reporter protein concentration,
- pmrB.bound is pmrB with lanthanide ion bound,
- prmB.bound.ph is phosphorylated pmrB with lanthanide ion bound,
- pmrA.ph is phosphorylated pmrA,
- ABComplex is complex of pmrA and pmrB.bound.ph during pmrA phosphorylation,
- AComplex, RPComplex are pmrA.ph inductors bound to respective promoters,
- ABRevComplex is complex of pmrA.ph and pmrB during pmrA dephosphorylation
Initial parameters were found in literature as we didn’t make component measures on our own.
Simulation and resultsDeterministic simulations were performed using TinkerCell software. There are few bugs in it, but it allows for fast model building and makes changes to the model quite easy. Simulation showed that signal greatly enhances GFP expression and that its growth is exponential with growing condensation of lanthanide ions.
GFP level when there is no lanthanide ions:
GFP levels with 100 um of ions:
ReferencesKierzek AM, Zhou L, Wanner BL. Stochastic kinetic model of two compo- nent system signalling reveals all-or-none, graded and mixed mode stochastic switching responses. Mol Biosyst. 2010;6(3):531-42
Wastewater study
System analysis
Safety
Possibilities of development
We can see two clear paths in which our project could be enhanced. One is to use more LBTs described in literature in detection and the other is to plan and construct more effective binding systems. Overmore, we had ideas about utilising some sulphur bacterias instead of E. coli. Their sulphur metabolism and ability to survive in low pH (in which metal leaching is more efficient) makes them excellent candidates for industrial utilisation of our project. Another thing that could produce glitches; our system should not be present in bacterias as plasmids. It would be much better idea to integrate it with bacterias' genome, so it would not 'mutate away' so quickly./*tu JEST KONIEC STRONY*/