Team:Warsaw/Project

From 2014.igem.org

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<p>Tell us more about your projectGive us background. Use this as the abstract of your projectBe descriptive but concise (1-2 paragraphs) </p>
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<div align="justify">
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<p>Did you ever wonder what are the parts in your smartphone, laptop , etc. made of that make them go round?
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Well, have a read and find out!
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<br>
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Lanthanides, often referred to as the rare earth metals, are important materials for the manufacture of almost all electronics.
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Not just the majority of your favourite gadgets like smartphones, tablets and NVDs (if you use one) but also TVs, radios etc. <br> contain semiconductor elements made with those metals.<br>Also some lanthanides salts were applied as catalysts in some organic reactions. <br><br>
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Nowadays, most available lanthanide ores are already on the brink of total exploitation. More worryingly still,it is very hard to isolate and purify lanthanides from solid electronics waste or sewer. There are techniques to do so, such as  ion-exchange chromatography,
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<br>
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but they are difficult to implement and rather ineffective, since the physical and chemical differences between these elements are small. This, in turn, renders them difficult to apply on an industrial scale. Faced with this predicament, we think that lanthanide recycling from waste seems a vital technological issue nowadays.
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<br><br>
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Henceforth, basing on the work done by scientists at the Massachusetts Institute of Technology [1] and the University of Chicago [2], we created our lanthanide-oriented project, which has two main points: <br><br>
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Firstly, we would like to recreate part of the work done by the University of  Chicago group in constructing
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an E.coli-based sensor system that would be capable of binding lanthanide ions using a modified two-componentPmrA/PmrB system from Salmonella,
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<br>
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and induce expression of GFP whenever such binding event occurred, allowing for detection
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of lanthanide ions in the environment. Secondly, we intend to devise a method for quantification of these ions
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using fluorescence measurements while creating BioBrick elements for respective elements of this system. <br> However, our ultimate goal is to invent a bacterial system capable of detecting and binding lanthanide ions (via lanthanide-binding proteins). The ions could be later extracted from the protein which in turn allow us to recycle these valuable metals from the liquid waste.
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<br><br>
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To sum up, a bacterial system providing  both signalling the presence of lanthanides in a liquid medium (e.g. sewer waste) in an easy-to-detect way and production of proteins that bind these lanthanides in stable complexes was proposed.<br> Moreover, design of abovementioned binding systems is the first step to creating an easy and efficient technology for eco-friendly retrieval of those industrially significant elements, and we look forward to potential collaborations with iGEM teams that share our goals in this year’s competition!
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<br>
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<br>
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</div>
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Further reading
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<ol>
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<li>Daughtry, K. et al. (2012). Tailoring Encodable Lanthanide-Binding Tags as MRI Contrast Agents. ChemBioChem , p. 2567-2574. </li>
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<li> Liang, H. et al. (2013). Engineering Bacterial Two-Component System PmrA/PmrB to Sense Lanthanide Ions. Journal of the American Chemical Society , pstr. 2037-2039. </li>
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</ol>
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<h3>References </h3>
<h3>References </h3>

Revision as of 21:48, 15 August 2014



WELCOME TO iGEM 2014!

Your team has been approved and you are ready to start the iGEM season!
On this page you can document your project, introduce your team members, document your progress
and share your iGEM experience with the rest of the world!


Click here to edit this page!

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Project Description

Content

Did you ever wonder what are the parts in your smartphone, laptop , etc. made of that make them go round? Well, have a read and find out!
Lanthanides, often referred to as the rare earth metals, are important materials for the manufacture of almost all electronics. Not just the majority of your favourite gadgets like smartphones, tablets and NVDs (if you use one) but also TVs, radios etc.
contain semiconductor elements made with those metals.
Also some lanthanides salts were applied as catalysts in some organic reactions.

Nowadays, most available lanthanide ores are already on the brink of total exploitation. More worryingly still,it is very hard to isolate and purify lanthanides from solid electronics waste or sewer. There are techniques to do so, such as ion-exchange chromatography,
but they are difficult to implement and rather ineffective, since the physical and chemical differences between these elements are small. This, in turn, renders them difficult to apply on an industrial scale. Faced with this predicament, we think that lanthanide recycling from waste seems a vital technological issue nowadays.

Henceforth, basing on the work done by scientists at the Massachusetts Institute of Technology [1] and the University of Chicago [2], we created our lanthanide-oriented project, which has two main points:

Firstly, we would like to recreate part of the work done by the University of Chicago group in constructing an E.coli-based sensor system that would be capable of binding lanthanide ions using a modified two-componentPmrA/PmrB system from Salmonella,
and induce expression of GFP whenever such binding event occurred, allowing for detection of lanthanide ions in the environment. Secondly, we intend to devise a method for quantification of these ions using fluorescence measurements while creating BioBrick elements for respective elements of this system.
However, our ultimate goal is to invent a bacterial system capable of detecting and binding lanthanide ions (via lanthanide-binding proteins). The ions could be later extracted from the protein which in turn allow us to recycle these valuable metals from the liquid waste.

To sum up, a bacterial system providing both signalling the presence of lanthanides in a liquid medium (e.g. sewer waste) in an easy-to-detect way and production of proteins that bind these lanthanides in stable complexes was proposed.
Moreover, design of abovementioned binding systems is the first step to creating an easy and efficient technology for eco-friendly retrieval of those industrially significant elements, and we look forward to potential collaborations with iGEM teams that share our goals in this year’s competition!

Further reading
  1. Daughtry, K. et al. (2012). Tailoring Encodable Lanthanide-Binding Tags as MRI Contrast Agents. ChemBioChem , p. 2567-2574.
  2. Liang, H. et al. (2013). Engineering Bacterial Two-Component System PmrA/PmrB to Sense Lanthanide Ions. Journal of the American Chemical Society , pstr. 2037-2039.

References

iGEM teams are encouraged to record references you use during the course of your research. They should be posted somewhere on your wiki so that judges and other visitors can see how you though about your project and what works inspired you.

You can use these subtopics to further explain your project

  1. Overall project summary
  2. Project Details
  3. Materials and Methods
  4. The Experiments
  5. Results
  6. Data analysis
  7. Conclusions

It's important for teams to describe all the creativity that goes into an iGEM project, along with all the great ideas your team will come up with over the course of your work.

It's also important to clearly describe your achievements so that judges will know what you tried to do and where you succeeded. Please write your project page such that what you achieved is easy to distinguish from what you attempted.

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