Revision as of 18:49, 31 October 2017

Composite part

「Description」

At the beginning, we read a flood of literature, and we found that rare earth elements, especially the capture methods, attracted numerous scholars both at home and abroad to explore. They have already constructed successful genetically encoded sensors for some rare earth elements. However, the lanthanide elements,one of the important and wealthy rare earth elements,are not included. Consequently, this year,our team are eager to fill the research vacancy.

We want to construct an intelligent system. Only when the concentration of the lanthanide ions reach the threshold, does it react.

In order to reach our goal, we need a smart sensing circuit. Fortunately,we found a two-component system called pmrA/pmrB. This system itself is aimed at detecting iron ions. If we can find appropriate sequence which can react to lanthanide ions, we can replace the iron-binding sequence with them to achieve our goal.

Through consulting a large number of literature, we made it! We know the most successful lanthanide binder is lanthanide-binding tag.And we will call it LBT in the following. After exchanging sequences, we fuse the pmrC promoter to the gfp gene which encodes green fluorescent protein to prove whether or not the PmrA-B-LBT are responsive to lanthanide.

Ions sensing is just the first step, then we need to capture them. In this part, we also use LBT——our good lanthanide hunter.

In order to capture more efficiently, we repeat them three times on cell with GS-Linker between each.

Now our bacteria have collected a lot of lanthanide ions. What we need to do at last is just capturing our cells. So we designed the Si-tag,which we did in our team's previous project,to combine the bacteria with silicon in order to get our bacteria back.

The circuit below can illustrate our project better:

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-                    <p style="margin-top: 10px;">At the beginning, we read a large amount of literature, and we found that rare earth elements, especially the methods of recycling, attracted a lot of people to study. They have already constructed successful genetically encoded sensors for some rare earth elements. However, the lanthanide ion, as an important rare earth element,are not included.  Consequently, our team are eager to solve this problem this year.</p>
+                    <p style="margin-top: 10px;">At the beginning, we read  a flood of literature, and we found that rare earth elements, especially the capture methods, attracted numerous scholars both at home and abroad to explore. They have already constructed successful genetically encoded sensors for some rare earth elements. However, the  lanthanide elements,one of the important and wealthy rare earth elements,are not included.  Consequently, this year,our team are eager to fill the research vacancy.</p>
-                    <p>We want to construct a smart system. Only when the concentration of the lanthanide ions in the environment reaches the threshold, it reacts. </p>
+                    <p>We want to construct an intelligent system. Only when the concentration of the lanthanide ions reach the threshold, does it react. </p>
-                    <p>In order to reach our goal, we need a smart sensing part. We found a two-component system called PmrA/PmrB. This system itself is aimed at iron ions. But if we can find the appropriate sequence which can react to lanthanide ions, we can replace the iron-binding with our own sequence and achieve our goal of sensing.
+                    <p>In order to reach our goal, we need a smart sensing circuit. Fortunately,we found a two-component system called pmrA/pmrB. This system itself is aimed at detecting iron ions. If we can find appropriate sequence which can react to lanthanide ions, we can replace the iron-binding sequence with them to achieve our goal.
-                    <p>Fortunately, we did find it! Through the search, we know the most successful lanthanide binder is lanthanide-binding tag.We will call it LBT in the following.  After replacing, we fuse the pmrC promoter to the <I>gfp</I> gene which encodes green fluorescent protein to prove whether or not the PmrA-B-LBT are responsive to lanthanide.</p>
+                    <p>  Through consulting a large number of literature, we made it! We know the most successful lanthanide binder is lanthanide-binding tag.And we will call it LBT in the following.  After exchanging sequences, we fuse the pmrC promoter to the <I>gfp</I> gene which encodes green fluorescent protein to prove whether or not the PmrA-B-LBT are responsive to lanthanide.</p>
                     <p>Ions sensing is just the first step, then we need to capture them. In this part, we also use LBT——our good lanthanide hunter.</p>
                     <p>In order to capture more efficiently, we repeat them three times on cell with GS-Linker between each.</p>
-                    <p>Now our bacteria have collected a lot of lanthanide ions. What we need to do at last is just capturing our cells. So we used the Si-tag which we did in the previous project of our team to combine the bacteria with silicon to capture our bacteria.</p>
+                    <p>Now our bacteria have collected a lot of lanthanide ions. What we need to do at last is just capturing our cells. So we designed the Si-tag,which we did in our team's previous project,to combine the bacteria with silicon in order to get our bacteria back.</p>
                     <p><span><strong>The circuit below can illustrate our project better:</strong><span></p>
                      <img title="demo1" src="https://static.igem.org/mediawiki/2017/3/3b/2017_HUST_China_Description_image1.png" alt="demo1" class="col-xs-4 col-xs-offset-4" style="padding: 10px 0px;">

Difference between revisions of "Team:HUST-China/Description"

Revision as of 18:49, 31 October 2017

「Description」