Difference between revisions of "Team:OUC-China/Improve"

 
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<h3>Overview</h3>
 
<h3>Overview</h3>
 
<br />
 
<br />
This year, we have created a brand new family called Csy4 family on the basis of an existing part <a href="http://parts.igem.org/Part:BBa_K1062004">BBa_K1062004</a>. We redesign four Csy4 mutants by point mutation to form this family, whose capabilities of cleavage and recognition are different from each other. As an important role in our project miniToe family, we have tested them by several ways. We have proved that our system can work well by using Csy4 family. Now Csy4 family is an improvement and has been shown to work well in our system.  
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This year, we create a brand new family called Csy4 family on the basis of an existing part, Csy4 <a href="http://parts.igem.org/Part:BBa_K1062004">BBa_K1062004</a>. We redesign four Csy4 mutants by point mutation. The members in Csy4 family have different capabilities of cleavage and recognition. As an important role in project, we tested them by several ways. The Csy4 family works well as expectation. Csy4 family is an improvement based on existing part and is proved work well in our system.  
 
 
 
</p>
 
</p>
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<h3>Proof of functions about Csy4 family</h3>
 
<h3>Proof of functions about Csy4 family</h3>
 
<br />
 
<br />
We have done three kinds of experiments to help us confirm the function of the Csy4 family. Our aim is to get some new Csy4 mutants with different cleavage capacity, so we specifically tested this aspect of them. For testing our system, we use sfGFP as our target gene. Our expectation is that the fluorescence intensities of sfGFP can vary upon the rates of Csy4s’ cleavage. That means we have improved four new parts which present various expression of target genes.
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We did three kinds of experiments to help us confirm the function of the Csy4 family. The aim is to get some new Csy4 mutants with different capabilities. Superfolder green fluorescent protein (sfGFP) is target gene for test experiments. Our expectation is that the fluorescence intensities of sfGFP change upon various activity of Csy4 mutants. It means we have improved four new parts which present various expression of target genes.
 
 
 
 
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<h3>Prediction</h3>
 
<h3>Prediction</h3>
 
<br />
 
<br />
Before the experiments, we have proved our ideas by model. The predication below shows the possibilities of different expression levels by different Csy4 mutants. So the model help us to get more information for our improvement deeply this year!
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Before the experiments, model proved our ideas. The predication shows the possibilities of different expression levels by different Csy4 mutants. It is not difficult to predict that the cleavage rate has an influence in the expression of sfGFP.
 
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  <div align="center"><img src="https://static.igem.org/mediawiki/2018/c/ca/T--OUC-China--res23.png" height="400"> </div>
 
  <div align="center"><img src="https://static.igem.org/mediawiki/2018/c/ca/T--OUC-China--res23.png" height="400"> </div>
 
<br />
 
<br />
  <div align="center"><p >Fig.2-3 The predication: The fluorescence intensities by different Csy4 mutants along with time</p></div>
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  <div align="center"><p >Fig.1 The predication: the fluorescence intensities by different Csy4 mutants along with time.</div>
 +
<br /><br />
 +
 
 +
We designed three kinds experiments to test the capabilities of five Csy4 mutants by putting them into miniToe system. So the recombination strains for test both have same pReporter but different Csy4 mutants plasmids in the following. The recombination strains to test the functions of Csy4 are strain-Csy4 (pCsy4&pReporter), strain-Csy4-Q104A (pCsy4-Q104A&pReporter), strain-Csy4-Y176F (pCsy4-Y176F&pReporter), strain-Csy4-F155A (pCsy4-F155A&pReporter), strain-Csy4-H29A (pCsy4-H29A&pReporter). At the same time, we have a control strain named strain-miniToe-only which only has pReporter. <br /><br />
 +
<div align="center"><img src="https://static.igem.org/mediawiki/2018/7/7f/T--OUC-China--plasmid.jpg" height="200"> </div> <br />
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</p>
 
 
  
</p>
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<p>
 
<p>
<h3>The result of miniToe Motility detection system</h3>
+
<h3>The qualitative experiments by fluorescent microscope</h3>
<br /><h4 ><font size="3">Proof of functions</font></h4>
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<br />
As we shown before in the first system, we have created a new method to regulate to downstream gene expression named miniToe. And we also have proved that our system can be enlarged. So we have created miniToe family in the second system.
+
First, we have tested five different groups by Fluorescent Stereo Microscope Leica M165 FC. The sfGFP accumulated during the cultivation period so the fluorescence can be observed by microscope after 8 hours. Because the five Csy4 mutants have different capabilities of cleavage, the distinguishing intensities of fluorescent can be seen by naked eyes. The five test strains have same miniToe part but different Csy4 mutant genes. From top to bottom in Fig.2, there are fluorescence images by fluorescent microscope which indicate strain-Csy4, strain-Csy4-Q104A, strain-Csy4-Y176F, strain-Csy4-F155A and strain-Csy4-H29A in sequence. The visible distinctions have shown in these images. The fluorescence intensities decrease one by one from top to bottom which means the Csy4s' capabilities of cleavage decrease one by one. The Csy4-WT has the strongest capability of cleavage when the Csy4-H29A is a kind of dead-Csy4 (dCsy4) which is hardly to find the fluorescence by microscope. The qualitative experiment is a basis of further experiments.
<br />
+
<br />
We believe that miniToe is also a good tool which can be apply to study of molecular mechanism.
+
<br /><br />
Scientists may puzzled with the functions of certain gene or protein when first discover it. Now one common method to study single gene is knock out or knock in. In this way, organisms without one gene show the lack of forms or functions. But if we want to know better about the gene functions, we may need different level of the gene expressions.
+
<br />
+
By using our system, the motility of E.coli can be regulated. As we know, MotA provides a channel for the proton gradient required for generation of torque. ΔmotA strains can build flagella but are non-motile because they are unable to generate the torque required for flagellar rotation.  
+
<br />
+
So we have done some works to test our system in dealing with the real-world problems by E.coli motility detection experiments. We construct our circuit by putting the motA behind our miniToe structure. So the motA as a target gene can be regulated by miniToe.
+
<br />
+
Five groups have been set, three test group and two control group. And the result shown below have proved that our system can work as expectation.
+
+
+
<div align="center"><img src="https://static.igem.org/mediawiki/2018/b/b1/T--OUC-China--res41.png" width="400"> </div>
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<br />
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<div align="center"><p >Fig.4-1 The control groups including positive group and negative group. Plates were inoculated with E.coli RP437 (A1, A2, A3) which have motility and they move everywhere in the plates. The plates on right are ΔmotA (the motA-deletion strain) (B1, B2, B3), E.coli RP6666 which have no motility so the strains stay on the center. We have three biological replicates in the experiment.</p></div>
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<div align="center"><img src="https://static.igem.org/mediawiki/2018/5/5e/T--OUC-China--res42.png" height="400"> </div>
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<br />
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<br />
 
<div align="center"><p >Fig.4-2 The test group-1. The plates were inoculated with Csy4-ΔmotA (the motA-deletion strain with Csy4 but no miniToe structure).Without the gene motA, the E.coli cannot move. And the Csy4 have no big influence on strain compared with the strain, ΔmotA. We have three biological replicates in the experiment.</p></div>
 
  
<div align="center"><img src="1" height="400"> </div>  
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<div>
<div align="center"><p >
+
 
Fig.4-3 The test group-2. The plates were inoculated with miniToe-motA (the motA-deletion strain with miniToe structure but no Csy4). The circuit is on the control of miniToe and it down stream motA can be regulated without Csy4. So the expression of downstream gene motA keep closing. We have three biological replicates in the experiment.</p></div>
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<div align="center"><img src="https://static.igem.org/mediawiki/2018/2/28/T--OUC-China--JCYWT.png" width="800"> </div>
<div align="center"><img src="1" height="400"> </div>
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<div align="center"><p >Fig.2-1. The expression of sfGFP by strain-Csy4.</p></div>
 +
 
 +
 
 +
<div align="center"><img src="https://static.igem.org/mediawiki/2018/1/19/T--OUC-China--JCYQ2.png" width="800"> </div>
 +
<div align="center"><p >Fig.2-2. The expression of sfGFP by strain-Csy4-Q104A.</p></div>
 +
 
 +
 
 +
<div align="center"><img src="https://static.igem.org/mediawiki/2018/b/bb/T--OUC-China--JCYY.png" width="800"> </div>
 +
<div align="center"><p >Fig.2-3. The expression of sfGFP by strain-Csy4-Y176F.</p></div>
 +
 
 +
 
 +
<div align="center"><img src="https://static.igem.org/mediawiki/2018/8/88/T--OUC-China--JCYF.png" width="800"> </div>
 +
<div align="center"><p >Fig.2-4. The expression of sfGFP by strain-Csy4-F155A.</p></div>
 +
 
 +
<div align="center"><img src="https://static.igem.org/mediawiki/2018/f/fd/T--OUC-China--JCYH.png" width="800"> </div>
 +
<div align="center"><p >Fig.2-5. The expression of sfGFP by strain-Csy4-H29A.</p></div>
 +
 
 
<br />
 
<br />
  <div align="center"><p >
+
  <div align="center"><p >Fig.2 The fluorescence images by fluorescent microscope. From top to bottom, the images shows the expression of sfGFP by strain-Csy4, strain-Csy4-Q104A, strain-Csy4-Y176F, strain-Csy4-F155A and strain-Csy4-H29A in sequence. The plotting scale is on the right corner of images. The images on the left shows E. coli without fluorescence excitation. The images on the right represent situation when fluorescence excitation.</p></div>
Fig.4-4 The test group.</p></div>
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 +
 
 
  
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<p>
 
<p>
<h3>The result of miniToe Motility detection system</h3>
+
<h3>The result by flow cytometer</h3>
<br /><h4 ><font size="3">Proof of functions</font></h4>
+
<br />
As we shown before in the first system, we have created a new method to regulate to downstream gene expression named miniToe. And we also have proved that our system can be enlarged. So we have created miniToe family in the second system.  
+
The qualitative experiment is not enough to analyze the Csy4 mutants. So we tested miniToe family system by flow cytometer. The expression of sfGFP by strain-Csy4, strain-Csy4-Q104A, strain-Csy4-Y176F, strain-Csy4-F155A and strain-Csy4-H29A is showed in Fig.3. We find that 5 groups' fluorescence intensities have an obvious order from Csy4-WT to Csy4-H29A, which means the capabilities decrease one by one. Their order goes from strong to weak is <a href="http://parts.igem.org/Part:BBa_K2615003">Csy4-WT</a>, <a href="http://parts.igem.org/Part:BBa_K2615004">Csy4-Q104A</a>, <a href="http://parts.igem.org/Part:BBa_K2615005">Csy4-Y176F</a>,<a href="http://parts.igem.org/Part:BBa_K2615006">Csy4-F155A</a> and <a href="http://parts.igem.org/Part:BBa_K2615007">Csy4-H29A</a>.
<br />
+
 
We believe that miniToe is also a good tool which can be apply to study of molecular mechanism.
+
Scientists may puzzled with the functions of certain gene or protein when first discover it. Now one common method to study single gene is knock out or knock in. In this way, organisms without one gene show the lack of forms or functions. But if we want to know better about the gene functions, we may need different level of the gene expressions.
+
<br />
+
By using our system, the motility of E.coli can be regulated. As we know, MotA provides a channel for the proton gradient required for generation of torque. ΔmotA strains can build flagella but are non-motile because they are unable to generate the torque required for flagellar rotation.  
+
<br />
+
So we have done some works to test our system in dealing with the real-world problems by E.coli motility detection experiments. We construct our circuit by putting the motA behind our miniToe structure. So the motA as a target gene can be regulated by miniToe.
+
<br />
+
Five groups have been set, three test group and two control group. And the result shown below have proved that our system can work as expectation.
+
 
 
 
 
<div align="center"><img src="https://static.igem.org/mediawiki/2018/b/b1/T--OUC-China--res41.png" width="400"> </div>
+
<div align="center"><img src="https://static.igem.org/mediawiki/2018/e/e8/T--OUC-China--fig2-5z.png" height="400"> </div>
 
<br />
 
<br />
  <div align="center"><p >Fig.4-1 The control groups including positive group and negative group. Plates were inoculated with E.coli RP437 (A1, A2, A3) which have motility and they move everywhere in the plates. The plates on right are ΔmotA (the motA-deletion strain) (B1, B2, B3), E.coli RP6666 which have no motility so the strains stay on the center. We have three biological replicates in the experiment.</p></div>
+
  <div align="center"><p >Fig.3  The fluorescence intensities of sfGFP about Csy4 mutants by flow cytometer. Histograms show distribution of fluorescence in samples with strain-Csy4 (Black), strain-Csy4-Q104A (Orange), strain-Csy4-Y176F (Red), strain-Csy4-F155A (Blue), strain-Csy4-H29A (Green). Crosscolumn number shows fold increase of sfGFP fluorescence.</p></div>
  
<div align="center"><img src="https://static.igem.org/mediawiki/2018/5/5e/T--OUC-China--res42.png" height="400"> </div>
+
<div align="center"><img src="https://static.igem.org/mediawiki/2018/d/da/T--OUC-China--JCPE.png" height="400"> </div>
 
<br />
 
<br />
 +
<div align="center"><p >Fig.4  The Gate Mean of flow cytometer. Histograms show the relative expression of sfGFP. The five test groups present different fluorescence intensities from high to low which prove that they have different capabilities of cleavage. </p></div>
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 +
 +
</p>
 +
 +
<p>
 +
<h3>The result by microplate reader</h3>
 +
<br />
 +
Besides all the works before, we also need to know more information about the Csy4 mutants in entire cultivation period. Even though we known that our Csy4 mutants have differentiated expression level in ten-hour-culture, the expression of whole cultivation period is also a reference for us to know if our system can work as expectations. 
 +
<br /><br />
 +
So we tested five test stains individually (strain-Csy4, strain-Csy4-Q104A, strain-Csy4-Y176F, strain-Csy4-F155A and strain-Csy4-H29A) by microplate reader every two hours. The green lines in all the images represents strain-miniToe-only group keep stable. It means the miniToe structure fold well and lock the process of translation without Csy4. And the five test groups show different characteristics. In Fig.5-A, the group strain-Csy4 shows the same result with the first system. The switch turns off without IPTG (as the blue line shows). And the expression level is the highest among all the test groups which indicates the Csy4-WT has strongest capabilities (Fig.5-F). In the Fig.5-B, the tendency of fluorescence intensities by Csy4-Q104A is similar with Csy4-WT. And the expression level is lower than Csy4-WT. The Csy4-Y176F’s capabilities ranks the third. What is special is Csy4-H29A. The active site of Csy4 contains an essential histidine residue (H29) that functions as a general base during RNA strand scission. Mutation of H29 to alanine inactivates Csy4 without affecting substrate binding affinity or specificity. So Csy4-H29A is a dead-Csy4 which has high binding affinity but has lowest capabilities of cleavage as we can see in Fig.5-E. In summary, we put all the test groups together in Fig.5-F, the picture shows our prediction by model matchs the result perfectly in Fig.6.
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<div align="center"><img src="https://static.igem.org/mediawiki/2018/5/56/T--OUC-China--res27.png" height="400"> </div>
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<br />
 +
<div align="center"><p >Fig.5  The fluorescence intensities of sfGFP by microplate reader. A. strain-Csy4. B. strain-Csy4-Q104A. C. strain-Csy4-Y176F. D. strain-Csy4-F155A. E. strain-Csy4-H29A. A-E. The blue line is test group with IPTG. The yellow line is test group without IPTG. The green line is a control group which only has miniToe structure without Csy4s. F. The summary of different test groups which indicates the capabilities of Csy4 mutants. The results are listed in the order: Csy4-WT>Csy4-Q104A>Csy4-Y176F>Csy4-F155A>Csy4-H29A.  </p></div>
 
 
 +
<div align="center"><img src="https://static.igem.org/mediawiki/2018/b/ba/T--OUC-China--res28.png" height="300"> </div>
 
<br />
 
<br />
  <div align="center"><p >Fig.4-2 The test group-1. The plates were inoculated with Csy4-ΔmotA (the motA-deletion strain with Csy4 but no miniToe structure).Without the gene motA, the E.coli cannot move. And the Csy4 have no big influence on strain compared with the strain, ΔmotA. We have three biological replicates in the experiment.</p></div>
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  <div align="center"><p >Fig.6 The comparison about model and result by microplate reader.  
 
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</p></div>
<div align="center"><img src="1" height="400"> </div>
+
<div align="center"><p >
+
Fig.4-3 The test group-2. The plates were inoculated with miniToe-motA (the motA-deletion strain with miniToe structure but no Csy4). The circuit is on the control of miniToe and it down stream motA can be regulated without Csy4. So the expression of downstream gene motA keep closing. We have three biological replicates in the experiment.</p></div>
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<div align="center"><img src="1" height="400"> </div>
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<br />
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<div align="center"><p >
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Fig.4-4 The test group.</p></div>
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+
  
 
</p>
 
</p>
  
  
 +
<p>
 +
<h3>In summary</h3>
 +
<br />
 +
This year, we design Csy4 family including four mutants on the basis of <a href="http://parts.igem.org/Part:BBa_K1062004">Csy4</a> which are <a href="http://parts.igem.org/Part:BBa_K2615004">Csy4-Q104A</a>, <a href="http://parts.igem.org/Part:BBa_K2615005">Csy4-Y176F</a>,<a href="http://parts.igem.org/Part:BBa_K2615006">Csy4-F155A</a> and <a href="http://parts.igem.org/Part:BBa_K2615007">Csy4-H29A</a>. Their capabilities are different.
 +
<br /><br />
 +
<a href="http://parts.igem.org/Part:BBa_K2615003">Csy4-WT</a>, the wild type, is a member of the CRISPR family, and also the key member of our project. Csy4-WT can specifically recognize and cleave a 22nt hairpin structure. We proved that Csy4 has the strongest capabilities of the Csy4 family by analysing the results by fluorescence microscopy, flow cytometry and microplate reader experiments. And the capabilities of the remaining members in Csy4 family shows a staircase pattern.
 +
<br /><br />
 +
<a href="http://parts.igem.org/Part:BBa_K2615004">Csy4-Q104A</a>, whose capabilities rank the second in Csy4 family. By point mutation, and we change the CAG(encoding Gln) to GCG(encoding Ala) on the 104th site. It can recognize and cleave miniToe structure on the RNA level, regulating the expression of downstream genes. By experiment, we find the expression level of strain-Csy4-Q104A was about half that of stain-Csy4-WT's.
 +
<br /><br />
 +
<a href="http://parts.igem.org/Part:BBa_K2615005">Csy4-Y176F</a>, which rank the third in Csy4 family. It is designed in the same way as Csy4-Q104A, but with the 176th site changed from TAC(encoding Tyr) to TTT(encoding Phe). By wet experiments, the expression level of downstream genes present stepwise decline from Csy4-WT to Csy4-Y176F.
 +
<br /><br />
 +
<a href="http://parts.igem.org/Part:BBa_K2615006">Csy4-F155A</a>, No.4 in the Csy4 family. We changed its 155th site from TTC(encoding Phe) to GCG(encoding Ara). It has a weaker capability of cleavage and recognition.
 +
<br /><br />
 +
<a href="http://parts.igem.org/Part:BBa_K2615007">Csy4-H29A</a>, the most special one in Csy4 family, whose 29th site is changed from CAC(encoding His ) to GCG(encoding Ara). Csy4-H29A has a high binding affinity but the lowest ability of cleavage, named dead-Csy4. There is no doubt that the downstream gene expression level by Csy4-H29A is the lowest in the family.
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<br /><br /><br /><br />
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<h3><font size="6" color="#008B45">Achievements</font></h3>
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<font size="4" color="black">
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<h3>Gold parts: Improving an existing part</h3>
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Improving an existing Part Standardization and building up on existing parts are the fundaments of iGEM. We have created FOUR new BioBrick Part (BBa_K2615004, BBa_K2615005, BBa_K2615006, BBa_K2615007) that has a functional improvement upon an existing BioBrick Part (BBa_K1062004). The sequences of four new parts and existing part are different, and the new parts are changed by point mutation. We have showed experimental result in both parts to demonstrate the improvement. We documented its experimental characterization on Part's Main Page on the Registry and submitted the sample to the Registry.
 +
<br /><br />See the pages below for details:
 +
<br />The existing part
 +
<br /><a href="http://parts.igem.org/Part:BBa_K1062004">parts.igem.org/Part:BBa_K1062004</a>
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<br /><br />
 +
The four improved parts
 +
<br /><a href="http://parts.igem.org/Part:BBa_K2615004">parts.igem.org/Part:BBa_K2615004</a>
 +
<br /><a href="http://parts.igem.org/Part:BBa_K2615005">parts.igem.org/Part:BBa_K2615005</a>
 +
<br /><a href="http://parts.igem.org/Part:BBa_K2615006">parts.igem.org/Part:BBa_K2615006</a>
 +
<br /><a href="http://parts.igem.org/Part:BBa_K2615007">parts.igem.org/Part:BBa_K2615007</a>
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<div id="class" align="center" style= "margin: 0cm 0cm 0pt; text-align: left"> </font>
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<div align="center"><img src="https://static.igem.org/mediawiki/2018/f/fc/T--OUC-China--%E7%BA%BF.png" width="900"></div>
  
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<br /> <br /> <br /> <br /> <br /> <br />
  
<br /><h4 ><font size="3">reference</font></h4>
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[1] Ravichandar J D, Bower A G, Julius A A, et al. Transcriptional control of motility enables directional movement of Escherichia coli in a signal gradient[J]. Scientific Reports, 2017, 7(1).
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   <div class="copyright1">Contact Us : oucigem@163.com  | &copy;2018 OUC IGEM.All Rights Reserved.  |  ………… </div>
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   <div class="copyright1">Contact Us : oucigem@163.com  | &copy;2018 OUC IGEM.All Rights Reserved. <br />
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<img src="https://static.igem.org/mediawiki/2017/b/b4/T--OUC-China--foot1.jpeg"alt="banner"width="80px">
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<img src="https://static.igem.org/mediawiki/2017/6/62/T--OUC-China--foot2.jpeg"alt="banner"width="80px">
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<img src="https://static.igem.org/mediawiki/2018/f/f3/T--OUC-China--lalala.png"alt="banner"width="80px">
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<img src="https://static.igem.org/mediawiki/2017/5/51/T--OUC-China--NSG.png"alt="banner"height="65px">
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<img src="https://static.igem.org/mediawiki/2017/2/2a/T--OUC-China--ML.png"alt="banner"height="65px">&emsp;
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  </div>
 
 
  

Latest revision as of 02:56, 18 October 2018

Team OUC-China: Main
banner

Improve

Overview


This year, we create a brand new family called Csy4 family on the basis of an existing part, Csy4 BBa_K1062004. We redesign four Csy4 mutants by point mutation. The members in Csy4 family have different capabilities of cleavage and recognition. As an important role in project, we tested them by several ways. The Csy4 family works well as expectation. Csy4 family is an improvement based on existing part and is proved work well in our system.

Proof of functions about Csy4 family


We did three kinds of experiments to help us confirm the function of the Csy4 family. The aim is to get some new Csy4 mutants with different capabilities. Superfolder green fluorescent protein (sfGFP) is target gene for test experiments. Our expectation is that the fluorescence intensities of sfGFP change upon various activity of Csy4 mutants. It means we have improved four new parts which present various expression of target genes.

Prediction


Before the experiments, model proved our ideas. The predication shows the possibilities of different expression levels by different Csy4 mutants. It is not difficult to predict that the cleavage rate has an influence in the expression of sfGFP.

Fig.1 The predication: the fluorescence intensities by different Csy4 mutants along with time.



We designed three kinds experiments to test the capabilities of five Csy4 mutants by putting them into miniToe system. So the recombination strains for test both have same pReporter but different Csy4 mutants plasmids in the following. The recombination strains to test the functions of Csy4 are strain-Csy4 (pCsy4&pReporter), strain-Csy4-Q104A (pCsy4-Q104A&pReporter), strain-Csy4-Y176F (pCsy4-Y176F&pReporter), strain-Csy4-F155A (pCsy4-F155A&pReporter), strain-Csy4-H29A (pCsy4-H29A&pReporter). At the same time, we have a control strain named strain-miniToe-only which only has pReporter. 


The qualitative experiments by fluorescent microscope


First, we have tested five different groups by Fluorescent Stereo Microscope Leica M165 FC. The sfGFP accumulated during the cultivation period so the fluorescence can be observed by microscope after 8 hours. Because the five Csy4 mutants have different capabilities of cleavage, the distinguishing intensities of fluorescent can be seen by naked eyes. The five test strains have same miniToe part but different Csy4 mutant genes. From top to bottom in Fig.2, there are fluorescence images by fluorescent microscope which indicate strain-Csy4, strain-Csy4-Q104A, strain-Csy4-Y176F, strain-Csy4-F155A and strain-Csy4-H29A in sequence. The visible distinctions have shown in these images. The fluorescence intensities decrease one by one from top to bottom which means the Csy4s' capabilities of cleavage decrease one by one. The Csy4-WT has the strongest capability of cleavage when the Csy4-H29A is a kind of dead-Csy4 (dCsy4) which is hardly to find the fluorescence by microscope. The qualitative experiment is a basis of further experiments.


Fig.2-1. The expression of sfGFP by strain-Csy4.

Fig.2-2. The expression of sfGFP by strain-Csy4-Q104A.

Fig.2-3. The expression of sfGFP by strain-Csy4-Y176F.

Fig.2-4. The expression of sfGFP by strain-Csy4-F155A.

Fig.2-5. The expression of sfGFP by strain-Csy4-H29A.


Fig.2 The fluorescence images by fluorescent microscope. From top to bottom, the images shows the expression of sfGFP by strain-Csy4, strain-Csy4-Q104A, strain-Csy4-Y176F, strain-Csy4-F155A and strain-Csy4-H29A in sequence. The plotting scale is on the right corner of images. The images on the left shows E. coli without fluorescence excitation. The images on the right represent situation when fluorescence excitation.

The result by flow cytometer


The qualitative experiment is not enough to analyze the Csy4 mutants. So we tested miniToe family system by flow cytometer. The expression of sfGFP by strain-Csy4, strain-Csy4-Q104A, strain-Csy4-Y176F, strain-Csy4-F155A and strain-Csy4-H29A is showed in Fig.3. We find that 5 groups' fluorescence intensities have an obvious order from Csy4-WT to Csy4-H29A, which means the capabilities decrease one by one. Their order goes from strong to weak is Csy4-WT, Csy4-Q104A, Csy4-Y176F,Csy4-F155A and Csy4-H29A.

Fig.3  The fluorescence intensities of sfGFP about Csy4 mutants by flow cytometer. Histograms show distribution of fluorescence in samples with strain-Csy4 (Black), strain-Csy4-Q104A (Orange), strain-Csy4-Y176F (Red), strain-Csy4-F155A (Blue), strain-Csy4-H29A (Green). Crosscolumn number shows fold increase of sfGFP fluorescence.


Fig.4  The Gate Mean of flow cytometer. Histograms show the relative expression of sfGFP. The five test groups present different fluorescence intensities from high to low which prove that they have different capabilities of cleavage.

The result by microplate reader


Besides all the works before, we also need to know more information about the Csy4 mutants in entire cultivation period. Even though we known that our Csy4 mutants have differentiated expression level in ten-hour-culture, the expression of whole cultivation period is also a reference for us to know if our system can work as expectations. 

So we tested five test stains individually (strain-Csy4, strain-Csy4-Q104A, strain-Csy4-Y176F, strain-Csy4-F155A and strain-Csy4-H29A) by microplate reader every two hours. The green lines in all the images represents strain-miniToe-only group keep stable. It means the miniToe structure fold well and lock the process of translation without Csy4. And the five test groups show different characteristics. In Fig.5-A, the group strain-Csy4 shows the same result with the first system. The switch turns off without IPTG (as the blue line shows). And the expression level is the highest among all the test groups which indicates the Csy4-WT has strongest capabilities (Fig.5-F). In the Fig.5-B, the tendency of fluorescence intensities by Csy4-Q104A is similar with Csy4-WT. And the expression level is lower than Csy4-WT. The Csy4-Y176F’s capabilities ranks the third. What is special is Csy4-H29A. The active site of Csy4 contains an essential histidine residue (H29) that functions as a general base during RNA strand scission. Mutation of H29 to alanine inactivates Csy4 without affecting substrate binding affinity or specificity. So Csy4-H29A is a dead-Csy4 which has high binding affinity but has lowest capabilities of cleavage as we can see in Fig.5-E. In summary, we put all the test groups together in Fig.5-F, the picture shows our prediction by model matchs the result perfectly in Fig.6.

Fig.5  The fluorescence intensities of sfGFP by microplate reader. A. strain-Csy4. B. strain-Csy4-Q104A. C. strain-Csy4-Y176F. D. strain-Csy4-F155A. E. strain-Csy4-H29A. A-E. The blue line is test group with IPTG. The yellow line is test group without IPTG. The green line is a control group which only has miniToe structure without Csy4s. F. The summary of different test groups which indicates the capabilities of Csy4 mutants. The results are listed in the order: Csy4-WT>Csy4-Q104A>Csy4-Y176F>Csy4-F155A>Csy4-H29A.


Fig.6 The comparison about model and result by microplate reader.

In summary


This year, we design Csy4 family including four mutants on the basis of Csy4 which are Csy4-Q104A, Csy4-Y176F,Csy4-F155A and Csy4-H29A. Their capabilities are different.

Csy4-WT, the wild type, is a member of the CRISPR family, and also the key member of our project. Csy4-WT can specifically recognize and cleave a 22nt hairpin structure. We proved that Csy4 has the strongest capabilities of the Csy4 family by analysing the results by fluorescence microscopy, flow cytometry and microplate reader experiments. And the capabilities of the remaining members in Csy4 family shows a staircase pattern.

Csy4-Q104A, whose capabilities rank the second in Csy4 family. By point mutation, and we change the CAG(encoding Gln) to GCG(encoding Ala) on the 104th site. It can recognize and cleave miniToe structure on the RNA level, regulating the expression of downstream genes. By experiment, we find the expression level of strain-Csy4-Q104A was about half that of stain-Csy4-WT's.

Csy4-Y176F, which rank the third in Csy4 family. It is designed in the same way as Csy4-Q104A, but with the 176th site changed from TAC(encoding Tyr) to TTT(encoding Phe). By wet experiments, the expression level of downstream genes present stepwise decline from Csy4-WT to Csy4-Y176F.

Csy4-F155A, No.4 in the Csy4 family. We changed its 155th site from TTC(encoding Phe) to GCG(encoding Ara). It has a weaker capability of cleavage and recognition.

Csy4-H29A, the most special one in Csy4 family, whose 29th site is changed from CAC(encoding His ) to GCG(encoding Ara). Csy4-H29A has a high binding affinity but the lowest ability of cleavage, named dead-Csy4. There is no doubt that the downstream gene expression level by Csy4-H29A is the lowest in the family.



Achievements

Gold parts: Improving an existing part

Improving an existing Part Standardization and building up on existing parts are the fundaments of iGEM. We have created FOUR new BioBrick Part (BBa_K2615004, BBa_K2615005, BBa_K2615006, BBa_K2615007) that has a functional improvement upon an existing BioBrick Part (BBa_K1062004). The sequences of four new parts and existing part are different, and the new parts are changed by point mutation. We have showed experimental result in both parts to demonstrate the improvement. We documented its experimental characterization on Part's Main Page on the Registry and submitted the sample to the Registry.

See the pages below for details:
The existing part
parts.igem.org/Part:BBa_K1062004

The four improved parts
parts.igem.org/Part:BBa_K2615004
parts.igem.org/Part:BBa_K2615005
parts.igem.org/Part:BBa_K2615006
parts.igem.org/Part:BBa_K2615007






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