Difference between revisions of "Team:Bielefeld-CeBiTec/Results/Selection/KnockOutKnochIn"

(Created page with "{{Template:Bielefeld-CeBiTec/header}} <html> <body> <div class="container main"> <div class="container text_header"><h1>Große Überschrift</h1></div> <div class="contain...")
 
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<div class="container text_header"><h1><i>In vivo</i> selection</h1></div>
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<div class="container text">
<div class="container text_header"><h1>Große Überschrift</h1></div>
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The first steps have been made. The proof was given, that both created fusion proteins of our bacterial two-hybrid system are <a href="https://2016.igem.org/Team:Bielefeld-CeBiTec/Results/Selection/ExpressionControl">expressed</a> by the cell. Also, the positive control HA4 and SH2 are <a href="https://2016.igem.org/Team:Bielefeld-CeBiTec/Results/Selection/InteractionControl">interacting</a> with each other and the chosen DNA
 
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binding domain cI of the phage 434 is <a href="https://2016.igem.org/Team:Bielefeld-CeBiTec/Results/Selection/BindingControl">binding</a> at the specific binding site OR1 upstream of the promoter. Now the parts <a href="http://parts.igem.org/Part:BBa_K2082221">BBa_K2082221</a> with the functional HA4-rpoZ fusion protein and <a href="http://parts.igem.org/Part:BBa_K2082231">BBa_K2082231</a> with the functional SH2-cI fusion protein and
<div class="container text_header"><h3>Überschrift</h3></div>
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the reporter of the bacterial two-hybrid system has to be combined in one <i>E. coli</i> culture. Also the created HA4 mutations and the Gal4-RpoZ part (<a href="http://parts.igem.org/Part:BBa_K2082226">BBa_K2082226</a>) as the negative vontrol were tested together with BBa_K2082231. After a successful transformation with both plasmids a visible difference between the five approaches could not be seen. (<b>Picture?</b>)
<div class="container text"> Text </div>
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Also changing the cI protein and binding site to the lambda cI do not consult in new results.
 
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<figure class="figure">
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Therefore, the decision was made, that the use of the same pUC19-derived pMB1 origin of replication with pSB1C3 and pSB1K3 could be a problem, because<i> E. coli</i> is not able to control the amount of plasmid in the cell if both plasmids have the same ori. The next step was the changing of the backbone of the part with SH2-cI and the reporter from pSB1K3 to <a href="http://parts.igem.org/Part:pSB4C5">pSB4C5</a>. The pSB4C5 vektor uses the pSC101 replication origing.
  <img src="Pfad" class="figure-img" alt="Alternativer Text">
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For different antibiotic resistances the other fusion protein HA4-RpoZ was cloned in the pSB1K3 vektor. To test the efficieny of the new constructs, both were transformed in the <i>E. coli</i> strain KRX together. A comparison of a culture with cells carrying both plasmids and a culture with only the pSB4C5 plasmid containing the reporter and the SH2-cI fusion protein reveals visible differences in the RFP fluorescence intensity. The culture with both plasmids has a higher
  <figcaption class="figure-caption">Beschreibung</figcaption>
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visual red colour (figure X)<b>(Picture)</b>. To validate the results, the two cultures were measured in the <a href="https://2016.igem.org/Team:Bielefeld-CeBiTec/Experiments/Protocols#tecan">TECAN</a> plate reader (figure X).<img align="left" src="https://static.igem.org/mediawiki/2016/1/13/Bielefeld_CeBiTec_2016_10_18_SEL_RFP_B2H.png" width=45%> Like expectet, the two measured samples differ from each other. A comparison of the RFP intensity demonstrates an about 48&#037;  higher RFP signal if the bacteria carrying both fusion proteins SH2-cI and HA4-RpoZ except only the SH2-cI. To calculate if the difference can be
</figure>
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pointed out as significant, an unpaired two sample t-test was applied(figure X). With a  calculated t-value of 4.62 and the corresponding p-value of 0.0099 the possibility, that the difference between these two fluorescence signals are completly random is lower than 1&#037;. 
 
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Due to the fact that the results are very significant the evidence is given, that <i>in vivo</i> selection with our designed bacterial two-hybrid system is possible.
 +
<br>
 +
<div id="CRISPR"></div>
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Although it is shown that the bacterial two-hybrid system is working, the output signal is lower than expectet. Two possibilities could increase the transcription activity of the bacterial two-hybrid selection system. The first oppertunity is the reduction of the background activity of the promoter. The used promoter <a href="http://parts.igem.org/Part:BBa_K2082210">BBa_K2082210</a> is a little bit leaky, therefore, without any interaction of the two fusion proteins the gene is a little bit expressed.
 +
In the measurement the reporter was brought in the pSB4C5 plasmid. For the plasmid itself a very high nanogram amount of DNA was measured after every plasmid isolation. Therefore, the plasmid is believed to be a high copy plasmid. Although the promoter is only a little bit leaky, the high amount of plasmid leads to a high number of the reporter gene. And if every reporter is a little bit leaky, the sole number of the reporter causes a high signal of RFP. This is seen in the figure X,  considering that the RFP signal is extremly high, without any transcription activation through the two fusion proteins.
 +
The second possibility for the low activation rate of the selection system is the native <i>rpoZ</i> gene in the <i>E. coli</i> cell. RpoZ is a subunit of the RNA polymerase I core complex. Under normal conditions the RpoZ protein would be guided by the beta&acute;-subunit to the core complex of the polymerase as the last unit.  If <i>E. coli</i> produces a lot of native RpoZ it competes with the RpoZ coupled with the HA4 monobody. Therefore, it is possible, that most of the most polymerases build their core with the native RpoZ instead the RpoZ-HA4 fusion protein. In this status it is not able to be recruited by the second
 +
fusion protein and the transcription activation of the reporter stay off.
 +
<br>
 +
An interesting fact is, that the RNA polymerase do not necessarily needs the RpoZ protein fo their functionality (Gosh et al., 2001; Mathew et al., 2005). Therefore the next step for the bacterial two-hybrid system is a knock-out of the native <i>rpoZ</i> gene combinded with a knock-in of the beta-lactamase containing reporter(<a href="http://parts.igem.org/Part:BBa_K2082238">BBa_K2082238</a>) in the genome of our working strain JS200 of <i>E. coli</i>. With this attempt it is possible to decrease the background activity of the reporter by only one copy of the reporter left in the cell and to eleminate the expression of the native RpoZ
 +
and preventing the competiton of the native RpoZ with the RpoZ-HA4 fusion protein in one step.
 +
<img align="right" src="https://static.igem.org/mediawiki/2016/c/c7/Bielefeld_CeBiTec_2016_10_18_SEL_Cas_Illustration.png" width=47% />
 +
The realization of such an experiment was made with the two plasmid CRISPR/Cas-system. The first plasmid contains the Cas protein and the second the small guide RNA sequence. If the guide RNA is expressed it can guide the Cas Protein to one specific sequence on the DNA. Now the Cas protein is able to cut the DNA at this specific sequence. Under normal conditions the cell would recognize the broken genome and would begin with a degeneration process of the whole cell. But by adding the right linear DNA sequence additional to the both plasmids within the bacterium, a special repair machanism
 +
can cut out the broken sequence in the genome and add instead the added DNA sequence at the same place. In this experiment a DNA sequence containing the reporter was created, which is able to repair the genome after the Cas protein did a cut inside the <i>rpoZ</i> gene. Therefore the bacterium needs to cut out the <i>rpoZ</i> gene completly and has to integrate the designed DNA sequence to be alive.
 +
Based on the beta-lactamase gene, which was implemented by the knock-in of the reporter, the cultures were plated on LB agar with a low concentration of ampicillin on it. Some of the growing cultures were picked for a colony PCR validation (figure X).
 +
<br>
 +
Some bands on the gel are 2300 to 2400 base-pairs long. This is the expectet length of the genomic sequence of the flanked <i>rpoZ</i> gene, therefore, these results are negative. However, 5 bands on the gel are longer with about 3000 base-pairs. With a length of about 1000 base-pairs of the reporter and each time 1000 base-pairs of the two flanked fragments of the designed DNA construct, the expectet length for a successful integration of the reporter gene in the genome was given.
 +
Therefore, the knock-out, knock-in experiment was successful and the reporter was perfectly integrated into the JS200 genome.
 +
<br>
 +
<center><img src="https://static.igem.org/mediawiki/2016/3/3d/Bielefeld_CeBiTec_2016_10_19_SEL_CRISPR.png" width=50%></center>
 +
<br>
 +
Although the integration was successful, it was not possible to test the advantages of this modification <i>in vivo</i>, because the time was to short. Also the different HA4 mutants could not be tested, because the cloning from pSB1C3 to pSB1K3 took to much time, so that the final measurement of the system with the mutants could not be completed.
 +
Nevertheless we can proudly say, that we designed a functional bacterial two-hybrid system and we prepared the lanes for upcoming experiments with the system.
 +
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Revision as of 01:01, 19 October 2016



In vivo selection

The first steps have been made. The proof was given, that both created fusion proteins of our bacterial two-hybrid system are expressed by the cell. Also, the positive control HA4 and SH2 are interacting with each other and the chosen DNA binding domain cI of the phage 434 is binding at the specific binding site OR1 upstream of the promoter. Now the parts BBa_K2082221 with the functional HA4-rpoZ fusion protein and BBa_K2082231 with the functional SH2-cI fusion protein and the reporter of the bacterial two-hybrid system has to be combined in one E. coli culture. Also the created HA4 mutations and the Gal4-RpoZ part (BBa_K2082226) as the negative vontrol were tested together with BBa_K2082231. After a successful transformation with both plasmids a visible difference between the five approaches could not be seen. (Picture?) Also changing the cI protein and binding site to the lambda cI do not consult in new results.
Therefore, the decision was made, that the use of the same pUC19-derived pMB1 origin of replication with pSB1C3 and pSB1K3 could be a problem, because E. coli is not able to control the amount of plasmid in the cell if both plasmids have the same ori. The next step was the changing of the backbone of the part with SH2-cI and the reporter from pSB1K3 to pSB4C5. The pSB4C5 vektor uses the pSC101 replication origing. For different antibiotic resistances the other fusion protein HA4-RpoZ was cloned in the pSB1K3 vektor. To test the efficieny of the new constructs, both were transformed in the E. coli strain KRX together. A comparison of a culture with cells carrying both plasmids and a culture with only the pSB4C5 plasmid containing the reporter and the SH2-cI fusion protein reveals visible differences in the RFP fluorescence intensity. The culture with both plasmids has a higher visual red colour (figure X)(Picture). To validate the results, the two cultures were measured in the TECAN plate reader (figure X). Like expectet, the two measured samples differ from each other. A comparison of the RFP intensity demonstrates an about 48% higher RFP signal if the bacteria carrying both fusion proteins SH2-cI and HA4-RpoZ except only the SH2-cI. To calculate if the difference can be pointed out as significant, an unpaired two sample t-test was applied(figure X). With a calculated t-value of 4.62 and the corresponding p-value of 0.0099 the possibility, that the difference between these two fluorescence signals are completly random is lower than 1%. Due to the fact that the results are very significant the evidence is given, that in vivo selection with our designed bacterial two-hybrid system is possible.
Although it is shown that the bacterial two-hybrid system is working, the output signal is lower than expectet. Two possibilities could increase the transcription activity of the bacterial two-hybrid selection system. The first oppertunity is the reduction of the background activity of the promoter. The used promoter BBa_K2082210 is a little bit leaky, therefore, without any interaction of the two fusion proteins the gene is a little bit expressed. In the measurement the reporter was brought in the pSB4C5 plasmid. For the plasmid itself a very high nanogram amount of DNA was measured after every plasmid isolation. Therefore, the plasmid is believed to be a high copy plasmid. Although the promoter is only a little bit leaky, the high amount of plasmid leads to a high number of the reporter gene. And if every reporter is a little bit leaky, the sole number of the reporter causes a high signal of RFP. This is seen in the figure X, considering that the RFP signal is extremly high, without any transcription activation through the two fusion proteins. The second possibility for the low activation rate of the selection system is the native rpoZ gene in the E. coli cell. RpoZ is a subunit of the RNA polymerase I core complex. Under normal conditions the RpoZ protein would be guided by the beta´-subunit to the core complex of the polymerase as the last unit. If E. coli produces a lot of native RpoZ it competes with the RpoZ coupled with the HA4 monobody. Therefore, it is possible, that most of the most polymerases build their core with the native RpoZ instead the RpoZ-HA4 fusion protein. In this status it is not able to be recruited by the second fusion protein and the transcription activation of the reporter stay off.
An interesting fact is, that the RNA polymerase do not necessarily needs the RpoZ protein fo their functionality (Gosh et al., 2001; Mathew et al., 2005). Therefore the next step for the bacterial two-hybrid system is a knock-out of the native rpoZ gene combinded with a knock-in of the beta-lactamase containing reporter(BBa_K2082238) in the genome of our working strain JS200 of E. coli. With this attempt it is possible to decrease the background activity of the reporter by only one copy of the reporter left in the cell and to eleminate the expression of the native RpoZ and preventing the competiton of the native RpoZ with the RpoZ-HA4 fusion protein in one step. The realization of such an experiment was made with the two plasmid CRISPR/Cas-system. The first plasmid contains the Cas protein and the second the small guide RNA sequence. If the guide RNA is expressed it can guide the Cas Protein to one specific sequence on the DNA. Now the Cas protein is able to cut the DNA at this specific sequence. Under normal conditions the cell would recognize the broken genome and would begin with a degeneration process of the whole cell. But by adding the right linear DNA sequence additional to the both plasmids within the bacterium, a special repair machanism can cut out the broken sequence in the genome and add instead the added DNA sequence at the same place. In this experiment a DNA sequence containing the reporter was created, which is able to repair the genome after the Cas protein did a cut inside the rpoZ gene. Therefore the bacterium needs to cut out the rpoZ gene completly and has to integrate the designed DNA sequence to be alive. Based on the beta-lactamase gene, which was implemented by the knock-in of the reporter, the cultures were plated on LB agar with a low concentration of ampicillin on it. Some of the growing cultures were picked for a colony PCR validation (figure X).
Some bands on the gel are 2300 to 2400 base-pairs long. This is the expectet length of the genomic sequence of the flanked rpoZ gene, therefore, these results are negative. However, 5 bands on the gel are longer with about 3000 base-pairs. With a length of about 1000 base-pairs of the reporter and each time 1000 base-pairs of the two flanked fragments of the designed DNA construct, the expectet length for a successful integration of the reporter gene in the genome was given. Therefore, the knock-out, knock-in experiment was successful and the reporter was perfectly integrated into the JS200 genome.

Although the integration was successful, it was not possible to test the advantages of this modification in vivo, because the time was to short. Also the different HA4 mutants could not be tested, because the cloning from pSB1C3 to pSB1K3 took to much time, so that the final measurement of the system with the mutants could not be completed. Nevertheless we can proudly say, that we designed a functional bacterial two-hybrid system and we prepared the lanes for upcoming experiments with the system.