Difference between revisions of "Team:Tongji China/Demonstrate"

 
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Here you can read detailed descriptions of the experiments we've done. To read about how we structured and planned our work, see the <a href="https://2018.igem.org/Team:Tongji_China/Design">Design</a>.
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You can get straight to a section by following these links:<br><br>
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<div style="text-align:center"><font size="5" face="Trebuchet MS";>
 
<a href="#1">Plasmid Construction</a><br>
 
<a href="#1">Plasmid Construction</a><br>
 
<a href="#2">Electroporation of <I>P. aeruginosa</I></a><br>
 
<a href="#2">Electroporation of <I>P. aeruginosa</I></a><br>
<a href="#3">Functional Analysis of T3SS system</a><br>
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<a href="#3">Functional Analysis of T3SS</a><br>
<a href="#4">Future Plans</a>
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<a href="#4">Future Plans</a></font>
 
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</div>
  
 
<a name="1">&emsp;</a>
 
<a name="1">&emsp;</a>
 
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<br><br><br>
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                 <h1>Plasmid Construction</h1>
 
                 <h1>Plasmid Construction</h1>
 
<div class="achievement">
 
<div class="achievement">
 
<p class="littletitle">Achievements</p>
 
<p class="littletitle">Achievements</p>
 
<ul>
 
<ul>
<li>Successfully conduct 2 plasmids containing positive control antigen DNA.</li>
+
<li>Successfully construct 2 plasmids containing positive control antigen DNA.</li>
<li>Successfully conduct 4 plasmids containing antigen DNA according to our filteration.</li>
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<li>Successfully construct 4 plasmids containing antigen DNA according to our filtration.</li>
 
</ul>
 
</ul>
 
</div>
 
</div>
 
<br>
 
<br>
 
<p class="littletitle">Introduction</p>
 
<p class="littletitle">Introduction</p>
In order to let the P. aeruginosa inject the antigens into the antigen presenting cells (APCs), we first need to add the antigens into the T3SS plasmid. Escherichia-Pseudomonas shuttle expression plasmid pExoS54F (shows in Figure 1), which encodes the T3SS effector ExoS promoter with N-terminal ExoS1–54 signal sequence, followed by a FLAG tag and a multiple cloning site (MCS). The pExoS54F plasmid contains two promoter region which can be activated simultaneously by ExsA binding to their common promoter region. PexoS is the promoter region which originally belongs to the toxin gene ExoS and the wild type P. aeruginosa inject the toxin ExoS into the host cell through the T3SS. The P. aeruginosa strain we use has knocked out the ExoS gene so we utilize its promoter and its N-terminal ExoS1–54 signal sequence which act as a T3SS secretion signal to let the T3SS secret proteins of interest. SpcS is a kind of T3SS chaperone and help the proteins of interest to enter the T3SS secretion channel.<br><br>
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In order to let the <I>P. aeruginosa</I> inject the antigens into the antigen presenting cells (APCs), we first need to add the DNA sequences of antigens into the T3SS plasmid. The plasmid we use is <I>Escherichia-Pseudomonas</I> shuttle expression plasmid pExoS54F (shown in <B>Figure 1</B>), which encodes the promoter of T3SS effector ExoS with N-terminal ExoS1–54 signal sequence, followed by a FLAG-tag and a multiple cloning site (MCS). The pExoS54F plasmid contains two promoter region which can be activated simultaneously by ExsA's binding to their common promoter region. PexoS is the promoter region which originally belongs to the toxin gene ExoS and the wild type <I>P. aeruginosa</I> inject the toxin ExoS into the host cells through the T3SS. The ExoS gene of the <I>P. aeruginosa</I> strain we use has been knocked out so we utilize its promoter and its N-terminal ExoS1–54 signal sequence which act as a T3SS secretion signal to let the T3SS secret proteins of interest. SpcS is a kind of T3SS chaperone and helps the proteins of interest to enter the T3SS secretion channel.<br><br>
 
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/d/da/T--Tongji_China--picture-experiment-1.png" width="70%" height="90%"></p>
 
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/d/da/T--Tongji_China--picture-experiment-1.png" width="70%" height="90%"></p>
 
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<br>
 
<br>
The proteins contained in the pExoS54F are actually not all the proteins that function in the T3SS protein delivery. There are approximately 40 proteins that regulate the secretion of T3SS effector proteins and many of them are encoded in the P. aeruginosa genome. The protein ExsE, ExsC, ExsD and ExsA are four cytoplasmic proteins (shows in the Figure 2) that control the coupling of transcription and secretion. ExsA is a DNA-binding protein required for transcriptional activation of the entire T3SS. The second regulatory protein, ExsD, functions as anti-activator by directly binding to ExsA. ExsC functions as an anti-anti-activator by directly binding to and inhibiting ExsD.  ExsE functions as a direct inhibitor of ExsC and provide an initiating signal for the whole process. Figure 2 shows the situation when the T3SS secretion is inhibit because the direct activator ExsA is inhibited by the binding ExsD.<br><br>
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The proteins encoded by the pExoS54F plasmid are actually not all the proteins that function in the process of T3SS protein delivery. There are approximately 40 proteins that regulate the secretion of T3SS effector proteins and many of them are encoded in the <I>P. aeruginosa</I> genome. The protein ExsE, ExsC, ExsD and ExsA are four cytoplasmic proteins (shown in the <B>Figure 2</B>) that control the coupling of transcription and secretion. ExsA is a DNA-binding protein required for transcriptional activation of the entire T3SS. The second regulatory protein, ExsD, functions as an anti-activator by directly binding to ExsA. ExsC functions as an anti-anti-activator by directly binding to and inhibiting ExsD.  ExsE functions as a direct inhibitor of ExsC and provide an initiating signal for the whole process. <B>Figure 2</B> shows the situation when the T3SS secretion is inhibited because the direct activator ExsA is inhibited by the binding ExsD.<br><br>
 
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/8/80/T--Tongji_China--picture-experiment-2.png" width="70%" height="90%"></p>
 
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/8/80/T--Tongji_China--picture-experiment-2.png" width="70%" height="90%"></p>
 
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<p class="littletitle">Results</p>
 
<p class="littletitle">Results</p>
 
<b>1.Sequence Synthesis</b><br><br>
 
<b>1.Sequence Synthesis</b><br><br>
As we successfully filter many antigens which may active the immune system and guide the T cells to target to the cancer, we choose 4 of them and two positive control antigens – NY-ESO-A and NY-ESO-B. NY-ESO is widely known as a germ cell protein that is often expressed by tumor cells but not normal somatic cells. The frequent finding of humoral and cellular immune responses against this antigen in cancer patients with NY-ESO-expressing tumors makes it one of the most immunogenic human tumor antigens known. Table 1 shows the antigens sequences.<br><br>
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As we successfully filtered many antigens which may active the immune system and guide the T cells to target to the tumor cells, we choose 4 of them and two positive controls: NY-ESO-A and NY-ESO-B. NY-ESO is widely known as a germ cell protein that is often expressed by tumor cells but not normal somatic cells. The frequent finding of humoral and cellular immune responses against this antigen in cancer patients with NY-ESO-expressing tumors makes it one of the most immunogenic human tumor antigens ever known. <b>Table 1</b> shows the sequences of these antigens.<br><br>
 
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<div class="instructionOfPicture">
<b>Table1</b> | our antigen sequences
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<b>Table1</b> | sequences of antigens
 
</div>
 
</div>
<br> Because the antigen sequence is quite short, we cannot choose the common way of synthesizing double strand. So we synthesize the 5’-3’single strand and the 3’-5’single strand with restriction site on both side, then take the method of annealing (see in the <a href="/Team:Tongji_China/Protocol">protocol</a>.) to pair two single strands into a double strand (Figure 3). Table 2 shows all the single strands we synthesized.
+
<br> Because the antigen sequences are quite short, we cannot choose the common way of synthesizing double strands. So we synthesize the 5’-3’ single strands and the 3’-5’ single strands with restriction site on both sides, then take the method of annealing (see in the <a href="/Team:Tongji_China/Protocol">protocol</a>) to pair two single strands into a double strand (<b>Figure 3</b>). <b>Table 2</b> shows all the single strands we synthesized.
 
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<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/6/68/T--Tongji_China--picture-experiment-3.png" width="100%" height="90%" /></p>
 
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/6/68/T--Tongji_China--picture-experiment-3.png" width="100%" height="90%" /></p>
                         <div class="instructionOfPicture">
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                         <br><div class="instructionOfPicture">
 
<b>Figure 3</b> | Annealing
 
<b>Figure 3</b> | Annealing
 
</div>
 
</div>
 
<br><br>
 
<br><br>
<b>2.Plasmid Restricted Digestion</b>
+
<b>2.Plasmid Restriction Digestion</b>
 
<br><br>
 
<br><br>
We use the restriction endonuclease Xal I and Sal I to digest the pExoS54F plasmid (see in the <a href="/Team:Tongji_China/Protocol">protocol</a>). Also the antigen sequences we synthesized have the restriction site of Xal I and Sal I. we set the single digestion control and the plasmid control to figure out whether the plasmid is digested completely. The DNA gel electrophoresis results (Figure 4) shows that the digestion is complete.
+
We use the restriction endonuclease Xbal I and Sal I to digest the pExoS54F plasmid (see in the <a href="/Team:Tongji_China/Protocol">protocol</a>). Also the antigen sequences we synthesized have the restriction site of Xbal I and Sal I. we set the single digestion control and the plasmid control to figure out whether the plasmid is digested completely. The DNA gel electrophoresis results (<b>Figure 4</b>) show that the digestion is complete.
 
<br><br>
 
<br><br>
  
 
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/f/fe/T--Tongji_China--picture-experiment-4.png" width="70%" height="90%" /></p>
 
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/f/fe/T--Tongji_China--picture-experiment-4.png" width="70%" height="90%" /></p>
 
<div class="instructionOfPicture">
 
<div class="instructionOfPicture">
<b>Figure 4</b> | DNA gel electrophoresis results for plasmid restricted digestion
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<b>Figure 4</b> | DNA gel electrophoresis results for plasmid restriction digestion
 
</div>
 
</div>
<br>
+
<br><br>
 
<b>3. Ligation & Transformation</b>
 
<b>3. Ligation & Transformation</b>
 
<br><br>
 
<br><br>
We ligase the digestion product and double-stranded fragment using T4 DNA ligase and conduct the chemical transfection (see in the <a href="/Team:Tongji_China/Protocol">protocol</a>). We conduct the colony PCR to test whether the colonies contain the right plasmid (see in the <a href="/Team:Tongji_China/Protocol">protocol</a>). The DNA gel electrophoresis results (Figure 5) shows that some of the colonies contain the right plasmids we want.
+
We link the digestion product and double-stranded fragments using T4 DNA ligase and conduct the chemical transformation (see in the <a href="/Team:Tongji_China/Protocol">protocol</a>). We conduct the colony PCR to test whether the colonies contain the right plasmids (see in the <a href="/Team:Tongji_China/Protocol">protocol</a>). The DNA gel electrophoresis results (<b>Figure 5</b>) show that some of the colonies contain the right plasmids we want.
 
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<br>
<br><h1>Electroporation of P. aeruginosa</h1>
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<br><h1>Electroporation of <I>P. aeruginosa</I></h1>
  
 
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<div class="littletitle">Introduction </div>
 
<div class="littletitle">Introduction </div>
<br><br>
+
<br>
To deliver antigens to cells which we want to infect by T3SS system, plasmids containing antigen sequences should be transfer to Pseudomonas aeruginosa. We choose Pseudomonas aeruginosa in the strain of PAK-JΔ9 which is an attenuated strain, for it has many advantages varies from efficiency and safety.
+
To deliver antigens into cells T3SS system, plasmids containing antigen sequences should be transfered to <I>Pseudomonas aeruginosa</I>. We choose <I>Pseudomonas aeruginosa</I> strain PAK-JΔ9 which is an attenuated strain, for it has many advantages varying from efficiency to safety.
 
<br><br>
 
<br><br>
 
The transform technique we use is electroporation, the most efficient bacterial transformation method available, which orders of magnitude more efficient and versatile than chemical methods. Electroporation uses accurately pulsed electric currents to induce transient gaps in the phospholipid bilayer of cells, and extracellular genetic material passes through these transient gaps. Genetic material is assimilated by the target cells’ DNA.
 
The transform technique we use is electroporation, the most efficient bacterial transformation method available, which orders of magnitude more efficient and versatile than chemical methods. Electroporation uses accurately pulsed electric currents to induce transient gaps in the phospholipid bilayer of cells, and extracellular genetic material passes through these transient gaps. Genetic material is assimilated by the target cells’ DNA.
 
<br><br>
 
<br><br>
The highest transformation efficiencies are obtained when cells are harvested in early mid-log growth, so we should prepare bacteria before operating and make competent cells.
+
The highest transformation efficiencies are obtained when cells are harvested in early mid-log growth, so we need to prepare bacteria before operating and make competent cells.
 
<br><br>
 
<br><br>
We transform Pseudomonas aeruginosa (see in the protocol) following the Gene Pulser XcellTM Electroporation System Instruction Manual.
+
We transform <I>Pseudomonas aeruginosa</I> (see in the <a href="https://2018.igem.org/Team:Tongji_China/Protocol">Protocol</a>) following the Gene Pulser Xcell<sup>TM</sup> Electroporation System Instruction Manual.
 
<br><br><br>
 
<br><br><br>
  
 
<div class="littletitle">Results</div>
 
<div class="littletitle">Results</div>
<br><br>
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<br>
<div class="judgeTitle2">1.</div>
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<b>1. Electroporation</b><br><br>
<br><br>
+
 
 
We use Gene Pulser Xcell™ Electroporation Systems (Bio-Rad) to transform bacteria.
 
We use Gene Pulser Xcell™ Electroporation Systems (Bio-Rad) to transform bacteria.
 
<br>
 
<br>
Gene Pulser Xcell conditions: C = 25 μF; PC = 200 ohm; V = 2.5 kV
+
Gene Pulser Xcell conditions: C = 25 μF; PC = 200 ohm; V = 2.5 kV.
 
<br>
 
<br>
After pulsing the competent cells, Incubate for 1 hour and plate cells onto LB agar plates with carbenicillin. Incubate for 12 hours at 37°C. Next day, observe the growth of the bacteria.
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After pulsing the competent cells, incubate for 1 hour and plate cells onto LB agar plates with carbenicillin. Incubate for 12 hours at 37°C. Next day, observe the growth of the bacteria.
 
<br><br>
 
<br><br>
<p style="text-align:center"><img src="" width="70%" height="90%" /></p>
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<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/d/d4/T--Tongji_China--picture-experiment-dian-zhuan.png" width="70%" height="90%" /></p>
 
<div class="instructionOfPicture">
 
<div class="instructionOfPicture">
<b>Figure 1</b> | The growth of the P. aeruginosa the next day.
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<b>Figure 1</b> | The growth of the <I>P. aeruginosa</I> the next day.
 
</div>
 
</div>
 
<br>
 
<br>
<font color="red">From figure 1, we can see that</font>
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From <b>figure 1</b>, we can see that</font> there are some colonies on the LB agar plates, however, the majority are lawns. From many times of experiments, we verify this conclusion.
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<br><br>
 +
<b>2. Colony PCR</b><br><br>
  
<br><br>
+
Though there are colonies on the carbenicillin-resistant LB plate, we are not sure that the colonies contain the plasmids we want, because some colonies may be satellite colonies. So, we did colony PCR to test the presence of plasmids(Results are shown in <b>Figure 2</b>).
<div class="judgeTitle2">2.</div>
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<br><br>
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Though there are colonies on the carbenicillin-resistant LB plate, we can not sure that the colonies contain the plasmid we want, because some colonies may be satellite colonies. So, we did colony PCR to test the presence of plasmids. (Results are shown in Figure 2)
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</div>
 
</div>
 
<br>
 
<br>
From the electrophoresis results of colony PCR, we can see that the band of our target DNA fragment is in the corresponding position (~200 bp). Therefore, it is indicated that our recombinant plasmids have been successfully transferred into P. aeruginosa.
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From the electrophoresis results of colony PCR, we can see that the bands of our target DNA fragments are in the corresponding position (~200 bp). Therefore, it is indicated that our recombinant plasmids have been successfully transferred into <I>P. aeruginosa</I>.
 
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<a name="3">&emsp;</a>
 
<a name="3">&emsp;</a>
 
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<HR/>
 
<br>
 
<br>
<br>
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<h1>Functional Analysis of T3SS</h1>
<h1>Functional Analysis of T3SS system</h1>
+
  
 
<div class="achievement">
 
<div class="achievement">
 
<p class="littletitle">Achievements</p>
 
<p class="littletitle">Achievements</p>
 
<ul>
 
<ul>
<li>We confirm that P. aeruginosa can synthesize the antigens by the induction of EGTA.</li>
+
<li>We confirm that <I>P. aeruginosa</I> can synthesize the antigens by the induction of EGTA.</li>
<li>Through infection of HeLa cells in vitro, we prove that bacteria can inject antigens into cells.</li>
+
<li>Through infection of HeLa cells <I>in vitro</I>, we prove that bacteria can inject antigens into cells.</li>
 
<li>We briefly confirm that the bacteria did not secrete proteins outside the cells while attaching cells and injecting.</li>
 
<li>We briefly confirm that the bacteria did not secrete proteins outside the cells while attaching cells and injecting.</li>
<li>Using the mouse animal model, the T3SS system is proven to work in vivo.</li>
+
<li>Using the animal model, the T3SS is proved to work <I>in vivo</I>.</li>
 
</ul>
 
</ul>
 
</div>
 
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<div class="littletitle">Introduction</div>
 
<div class="littletitle">Introduction</div>
<br><br>
+
<br>
In normal low calcium environment, antigens can’t be released by bacteria.<br><br>
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In normal high calcium environment, antigens can’t be synthesized by bacteria.<br><br>
 
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/1/1d/T--Tongji_China--picture-experiment-3-0-1.png" width="75%" height="90%" /></p>
 
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/1/1d/T--Tongji_China--picture-experiment-3-0-1.png" width="75%" height="90%" /></p>
 
<div class="instructionOfPicture">
 
<div class="instructionOfPicture">
<b>Figure 1 </b>| In normal environment, pore of T3SS is closed, and antigens can’t pass through.
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<b>Figure 1 </b>| In normal environment, pore of T3SS is closed, and antigens can’t be synthesized.
 
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<b>Figure 2 </b>| Polar Translocation  
 
<b>Figure 2 </b>| Polar Translocation  
 
</div><br><br>
 
</div><br><br>
Another way is triggered with low calcium environment, such as in the presence of calcium chelator EGTA. It can trigger the bacteria to release the antigens into the culture medium without the formation of the T3SS translocon. This way works without the presence of host cells and defined as “non-polar translocation”.
+
Another way is triggered by low calcium environment, such as in the presence of calcium chelator EGTA. It can trigger the bacteria to release the antigens into the culture medium without the formation of the T3SS translocon. This way works without the presence of host cells and is defined as “non-polar translocation”.
 
<br><br>
 
<br><br>
  
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/d/d6/T--Tongji_China--picture-experiment-3-0-3.png" width="70%" height="90%" /></p>
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<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/d/d6/T--Tongji_China--picture-experiment-3-0-3.png" width="90%" height="90%" /></p>
 
<div class="instructionOfPicture">
 
<div class="instructionOfPicture">
<b>Figure 3 </b>| Polar Translocation  
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<b>Figure 3 </b>| Non-polar Translocation  
 
</div>
 
</div>
 
<br><br>
 
<br><br>
To analyze the antigen secretion ability of the engineered bacteria we construct, we use both the “non-polar translocation” way and the “polar translocation” way to conduct the experiment.
+
To analyze the antigen secretion ability of the engineered bacteria we constructed, we use both the “non-polar translocation” way and the “polar translocation” way to conduct the experiment.
The signature is detected by the Flag-tag which is carried in pExoS54F-NY-ESO-A, pExoS54F-NY-ESO-B, pExoS54F-0201, pExoS54F-0301A, pExoS54F-0301B, pExoS54F-0301C and pExoS54F-mCherry.
+
The signature is detected by the FLAG-tag which is carried in plasmids: pExoS54F-NY-ESO-A, pExoS54F-NY-ESO-B, pExoS54F-0201, pExoS54F-0301A, pExoS54F-0301B, pExoS54F-0301C and pExoS54F-mCherry. The molecular weight of the antigens is ~30 kDa in theory.
<br><br>
+
<br><br><br>
  
<div class="littletitle">Overview</div>
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<div class="littletitle">Overview</div><br>
1. First, in order to test that the bacteria can synthesize the antigens we want, EGTA is used to induce Pseudomonas aeruginosa to secrete the antigen polypeptide into the culture solution, and the presence is detected by western bolt (see result 1).<br>
+
1. First, in order to test whether the bacteria can synthesize the antigens we want, EGTA is used to induce <I>Pseudomonas aeruginosa</I> to secrete the antigen polypeptides into the culture solution, and the presence is detected by <a href="#re1">western blot (see result 1)</a>.<br><br>
2. In order to test that bacteria can inject antigens into cells, we performed in vitro infection of HeLa cells, and the presence of Flag-tag in the cells was detected by western blot (see result 2) and immunofluorescence (see result 3) to confirm the presence of antigen.<br>
+
2. In order to test whether bacteria can inject antigens into cells, we perform <I>in vitro</I> infection of HeLa cells, and the presence of FLAG-tag in the cells was detected by <a href="#re2">western blot (see result 2)</a> and <a href="#re3">immunofluorescence (see result 3)</a> to confirm the successful injection of antigens.<br><br>
3. At the same time, in order to prove that the bacteria did not secrete proteins outside the cells while attaching cells and injecting, we detected the supernatant of the infected cells by western blot (see result 4).<br>
+
3. At the same time, in order to prove that the bacteria do not secrete proteins outside the targeted cells while attaching cells and injecting, we detect the culture supernatant of the infected cells by <a href="#re4"> western blot (see result 4)</a>.<br><br>
4. Finally, using the mouse animal model, the T3SS system was further verified in vivo by immunohistochemistry (see result 5).
+
4. Finally, using the animal model, the T3SS is further verified <I>in vivo</I> by <a href="#re5">immunohistochemistry (see result 5)</a>.
<br><br>
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<br><br><br>
  
<div class="littletitle">Results</div>
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<div class="littletitle">Results<a name="re1">&emsp;</a></div>
 +
<br><br><br>
 +
<b>1. Western Blot (EGTA Induction)</b><br><br>
 +
All the proteins secreted by the <I>P. aeriginosa</I> strain PAK-J△9 are analyzed by western blot. <br>
 +
We use the calcium chelator EGTA to trigger the secretion of proteins. (To see the exact process of the induction, you can go to the <a href="https://2018.igem.org/Team:Tongji_China/Protocol">Protocol</a>.) We add 100% TCA to culture medium to reach a final concentration of approximately 10% which can precipitate the proteins form culture medium. But the final concentration of TCA may vary with the molecular weight of the precipitated protein but can't be too high, otherwise other substances will be precipitated.
 
<br><br>
 
<br><br>
<div class="judgeTitle2">RESULT 1.</div><br><br>
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First, we test which TCA concentration can better precipitate proteins from culture medium so we set the TCA concentration gradient of 10%, 15% to 20%. We randomly select one of <I>P. aeruginosa</I> which carries the antigen in theory to conduct the experiment.  
All the secretion of proteins in the P. aeriginosa strain PAK-J△9 are analyzed by western blot. <br>
+
We use the calcium chelator EGTA to trigger the secretion of proteins. (To see the exact process of the induction, you can go to the <a href="https://2018.igem.org/Team:Tongji_China/Protocol">Protocol</a>.) Add 100% TCA to culture medium to reach a final concentration of approximately 10% which can precipitate the proteins form culture medium. But the final concentration of TCA used may vary with the molecular weight of the precipitated protein and shouldn’t be too high, otherwise other substances will be precipitated.  
+
 
<br><br>
 
<br><br>
First, we test which TCA concentration can better precipitate proteins from culture medium and set the TCA concentration gradient of 10%, 15% to 20%. We randomly select one type of P. aeruginosa which carrying the antigen in theory to conduct the experiment.
+
The result is analyzed by western blot (<b>Figure 1.1</b>). As is shown in figure, 20% TCA concentration successfully precipitates the proteins. So we decide to use the 20% TCA concentration.
<br><br>
+
The result is analyzed by western blot (Figure 1.1). As is shown in figure, 20% TCA concentration successfully precipitates the proteins. So we decide to use the 20% TCA concentration.
+
 
<br><br>
 
<br><br>
 
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/7/74/T--Tongji_China--picture-experiment-3-1-1.png" width="70%" height="90%" /></p>
 
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/7/74/T--Tongji_China--picture-experiment-3-1-1.png" width="70%" height="90%" /></p>
 
<div class="instructionOfPicture">
 
<div class="instructionOfPicture">
<b>Figure 1.1 </b>| As is shown in the figure, both 10% and 15% TCA concentration cannot precipitate the proteins from culture medium, only the 20% TCA concentration can successfully precipitate the proteins.
+
<b>Figure 1.1 </b>| As is shown in the figure, both 10% and 15% TCA concentration cannot precipitate the proteins from culture medium. Only the 20% TCA concentration can successfully precipitate the proteins.
 
</div>
 
</div>
 
<br><br>
 
<br><br>
  
According to the conclusion we made in the first experiment, we conduct EGTA induction experiment to test whether the engineered P. aeruginosa we constructed can produce and secret the antigens.<br><br>
+
According to the conclusion we made in the first experiment, we conduct EGTA induction experiment to test whether the engineered <I>P. aeruginosa</I> we constructed can produce and secret the antigens.<br><br>
We set 6 test groups and a control group. Each test group contains engineered P. aeruginosa carrying the plasmid pExoS54F-NY-ESO-A, pExoS54F-NY-ESO-B, pExoS54F-0201, pExoS54F-0301A, pExoS54F-0301B and pExoS54F-0301C. The culture medium of the control group is without the presence of EGTA and the rest of the conditions are consistent with the test groups. <br><br>
+
We set 6 test groups and a control group. Each test group contains engineered <I>P. aeruginosa</I> carrying the plasmids: pExoS54F-NY-ESO-A, pExoS54F-NY-ESO-B, pExoS54F-0201, pExoS54F-0301A, pExoS54F-0301B and pExoS54F-0301C. The culture medium of the control group is without the presence of EGTA and the rest of the conditions are consistent with the test groups. <br><br>
The result is analyzed by western blot (Figure 1.2). Five antigens (NY-ESO-A, NY-ESO-B, 0201, 0301A and 0301C) are successfully secreted by bacteria.<br><br>
+
The result is analyzed by western blot (<b>Figure 1.2</b>). Five antigens (NY-ESO-A, NY-ESO-B, 0201, 0301A and 0301C) are successfully secreted by bacteria.<br><br>
  
 
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/f/f4/T--Tongji_China--picture-experiment-3-2-1.png" width="70%" height="90%" /></p>
 
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/f/f4/T--Tongji_China--picture-experiment-3-2-1.png" width="70%" height="90%" /></p>
Line 386: Line 395:
 
<br><br>
 
<br><br>
  
There may be something wrong in our operation with pExoS54F-0301B plasmid, but we don’t have enough time to test. If we have more time, we will do this experiment again using pExoS54F-0201 plasmid as positive control to make sure the whole experiment operation is correct. At the same time, we will do colony PCR to check the pExoS54F-0301B plasmids are still in our engineered P. aeruginosa. If we can’t get successful result, we will repeat experiments from Electroporation of P. aeruginosa.
+
There may be something wrong in our operation with pExoS54F-0301B plasmid, but we don’t have enough time to test. If we have more time, we will do this experiment again using pExoS54F-0201 plasmid as positive control to make sure the whole experiment operation is correct. At the same time, we will do colony PCR to check whether the pExoS54F-0301B plasmids are still in our engineered <I>P. aeruginosa</I>. If we can’t get positive result, we will repeat experiments from the pocedure of electroporation of <I>P. aeruginosa</I>. However, from the results below we can conclude that the bacteria contain these plasmids and our design is correct.
<br><br>
+
<br><a name="re2">&emsp;</a><br>
<font color="red">From another 5 plasmids, we can draw a conclusion that the bacteria can synthesize the antigens we want by the induction of EGTA.</font>
+
From another 5 plasmids, we can draw a conclusion that the bacteria can synthesize the antigens we want by the induction of EGTA.
  
<br><br>
+
<br><br><br>
<div class="judgeTitle2">RESULT 2.</div>
+
<b>2. Western Blot (Lysates of Infected Cells)</b><br><br>
<br><br>
+
We conduct an experiment to analyze whether the host cell contact can trigger the production of the antigens and whether the engineered <I>P. aeruginosa</I> can inject these antigens into host cell cytosol in the level of protein. <br><br>
We conduct an experiment to analyze whether the host cell contact can trigger the production of the antigens and whether the engineered P. aeruginosa can inject these antigens into host cell cytosol in the level of protein. <br><br>
+
We infect the HeLa cells with the engineered <I>P. aeruginosa</I> respectively carrying the plasmids: pExoS54F-NY-ESO-A, pExoS54F-NY-ESO-B, pExoS54F-0201, pExoS54F-0301A, pExoS54F-0301B and pExoS54F-0301C, then collect the lysates of HeLa cells. We analyze the cell lysates by western blot (<b>Figure 2</b>).<br><br>
We infect the HeLa cells with the engineered P. aeruginosa respectively carrying the plasmid pExoS54F-NY-ESO-A, pExoS54F-NY-ESO-B, pExoS54F-0201, pExoS54F-0301A, pExoS54F-0301B and pExoS54F-0301C, then collect the HeLa cell lysates. We analyze the cell lysates by western blot (Figure 2).<br><br>
+
  
  
<p style="text-align:center"><img src="" width="70%" height="90%" /></p>
+
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/e/e3/T--Tongji_China--picture-experiment-western-hela.png" width="70%" height="90%" /></p>
 
<div class="instructionOfPicture">
 
<div class="instructionOfPicture">
<b>Figure 2 </b>|  
+
<b>Figure 2 </b>| Western Blot (Using the cell lysates samples)
</div>
+
  
<div class="judgeTitle2">RESULT 3.</div>
+
</div>
In order to increase the persuasiveness of the experiment, we also used immunofluorescence techniques to prove that bacteria injected antigen into the cells.
+
<br><br>
 +
The result shows that all of the six antigens can be detected in the western blot. The engineered <I>P. aerugnosa</I> carrying the plasmids: pExoS54F-NY-ESO-A, pExoS54F-NY-ESO-B, pExoS54F-0201, pExoS54F-0301A, pExoS54F-0301B and pExoS54F-0301C can be successfully induced to express and inject the peptides into the host cells.<a name="re3">&emsp;</a>
 +
<br><br><br><br>
 +
<b>3. Immunofluorescence of Infected Cells</b><br><br>
 +
In order to increase the persuasiveness of the experiments, we also use immunofluorescence technique to prove that bacteria injecte antigens into the cells.
 
Immunofluorescence is a technique used for light microscopy with a fluorescence microscope and is used primarily on microbiological samples. This technique uses the specificity of antibodies to their antigen to target fluorescent dyes to specific biomolecule targets within a cell, and therefore allows visualization of the distribution of the target molecule through the sample.<br><br>
 
Immunofluorescence is a technique used for light microscopy with a fluorescence microscope and is used primarily on microbiological samples. This technique uses the specificity of antibodies to their antigen to target fluorescent dyes to specific biomolecule targets within a cell, and therefore allows visualization of the distribution of the target molecule through the sample.<br><br>
We use anti-FLAG antibody to specificity target Flag-tag, which is supposed to be in the cells. Then we use secondary antibody which carries the fluorophore, recognizes the primary antibody and binds to it. And we also use DAPI to label DNA. (You can see more details in<a href="/Team:Tongji_China/Protocol">protocol</a>.)<br><br>
+
We use anti-FLAG antibody to specifically target FLAG-tag, which is supposed to be in the cells. Then we use secondary antibody which carries the fluorophore to recognize the primary antibody and bind to it. And we also use DAPI to label DNA. (You can see more details in <a href="/Team:Tongji_China/Protocol">protocol</a>.)<br><br>
We use an epifluorescence microscope to confirm the presence of intracellular antigens and observe finer structures by using confocal microscope.
+
We use an epifluorescence microscope to confirm the presence of intracellular antigens and observe finer structures by confocal microscope.
 
<br><br>
 
<br><br>
  
 
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/3/38/T--Tongji_China--picture-experiment-3-4-1_2.png" width="70%" height="90%" /></p>
 
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/3/38/T--Tongji_China--picture-experiment-3-4-1_2.png" width="70%" height="90%" /></p>
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/3/32/T--Tongji_China--picture-experiment-3-4-2_2.png" width="70%" height="90%" /></p>
+
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/3/32/T--Tongji_China--picture-experiment-3-4-2_2.png" width="70%" height="90%" /></p>s
 
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/8/8d/T--Tongji_China--picture-experiment-3-4-3_2.png" width="70%" height="90%" /></p>
 
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/8/8d/T--Tongji_China--picture-experiment-3-4-3_2.png" width="70%" height="90%" /></p>
 
<div class="instructionOfPicture">
 
<div class="instructionOfPicture">
<b>Figure 3.1 </b>| Results of immunofluorescence pictured by epifluorescence microscope. Antigens are in red. The nuclei are stained blue by DAPI. Scar bar, <font color="red">μm.</font>
+
<b>Figure 3.1 </b>| Results of immunofluorescence pictured by epifluorescence microscope. Antigens are in green. The nuclei are stained blue by DAPI. Scar bar, 50 μm.</font>
 
</div>
 
</div>
 
<br><br>
 
<br><br>
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<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/c/c4/T--Tongji_China--picture-experiment-confocol-2.png" width="70%" height="90%" /></p>
 
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/c/c4/T--Tongji_China--picture-experiment-confocol-2.png" width="70%" height="90%" /></p>
 
<div class="instructionOfPicture">
 
<div class="instructionOfPicture">
<b>Figure 3.2 </b>| Results of immunofluorescence pictured by confocal microscope. Antigens are in red. The nuclei are stained blue by DAPI. Scar bar, <font color="red">μm.</font>
+
<b>Figure 3.2 </b>| Results of immunofluorescence pictured by confocal microscope. Antigens are in green. The nuclei are stained blue by DAPI. Scar bar, 100 μm.</font>
 
</div>
 
</div>
 
<br><br>
 
<br><br>
  
  
We can see several cells are injected antigens by T3SS system. But the efficiency is not high, which is related to the relative amount of cells and bacteria. And what caught our attention is that we can find green antigens in the group of pExoS54F-0301B plasmid, which support this plasmid is worked.
+
We can see antigens several cells are injected into cells by T3SS. But the efficiency is not high, which is related to the relative amount of cells and bacteria. And what catches our attention is that we can find green antigens in the group of pExoS54F-0301B plasmid, which support this plasmid works.<a name="re4">&emsp;</a>
 
<br><br>
 
<br><br>
So, we can confirm that, P. aeruginosa can inject antigens into cells in vitro.
+
So, we can confirm that, <I>P. aeruginosa</I> can inject antigens into cells <I>in vitro</I>.
 
<br><br>
 
<br><br>
  
  
<div class="judgeTitle2">RESULT 4.</div><br><br>
+
<b>4. Western Blot (Culture Supernatant of Infected Cells)</b><br><br>
 
In order to prove the safety of our system, we conduct an experiment to test whether the culture supernatant of bacterially infected cells contains the antigens.  
 
In order to prove the safety of our system, we conduct an experiment to test whether the culture supernatant of bacterially infected cells contains the antigens.  
 
<br><br>
 
<br><br>
We collect the culture supernatant of bacterially infected cells and use the TCA-acetone precipitation to precipitate the secreted proteins which may be contained in the culture supernatant. To prove the experimental operation is correct, we set a positive control of cell lysates (These cells are infected by P. aeruginosa carrying pExoS54F-mCherry). Then we analyze the sediment by western blot to figure out the existence of the secreted proteins (Figure 3). As is shown in the figure, all of the culture supernatant of bacterially infected cells do not contain the proteins, which further prove that our system is safe enough.
+
We collect the culture supernatant of bacterially infected cells and use the TCA-acetone precipitation to precipitate the secreted proteins which may be contained in the culture supernatant. To prove the experimental operation is correct, we set a positive control of cell lysates (These cells are infected by <I>P. aeruginosa</I> carrying pExoS54F-mCherry). Then we analyze the sediment by western blot to figure out the existence of the secreted proteins (<b>Figure 4</b>). As is shown in the figure, all of the culture supernatant of bacterially infected cells does not contain the proteins, which further proves that our system is safe enough.
 
<br><br>
 
<br><br>
  
<p style="text-align:center"><img src="" width="70%" height="90%" /></p>
+
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/d/d5/T--Tongji_China--picture-experiment-3-3-1.png" width="70%" height="90%" /></p>
 
<div class="instructionOfPicture">
 
<div class="instructionOfPicture">
<b>Figure 4 </b>| Six samples (Left) of culture supernatant of bacterially infected cells which was infected respectively by the P. aeruginosa carrying the pExoS54F-NY-ESO-A, pExoS54F-NY-ESO-B, pExoS54F-0201, pExoS54F-0301A do not show extinct signature of the existence of proteins. And the signature of positive control (Flag-mCherry) is successfully detected.
+
<b>Figure 4 </b>| Six samples (left) of culture supernatant of bacterially infected cells which was infected respectively by the <I>P. aeruginosa</I> carrying the pExoS54F-NY-ESO-A, pExoS54F-NY-ESO-B, pExoS54F-0201, pExoS54F-0301A do not show extinct signature of existence of proteins. And the signal of positive control (Flag-mCherry) is successfully detected.
 
</div>
 
</div>
 
<br><br>
 
<br><br>
 +
<a name="re5">&emsp;</a>
 +
We can draw a conclusion that our system is safe enough and only inject the antigens into cell cytosol when attaching to the cell membrane.
 +
<br><br><br>
  
We can draw a conclusion that our system is safe enough and only inject the antigens into cell cytosol when attaching the cell membrane without wasting the antigens into the culture supernatant.
 
<br><br>
 
  
 
+
<b>5. Immunohistochemistry</b><br><br>
<div class="judgeTitle2">RESULT 5.</div>
+
Finally, using the animal model, the T3SS is further verified <I>in vivo</I> by immunohistochemistry. We give mice bacteria by oral gavage. After 4 hours, the mice are dissected, frozen sections of the mice intestine are taken for immunofluorescence experiment. In this way, we check whether the T3SS is effective <I>in vivo</I>. The pictures below are part of our results, and the design of this experiment accords with our animal check in form.
<br><br>
+
Finally, using the mouse animal model, the T3SS system was further verified in vivo by immunohistochemistry. We give mice bacteria by oral gavage. After 4 hours, the mice are dissected, frozen sections of the mouse intestine are taken and do immunofluorescence experiment. In this way, we check whether the T3SS system is effective in vivo.
+
 
<br><br>
 
<br><br>
 +
<p style="text-align:center"><img src="https://static.igem.org/mediawiki/2018/1/1f/T--Tongji_China--picture--IHC.png" width="100%" height="100%" /></p>
 
<div class="instructionOfPicture">
 
<div class="instructionOfPicture">
<b>Figure 5 </b>| Six samples (Left) of culture supernatant of bacterially infected cells which was infected.
+
<b>Figure 5 </b>| The pictures are the immunohistochemistry of frozen selections of mice intestine with anti-FLAG antibody. The pictures above are all taken by the ZEISS Axio Imager 2. The time for FITC is 1000 ms while the time for DAPI is 29 ms.
 
</div>
 
</div>
 +
<br>
 +
According to the pictures above, compared to the negative control, two test groups with different kind of antigens both have some areas with higher intensity of green fluorescence. In these areas, we can find blue fluorescence inside which shows the nuclei and the peptides are secreted into the cytoplasm. From the pictures, we can conclude that it is not that efficient since there are only several positive cells in one visual field.<br><br>
 +
According to the articles before and the experiments done by other institutes, the efficiency should be higher. For we do not have enough time to revise the experimental conditions, we come up with several possible reasons for the low efficiency. Firstly, about the bacteria, there used to be bacteria saved in -80℃ which lost the plasmid. It is possible that this happened to us again. Secondly, the concentration of bacteria lavaged to the mice may be a little bit low. Thirdly, we do not add extra termination codon to the antigen so that there are several amino acids behind the antigen which may have influence on the efficiency. Also, for the background of the negative control is high, there may be something wrong with our sections or antibody.<br><br>
 +
In all, it is proved that this system works, though the efficiency is relatively low according to <I>our</I> results. With more conditions to be optimized and the design of experiments to be more precise, the results should be better. It is after all a promising system used in immunotherapy for cancer. And we will continue to work for it.
 
<br><br>
 
<br><br>
 
<div class="littletitle">Analysis</div>
 
<br><br>
 
 
<div class="littletitle">Conclusion</div>
 
<br><br>
 
 
 
<div class="reference">
 
<div class="reference">
<p><b>REFERENCE</b></p>
+
<div class="littletitle">
 +
<font face="Trebuchet MS">Reference</font></p>
 +
</div>
 
https://en.wikipedia.org/wiki/Immunofluorescence
 
https://en.wikipedia.org/wiki/Immunofluorescence
 
</div>
 
</div>
 +
 +
<br><a name="4">&emsp;</a>
 +
<br><br><br>
 +
<HR/>
 +
<br>
 +
<h1>Future plan</h1>
 +
<br><br>
 +
<div class="littletitle">1 Optimizing Experiment Condition</div>
 +
Although we obtained many positive results during the experiment, there is still a certain distance from the result we expect. We analyzed our results and list many feasible directions to optimize our experiment condition. We are planning to conduct more experiments to figure out better experiment conditions.
 +
<br><br>
 +
<div class="littletitle">2 Further Experimental Proof</div>
 +
In our lab experiment, we just do the early stage work to prove that our system works efficiently. There are lots of things we can do to further prove the feasibility of our system.
 +
<br><br>
 +
<b>1. ELISA & ELISpot</b>
 +
<br><br>
 +
Firstly, we plan to conduct ELISA and ELISpot using wild type mice to analyze whether our system can cause immune system response after at least one month engineered <I>P. aeruginosa</I> immunizing.
 +
<br><br>
 +
Enzyme-linked immunosorbent assay (abbreviated ELISA) refers to the qualitative and quantitative detection method of binding soluble antigen or antibody to a solid phase carrier, using antigen-antibody binding specificity for immune reaction. We will immunize the wild type mice by the engineered <I>P. aeruginosa</I> for at least one month and collect their serum to conduct the ELISA to analyze the IFN-γ level, which can reflect the extent of T cell activation.
 +
<br><br>
 +
Enzyme-linked immunoSpot assay (ELISpot) is a modified version of the ELISA immunoassay, allowing for the detection of cells that secrete cytokines or antibodies. Unlike ELISA, ELISpot is able to detect a single cell that secretes a protein of interest.
 +
<br><br>
 +
To conduct the ELISpot, we first need to place cytokine-specific antibodies onto an ELISpot plate, then the CD8+ T cells will be added. The activated T cells produce cytokine which binds to the antibodies. The cells are then removed whilst detection antibodies that can bind with the enzyme being added. Finally the substrate forms a colored spot on the T cells which secrete the antibody and the cells are then counted through a microscope. Through the ELISpot we can detect the percentage of activated T cells to evaluate the antigenic activity.
 +
<br><br>
 +
<b>2. Tumor cell challenge experiment</b>
 +
<br><br>
 +
If some positive signals can be detected, we will then do the tumor cell challenge experiment.
 +
<br><br>
 +
During the protection against tumor cell challenge, we will immunize the mice for at least two weeks and then challenge the immunized mice with tumor to see whether the immune system can protect the immunized mice from tumor.
 +
<br><br>
 +
Then, we will conduct experiment on tumor therapy model to test whether the activated immune system can kill the tumor cells. We can analyze the ability of the antigens by measuring the size of the tumor.
 +
<br><br>
 
<br><br>
 
<br><br>
  

Latest revision as of 03:45, 18 October 2018

Programme
Wet Lab
Experiment



Here you can read detailed descriptions of the experiments we've done. To read about how we structured and planned our work, see the Design. You can get straight to a section by following these links:






Plasmid Construction

Achievements

  • Successfully construct 2 plasmids containing positive control antigen DNA.
  • Successfully construct 4 plasmids containing antigen DNA according to our filtration.

Introduction

In order to let the P. aeruginosa inject the antigens into the antigen presenting cells (APCs), we first need to add the DNA sequences of antigens into the T3SS plasmid. The plasmid we use is Escherichia-Pseudomonas shuttle expression plasmid pExoS54F (shown in Figure 1), which encodes the promoter of T3SS effector ExoS with N-terminal ExoS1–54 signal sequence, followed by a FLAG-tag and a multiple cloning site (MCS). The pExoS54F plasmid contains two promoter region which can be activated simultaneously by ExsA's binding to their common promoter region. PexoS is the promoter region which originally belongs to the toxin gene ExoS and the wild type P. aeruginosa inject the toxin ExoS into the host cells through the T3SS. The ExoS gene of the P. aeruginosa strain we use has been knocked out so we utilize its promoter and its N-terminal ExoS1–54 signal sequence which act as a T3SS secretion signal to let the T3SS secret proteins of interest. SpcS is a kind of T3SS chaperone and helps the proteins of interest to enter the T3SS secretion channel.

Figure 1 | Escherichia-Pseudomonas shuttle expression plasmid pExoS54F

The proteins encoded by the pExoS54F plasmid are actually not all the proteins that function in the process of T3SS protein delivery. There are approximately 40 proteins that regulate the secretion of T3SS effector proteins and many of them are encoded in the P. aeruginosa genome. The protein ExsE, ExsC, ExsD and ExsA are four cytoplasmic proteins (shown in the Figure 2) that control the coupling of transcription and secretion. ExsA is a DNA-binding protein required for transcriptional activation of the entire T3SS. The second regulatory protein, ExsD, functions as an anti-activator by directly binding to ExsA. ExsC functions as an anti-anti-activator by directly binding to and inhibiting ExsD. ExsE functions as a direct inhibitor of ExsC and provide an initiating signal for the whole process. Figure 2 shows the situation when the T3SS secretion is inhibited because the direct activator ExsA is inhibited by the binding ExsD.

Figure 2 | Four cytoplasmic proteins ExsE, ExsC, ExsD and ExsA control the coupling of transcription and secretion.

Overview

1.Sequence Synthesis
2.Plasmid Restricted Digestion
3.Ligation & Transformation

Results

1.Sequence Synthesis

As we successfully filtered many antigens which may active the immune system and guide the T cells to target to the tumor cells, we choose 4 of them and two positive controls: NY-ESO-A and NY-ESO-B. NY-ESO is widely known as a germ cell protein that is often expressed by tumor cells but not normal somatic cells. The frequent finding of humoral and cellular immune responses against this antigen in cancer patients with NY-ESO-expressing tumors makes it one of the most immunogenic human tumor antigens ever known. Table 1 shows the sequences of these antigens.

Part name Antigen Sequence
BBa_K2730001 NY-ESO-A atgtcgttgttgatgctgatcacccagtgcccgttgtga
BBa_K2730002 NY-ESO-B atgcagttgtcgttgttgatgctgatcacctga
BBa_K2730003 0201 atgttgcacttgtagggctcgtagccgccggcgtga
BBa_K2730004 0301A atgcacttgtagggctcgtagccgccggcgcggtga
BBa_K2730005 0301B atggcgatctcgacccgggacccgttgtcgaagtga
BBa_K2730006 0301C atgaagttgttgaagcggcaggcggaaggcaagtga
Table1 | sequences of antigens

Because the antigen sequences are quite short, we cannot choose the common way of synthesizing double strands. So we synthesize the 5’-3’ single strands and the 3’-5’ single strands with restriction site on both sides, then take the method of annealing (see in the protocol) to pair two single strands into a double strand (Figure 3). Table 2 shows all the single strands we synthesized.

NY-ESO-A-F ctagaATGTCGTTGTTGATGCTGATCACCCAGTGCCCGTTGTGAg
NY-ESO-A-R tcgacTCATCACAACGGGCACTGGGTGATCAGCATCAACAACGACATt
NY-ESO-B-F ctagaATGCAGTTGTCGTTGTTGATGCTGATCACCTGAg
NY-ESO-B-R tcgacTCAGGTGATCAGCATCAACAACGACAACTGCATt
0201-F ctagaATGTTGCACTTGTAGGGCTCGTAGCCGCCGGCGTGAg
0201-R tcgacTCACGCCGGCGGCTACGAGCCCTACAAGTGCAACATt
0301A-F ctagaATGCACTTGTAGGGCTCGTAGCCGCCGGCGCGGTGAg
0301A-R tcgacTCACCGCGCCGGCGGCTACGAGCCCTACAAGTGCATt
0301B-F ctagaATGGCGATCTCGACCCGGGACCCGTTGTCGAAGTGAg
0301B-R tcgacTCACTTCGACAACGGGTCCCGGGTCGAGATCGCCATt
0301C-F ctagaATGAAGTTGTTGAAGCGGCAGGCGGAAGGCAAGTGAg
0301C-R tcgacTCACTTGCCTTCCGCCTGCCGCTTCAACAACTTCATt

Table2 | All the single strands


Figure 3 | Annealing


2.Plasmid Restriction Digestion

We use the restriction endonuclease Xbal I and Sal I to digest the pExoS54F plasmid (see in the protocol). Also the antigen sequences we synthesized have the restriction site of Xbal I and Sal I. we set the single digestion control and the plasmid control to figure out whether the plasmid is digested completely. The DNA gel electrophoresis results (Figure 4) show that the digestion is complete.

Figure 4 | DNA gel electrophoresis results for plasmid restriction digestion


3. Ligation & Transformation

We link the digestion product and double-stranded fragments using T4 DNA ligase and conduct the chemical transformation (see in the protocol). We conduct the colony PCR to test whether the colonies contain the right plasmids (see in the protocol). The DNA gel electrophoresis results (Figure 5) show that some of the colonies contain the right plasmids we want.

Figure 5 | DNA gel electrophoresis results for colony PCR





Electroporation of P. aeruginosa

Achievements

Successfully transfer the plasmids into P. aeruginosa.

Introduction

To deliver antigens into cells T3SS system, plasmids containing antigen sequences should be transfered to Pseudomonas aeruginosa. We choose Pseudomonas aeruginosa strain PAK-JΔ9 which is an attenuated strain, for it has many advantages varying from efficiency to safety.

The transform technique we use is electroporation, the most efficient bacterial transformation method available, which orders of magnitude more efficient and versatile than chemical methods. Electroporation uses accurately pulsed electric currents to induce transient gaps in the phospholipid bilayer of cells, and extracellular genetic material passes through these transient gaps. Genetic material is assimilated by the target cells’ DNA.

The highest transformation efficiencies are obtained when cells are harvested in early mid-log growth, so we need to prepare bacteria before operating and make competent cells.

We transform Pseudomonas aeruginosa (see in the Protocol) following the Gene Pulser XcellTM Electroporation System Instruction Manual.


Results

1. Electroporation

We use Gene Pulser Xcell™ Electroporation Systems (Bio-Rad) to transform bacteria.
Gene Pulser Xcell conditions: C = 25 μF; PC = 200 ohm; V = 2.5 kV.
After pulsing the competent cells, incubate for 1 hour and plate cells onto LB agar plates with carbenicillin. Incubate for 12 hours at 37°C. Next day, observe the growth of the bacteria.

Figure 1 | The growth of the P. aeruginosa the next day.

From figure 1, we can see that there are some colonies on the LB agar plates, however, the majority are lawns. From many times of experiments, we verify this conclusion.

2. Colony PCR

Though there are colonies on the carbenicillin-resistant LB plate, we are not sure that the colonies contain the plasmids we want, because some colonies may be satellite colonies. So, we did colony PCR to test the presence of plasmids(Results are shown in Figure 2).

Figure 2 | The electrophoresis results of colony PCR.

From the electrophoresis results of colony PCR, we can see that the bands of our target DNA fragments are in the corresponding position (~200 bp). Therefore, it is indicated that our recombinant plasmids have been successfully transferred into P. aeruginosa.





Functional Analysis of T3SS

Achievements

  • We confirm that P. aeruginosa can synthesize the antigens by the induction of EGTA.
  • Through infection of HeLa cells in vitro, we prove that bacteria can inject antigens into cells.
  • We briefly confirm that the bacteria did not secrete proteins outside the cells while attaching cells and injecting.
  • Using the animal model, the T3SS is proved to work in vivo.

Introduction

In normal high calcium environment, antigens can’t be synthesized by bacteria.

Figure 1 | In normal environment, pore of T3SS is closed, and antigens can’t be synthesized.


Secretion of the antigens can be activated in two ways.

One way is to form the host cell contact. When a contact signal has been sensed by the bacteria, a rapid production and specific insertion into the translocon follows and the antigens can successfully be injected into the host cell cytosol, without wasting them into the culture supernatant. This way is called “polar translocation”.

Figure 2 | Polar Translocation


Another way is triggered by low calcium environment, such as in the presence of calcium chelator EGTA. It can trigger the bacteria to release the antigens into the culture medium without the formation of the T3SS translocon. This way works without the presence of host cells and is defined as “non-polar translocation”.

Figure 3 | Non-polar Translocation


To analyze the antigen secretion ability of the engineered bacteria we constructed, we use both the “non-polar translocation” way and the “polar translocation” way to conduct the experiment. The signature is detected by the FLAG-tag which is carried in plasmids: pExoS54F-NY-ESO-A, pExoS54F-NY-ESO-B, pExoS54F-0201, pExoS54F-0301A, pExoS54F-0301B, pExoS54F-0301C and pExoS54F-mCherry. The molecular weight of the antigens is ~30 kDa in theory.


Overview

1. First, in order to test whether the bacteria can synthesize the antigens we want, EGTA is used to induce Pseudomonas aeruginosa to secrete the antigen polypeptides into the culture solution, and the presence is detected by western blot (see result 1).

2. In order to test whether bacteria can inject antigens into cells, we perform in vitro infection of HeLa cells, and the presence of FLAG-tag in the cells was detected by western blot (see result 2) and immunofluorescence (see result 3) to confirm the successful injection of antigens.

3. At the same time, in order to prove that the bacteria do not secrete proteins outside the targeted cells while attaching cells and injecting, we detect the culture supernatant of the infected cells by western blot (see result 4).

4. Finally, using the animal model, the T3SS is further verified in vivo by immunohistochemistry (see result 5).


Results



1. Western Blot (EGTA Induction)

All the proteins secreted by the P. aeriginosa strain PAK-J△9 are analyzed by western blot.
We use the calcium chelator EGTA to trigger the secretion of proteins. (To see the exact process of the induction, you can go to the Protocol.) We add 100% TCA to culture medium to reach a final concentration of approximately 10% which can precipitate the proteins form culture medium. But the final concentration of TCA may vary with the molecular weight of the precipitated protein but can't be too high, otherwise other substances will be precipitated.

First, we test which TCA concentration can better precipitate proteins from culture medium so we set the TCA concentration gradient of 10%, 15% to 20%. We randomly select one of P. aeruginosa which carries the antigen in theory to conduct the experiment.

The result is analyzed by western blot (Figure 1.1). As is shown in figure, 20% TCA concentration successfully precipitates the proteins. So we decide to use the 20% TCA concentration.

Figure 1.1 | As is shown in the figure, both 10% and 15% TCA concentration cannot precipitate the proteins from culture medium. Only the 20% TCA concentration can successfully precipitate the proteins.


According to the conclusion we made in the first experiment, we conduct EGTA induction experiment to test whether the engineered P. aeruginosa we constructed can produce and secret the antigens.

We set 6 test groups and a control group. Each test group contains engineered P. aeruginosa carrying the plasmids: pExoS54F-NY-ESO-A, pExoS54F-NY-ESO-B, pExoS54F-0201, pExoS54F-0301A, pExoS54F-0301B and pExoS54F-0301C. The culture medium of the control group is without the presence of EGTA and the rest of the conditions are consistent with the test groups.

The result is analyzed by western blot (Figure 1.2). Five antigens (NY-ESO-A, NY-ESO-B, 0201, 0301A and 0301C) are successfully secreted by bacteria.

Figure 1.2 | Five antigens (NY-ESO-A, NY-ESO-B, 0201, 0301A and 0301C) are successfully secreted by bacteria but no extinct signal was detected from 0301B.


There may be something wrong in our operation with pExoS54F-0301B plasmid, but we don’t have enough time to test. If we have more time, we will do this experiment again using pExoS54F-0201 plasmid as positive control to make sure the whole experiment operation is correct. At the same time, we will do colony PCR to check whether the pExoS54F-0301B plasmids are still in our engineered P. aeruginosa. If we can’t get positive result, we will repeat experiments from the pocedure of electroporation of P. aeruginosa. However, from the results below we can conclude that the bacteria contain these plasmids and our design is correct.

From another 5 plasmids, we can draw a conclusion that the bacteria can synthesize the antigens we want by the induction of EGTA.


2. Western Blot (Lysates of Infected Cells)

We conduct an experiment to analyze whether the host cell contact can trigger the production of the antigens and whether the engineered P. aeruginosa can inject these antigens into host cell cytosol in the level of protein.

We infect the HeLa cells with the engineered P. aeruginosa respectively carrying the plasmids: pExoS54F-NY-ESO-A, pExoS54F-NY-ESO-B, pExoS54F-0201, pExoS54F-0301A, pExoS54F-0301B and pExoS54F-0301C, then collect the lysates of HeLa cells. We analyze the cell lysates by western blot (Figure 2).

Figure 2 | Western Blot (Using the cell lysates samples)


The result shows that all of the six antigens can be detected in the western blot. The engineered P. aerugnosa carrying the plasmids: pExoS54F-NY-ESO-A, pExoS54F-NY-ESO-B, pExoS54F-0201, pExoS54F-0301A, pExoS54F-0301B and pExoS54F-0301C can be successfully induced to express and inject the peptides into the host cells.



3. Immunofluorescence of Infected Cells

In order to increase the persuasiveness of the experiments, we also use immunofluorescence technique to prove that bacteria injecte antigens into the cells. Immunofluorescence is a technique used for light microscopy with a fluorescence microscope and is used primarily on microbiological samples. This technique uses the specificity of antibodies to their antigen to target fluorescent dyes to specific biomolecule targets within a cell, and therefore allows visualization of the distribution of the target molecule through the sample.

We use anti-FLAG antibody to specifically target FLAG-tag, which is supposed to be in the cells. Then we use secondary antibody which carries the fluorophore to recognize the primary antibody and bind to it. And we also use DAPI to label DNA. (You can see more details in protocol.)

We use an epifluorescence microscope to confirm the presence of intracellular antigens and observe finer structures by confocal microscope.

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Figure 3.1 | Results of immunofluorescence pictured by epifluorescence microscope. Antigens are in green. The nuclei are stained blue by DAPI. Scar bar, 50 μm.


Figure 3.2 | Results of immunofluorescence pictured by confocal microscope. Antigens are in green. The nuclei are stained blue by DAPI. Scar bar, 100 μm.


We can see antigens several cells are injected into cells by T3SS. But the efficiency is not high, which is related to the relative amount of cells and bacteria. And what catches our attention is that we can find green antigens in the group of pExoS54F-0301B plasmid, which support this plasmid works.

So, we can confirm that, P. aeruginosa can inject antigens into cells in vitro.

4. Western Blot (Culture Supernatant of Infected Cells)

In order to prove the safety of our system, we conduct an experiment to test whether the culture supernatant of bacterially infected cells contains the antigens.

We collect the culture supernatant of bacterially infected cells and use the TCA-acetone precipitation to precipitate the secreted proteins which may be contained in the culture supernatant. To prove the experimental operation is correct, we set a positive control of cell lysates (These cells are infected by P. aeruginosa carrying pExoS54F-mCherry). Then we analyze the sediment by western blot to figure out the existence of the secreted proteins (Figure 4). As is shown in the figure, all of the culture supernatant of bacterially infected cells does not contain the proteins, which further proves that our system is safe enough.

Figure 4 | Six samples (left) of culture supernatant of bacterially infected cells which was infected respectively by the P. aeruginosa carrying the pExoS54F-NY-ESO-A, pExoS54F-NY-ESO-B, pExoS54F-0201, pExoS54F-0301A do not show extinct signature of existence of proteins. And the signal of positive control (Flag-mCherry) is successfully detected.


We can draw a conclusion that our system is safe enough and only inject the antigens into cell cytosol when attaching to the cell membrane.


5. Immunohistochemistry

Finally, using the animal model, the T3SS is further verified in vivo by immunohistochemistry. We give mice bacteria by oral gavage. After 4 hours, the mice are dissected, frozen sections of the mice intestine are taken for immunofluorescence experiment. In this way, we check whether the T3SS is effective in vivo. The pictures below are part of our results, and the design of this experiment accords with our animal check in form.

Figure 5 | The pictures are the immunohistochemistry of frozen selections of mice intestine with anti-FLAG antibody. The pictures above are all taken by the ZEISS Axio Imager 2. The time for FITC is 1000 ms while the time for DAPI is 29 ms.

According to the pictures above, compared to the negative control, two test groups with different kind of antigens both have some areas with higher intensity of green fluorescence. In these areas, we can find blue fluorescence inside which shows the nuclei and the peptides are secreted into the cytoplasm. From the pictures, we can conclude that it is not that efficient since there are only several positive cells in one visual field.

According to the articles before and the experiments done by other institutes, the efficiency should be higher. For we do not have enough time to revise the experimental conditions, we come up with several possible reasons for the low efficiency. Firstly, about the bacteria, there used to be bacteria saved in -80℃ which lost the plasmid. It is possible that this happened to us again. Secondly, the concentration of bacteria lavaged to the mice may be a little bit low. Thirdly, we do not add extra termination codon to the antigen so that there are several amino acids behind the antigen which may have influence on the efficiency. Also, for the background of the negative control is high, there may be something wrong with our sections or antibody.

In all, it is proved that this system works, though the efficiency is relatively low according to our results. With more conditions to be optimized and the design of experiments to be more precise, the results should be better. It is after all a promising system used in immunotherapy for cancer. And we will continue to work for it.

Reference

https://en.wikipedia.org/wiki/Immunofluorescence






Future plan



1 Optimizing Experiment Condition
Although we obtained many positive results during the experiment, there is still a certain distance from the result we expect. We analyzed our results and list many feasible directions to optimize our experiment condition. We are planning to conduct more experiments to figure out better experiment conditions.

2 Further Experimental Proof
In our lab experiment, we just do the early stage work to prove that our system works efficiently. There are lots of things we can do to further prove the feasibility of our system.

1. ELISA & ELISpot

Firstly, we plan to conduct ELISA and ELISpot using wild type mice to analyze whether our system can cause immune system response after at least one month engineered P. aeruginosa immunizing.

Enzyme-linked immunosorbent assay (abbreviated ELISA) refers to the qualitative and quantitative detection method of binding soluble antigen or antibody to a solid phase carrier, using antigen-antibody binding specificity for immune reaction. We will immunize the wild type mice by the engineered P. aeruginosa for at least one month and collect their serum to conduct the ELISA to analyze the IFN-γ level, which can reflect the extent of T cell activation.

Enzyme-linked immunoSpot assay (ELISpot) is a modified version of the ELISA immunoassay, allowing for the detection of cells that secrete cytokines or antibodies. Unlike ELISA, ELISpot is able to detect a single cell that secretes a protein of interest.

To conduct the ELISpot, we first need to place cytokine-specific antibodies onto an ELISpot plate, then the CD8+ T cells will be added. The activated T cells produce cytokine which binds to the antibodies. The cells are then removed whilst detection antibodies that can bind with the enzyme being added. Finally the substrate forms a colored spot on the T cells which secrete the antibody and the cells are then counted through a microscope. Through the ELISpot we can detect the percentage of activated T cells to evaluate the antigenic activity.

2. Tumor cell challenge experiment

If some positive signals can be detected, we will then do the tumor cell challenge experiment.

During the protection against tumor cell challenge, we will immunize the mice for at least two weeks and then challenge the immunized mice with tumor to see whether the immune system can protect the immunized mice from tumor.

Then, we will conduct experiment on tumor therapy model to test whether the activated immune system can kill the tumor cells. We can analyze the ability of the antigens by measuring the size of the tumor.