Difference between revisions of "Team:BNU-China/Demonstrate"

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   <p><b>Display module</b></p>
 
   <p><b>Display module</b></p>
 
     <h3>Plasmid construction</h3>
 
     <h3>Plasmid construction</h3>
         <p>We have accomplished the construction of 2 parts whose functions are described respectively in the previous design page. <a href="https://2017.igem.org/Team:BNU-China/Design#title2">(Microtubule module)</a> They are <a href="">(BBa_K2220019)</a> and pYD1-β tubulin <a href="">(BBa_K2220020)</a>, both parts have been validated by sequencing.The electrophoresis image of these two parts are shown as below (See Figure 1).<br>
+
         <p>We have accomplished the construction of two parts whose functions are described respectively in the previous design page <a href="https://2017.igem.org/Team:BNU-China/Design#title2">(Microtubule module)</a>. They are <a href="">(BBa_K2220019)</a> and pYD1-β tubulin <a href="">(BBa_K2220020)</a>, both parts have been validated by sequencing. The electrophoresis image of these two parts are shown as below (See Figure 1).<br>
         pYD1-β tubuiin was transfected into <i>S. cerevisiae</i> EBY100 by our team and validated its function by protein analysis, including Western blot and immunofluorescence microscopy(See Figure 2 and 3). Meanwhile, pYD1-α tubulin was transfected into <i>S.cerevisiae</i> EBY100 by FAFU-China, as part of collebration works.(<a href = "FAFU-China">Click </a>to see more details)</p>
+
         pYD1-β tubuiin was transfected into <i>S. cerevisiae</i> EBY100 by our team and validated its function by protein analysis, including Western blot and immunofluorescence microscopy(See Figure 2 and 3). Meanwhile, pYD1-α tubulin was transfected into <i>S.cerevisiae</i> EBY100 by FAFU-China, as part of collebration works.(<a href = "https://2017.igem.org/Team:FAFU-CHINA/Collaborations">Click </a>to see more details)</p>
  
 
   <img src="https://static.igem.org/mediawiki/2017/6/6f/T--BNU-China--results1.png" alt="Sorry, the image is not supported by your browser.">
 
   <img src="https://static.igem.org/mediawiki/2017/6/6f/T--BNU-China--results1.png" alt="Sorry, the image is not supported by your browser.">
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     <h3>Protein expression analysis- Western blot</h3>
 
     <h3>Protein expression analysis- Western blot</h3>
           <p>Recombinant <i>S.cerevisiae</i> EBY100 strain harboring the pYD1-β tubulin plasmid was precultivated to mid-log growth phase and then induced by galactose. After 24h inducing, the recombinant proteins are extracted and analysed by Western blot.The image shows the results of a Western blot analysis carried out with an anti-V5 antibody.</p>
+
           <p>Recombinant <i>S.cerevisiae</i> EBY100 strain harbouring the pYD1-β tubulin plasmid was precultivated to mid-log growth phase and then induced by galactose. After 24h inducing,the supernatent from cell lysate of engineered EBY100-pYD1-β was analysed by Western blot.The image shows the results of a Western blot analysis carried out with an anti-V5 antibody.</p>
 
<img src="https://static.igem.org/mediawiki/2017/9/9f/T-BNU-China-results4.png" alt="Sorry, the image is not supported by your browser.">
 
<img src="https://static.igem.org/mediawiki/2017/9/9f/T-BNU-China-results4.png" alt="Sorry, the image is not supported by your browser.">
 
       <h4>Figure 2 The partly results of a Western blot analysis carried out with an anti-V5 antibody.</h4>
 
       <h4>Figure 2 The partly results of a Western blot analysis carried out with an anti-V5 antibody.</h4>
  
     <h3>Function analysis- Immunoflruorescence microscopy</h3>
+
     <h3>Function analysis- Immunofluorescence microscopy</h3>
         <p>Recombinant <i>S. cerevisiae</i> EBY100 strain harboring the pYD1–β tubulin plasmid was precultivated to mid-log growth phase and then induced for 24 h at 20℃. During the inducing period, cells equaling to 2 OD<sub>600</sub> units were collected every two hours from 8 h to 24 h. To detect the displayed protein, immunofluorescence microscopy was performed, with mouse IgG against βI tubulin and donkey anti-mouse IgG conjugated with Cy3 as primary and second antibody respectively. Results showed that optimal detection of β-tubulin occurred at 12 h.  
+
         <p>Recombinant <i>S. cerevisiae</i> EBY100 strain harbouring the pYD1–β tubulin plasmid was precultivated to mid-log growth phase and then induced for 24 h at 20℃. During the inducing period, cells equaling to 2 OD<sub>600</sub> units were collected every two hours from 8 h to 24 h. To detect the displayed protein, immunofluorescence microscopy was performed, with mouse IgG against βI tubulin and donkey anti-mouse IgG conjugated with Cy3 as primary and second antibody respectively. Results showed that optimal detection of β-tubulin occurred at 12 h.  
 
         </p>
 
         </p>
 
   <img src="https://static.igem.org/mediawiki/2017/8/82/T--BNU-China--Results-1-beta.png" alt="Sorry, the image is not supported by your browser.">
 
   <img src="https://static.igem.org/mediawiki/2017/8/82/T--BNU-China--Results-1-beta.png" alt="Sorry, the image is not supported by your browser.">
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     <img src="https://static.igem.org/mediawiki/2017/5/53/T-BNU-China-malpha1.jpeg" alt="Sorry, the image is not supported by your browser." >
 
     <img src="https://static.igem.org/mediawiki/2017/5/53/T-BNU-China-malpha1.jpeg" alt="Sorry, the image is not supported by your browser." >
       <h4> Figure 4 An obvious color of mCherry produced by our engineered yeast harboring vector pYCα-mCherry-α . </h4>
+
       <h4> Figure 4 An obvious color of mCherry produced by our engineered yeast harbouring vector pYCα-mCherry-α . </h4>
  
 
       <p>Recombinant <i>S. cerevisiae</i> INVSc1 strain harboring pYCα-α tubulin, pYCα-β tubulin, pYCα-mCherry and pYCα-mCherry-α tubulin plasmid were precultivated to mid-log growth phase respectively and then induced for 48 h at 30℃. The recombinant proteins were extracted and analysed by Western blot. The image shows the results of a Western blot analysis carried out with an anti-V5 antibody.</p>
 
       <p>Recombinant <i>S. cerevisiae</i> INVSc1 strain harboring pYCα-α tubulin, pYCα-β tubulin, pYCα-mCherry and pYCα-mCherry-α tubulin plasmid were precultivated to mid-log growth phase respectively and then induced for 48 h at 30℃. The recombinant proteins were extracted and analysed by Western blot. The image shows the results of a Western blot analysis carried out with an anti-V5 antibody.</p>
 
     <img src="https://static.igem.org/mediawiki/2017/2/25/T-BNU-China-results3.png" alt="Sorry, the image is not supported by your browser." >
 
     <img src="https://static.igem.org/mediawiki/2017/2/25/T-BNU-China-results3.png" alt="Sorry, the image is not supported by your browser." >
       <h4>Figure 5 The results of a Western blot analysis carried out with an anti-V5 antibody.</h4>
+
       <h4>Figure 5 Western blot analysis of the supernatent from cell lysate of engineered yeasts mentioned above, carried out with an anti-V5 antibody.</h4>
 
     <p>Furthermore, it has been proven that our recombinant proteins can be secreted normally and worked as it expected. Firstly, the secretion function of part pYCα-mCherry have been proven by western blot analysis (See Figure 5). And then we test the dynamic behavior of our recombinant proteins mCherry-α tubulin and β tubulin, described in the following functional analysis.</p>
 
     <p>Furthermore, it has been proven that our recombinant proteins can be secreted normally and worked as it expected. Firstly, the secretion function of part pYCα-mCherry have been proven by western blot analysis (See Figure 5). And then we test the dynamic behavior of our recombinant proteins mCherry-α tubulin and β tubulin, described in the following functional analysis.</p>
  
 
     <img src="https://static.igem.org/mediawiki/2017/0/08/T--BNU-China--results-secretion1.png" alt= "Sorry, the image is not supported by your browser." >
 
     <img src="https://static.igem.org/mediawiki/2017/0/08/T--BNU-China--results-secretion1.png" alt= "Sorry, the image is not supported by your browser." >
       <h4> Figure 6 The partly results of a Western blot analysis carried out with an anti-V5 antibody.<br>
+
       <h4> Figure 6 The results of Western blot analysis carried out with an anti-V5 antibody.<br>
     A the purified supernatant of <i>S.cerevisiae</i> INVSc1 harboring pYCα-mCherry culture, induced for 12 hours in SG-Ura.<br>
+
     <i>Lane</i> A the purified supernatant of <i>S.cerevisiae</i> INVSc1 harboring pYCα-mCherry culture, induced for 12 hours in SG-Ura.<br>
     B the extracted proteins of <i>S.cerevisiae</i> INVSc1 harboring pYCα-mCherry culture(without purified), induced for 12 hours in SG-Ura.</h4>
+
     <i>Lane</i> B the supernatent from cell lysate of <i>S.cerevisiae</i> INVSc1 harboring pYCα-mCherry (without purified), induced for 12 hours in SG-Ura.</h4>
 
        
 
        
 
       <h3>Protein expression analysis- Fluorescence microscopy </h3>
 
       <h3>Protein expression analysis- Fluorescence microscopy </h3>
       <p>Recombinant <i>S. cerevisiae</i> INVSc1 strain harboring the pYCα–mCherry-α tubulin or pYCα–mCherry plasmid was precultivated to mid-log growth phase respectively and then induced for 48 h at 30℃. To detect the protein expression of our engineered yeast, fluorescence microscopy was performed. As image shown below, the expression rate of mCherry is almost up to 100%.</p>
+
     
 +
       <p>Recombinant <i>S. cerevisiae</i> INVSc1 strain harbouring the pYCα–mCherry-α tubulin or pYCα–mCherry plasmid was precultivated to mid-log growth phase respectively and then induced for 20 h at 30℃. To detect the protein expression of our engineered yeast, fluorescence microscopy was performed. As image shown below, the expression rate of mCherry is almost up to 100%.</p>
 
       <img src="https://static.igem.org/mediawiki/2017/1/19/T-BNU-China-results2.png" alt="Sorry, the image is not supported by your browser.">
 
       <img src="https://static.igem.org/mediawiki/2017/1/19/T-BNU-China-results2.png" alt="Sorry, the image is not supported by your browser.">
 
       <h4>Figure 7 Induced 20h in SG-Ura medium;<br>
 
       <h4>Figure 7 Induced 20h in SG-Ura medium;<br>
 
         A,B recipient strain with empty plasmid; <br>
 
         A,B recipient strain with empty plasmid; <br>
         C bright-field micrograph of S. cerevisiae INVSc1 cells harbouring pYCα–mCherry-α;<br>
+
         C bright-field micrograph of <i>S. cerevisiae</i> INVSc1 cells harbouring pYCα–mCherry-α;<br>
         D fluorescence micrograph of S. cerevisiae INVSc1 cells harbouring  pYCα–mCherry-α; <br>
+
         D fluorescence micrograph of <i>S. cerevisiae</i> INVSc1 cells harbouring  pYCα–mCherry-α; <br>
         E bright-field micrograph of S. cerevisiae INVSc1 cells harbouring pYCα–mCherry;<br>  
+
         E bright-field micrograph of <i>S. cerevisiae</i> INVSc1 cells harbouring pYCα–mCherry;<br>  
         F fluorescence micrograph of S. cerevisiae INVSc1 cells harbouring  pYCα–mCherry.<br></h4>
+
         F fluorescence micrograph of <i>S. cerevisiae</i> INVSc1 cells harbouring  pYCα–mCherry.<br></h4>
 
+
   
  <h3>Function analysis- Electron microscopy <span>&</span> OD<sub>340</sub> test</h3>
+
    <p>Recombinant <i>S. cerevisiae</i> INVSc1 strain harbouring pYCα–β tubulin-mGFP plasmid was precultivated to mid-log growth phase and then induced for 18 h at 30℃ in SG-Ura medium. The expression of recombinant protein can be obviously observed from fluorescence microscope field.</p>
 +
      <img src="https://static.igem.org/mediawiki/2017/8/84/T--BNU-China--2mgfp.png" alt="Sorry, the image is not supported by your browser.">
 +
      <h4>Figure 8 Induced 18h in SG-Ura medium;<br>
 +
          A,B recipient strain with empty plasmid; <br>
 +
        C bright-field micrograph of <i>S. cerevisiae</i> INVSc1 cells harbouring pYCα–β tubulin-mGFP;<br>
 +
        D fluorescence micrograph of <i>S. cerevisiae</i> INVSc1 cells harbouring  pYCα–β tubulin-mGFP.<br> </h4>
  
 +
        <p>From the images above, we can conclude that all of our parts can work as it expected, including display or secretion of recombinant proteins. Then, we test the function of our upgraded display system.</p>
  
 +
  <h3>Function analysis- OD<sub>340</sub> test <span>&</span> Electron microscopy</h3>
  
 +
    <p>Tubulin polymerization assay is based on an adaption of the original method of Shelanski et al.(1973) and Lee at al.(1977). Light at wavelength of 340 nm is scattered by microtubules proportionally to the concentration of polymerized microtubule. Purified α and β tubulins secreted by engineered <i>INVSc1</i> were mixed together and incubated at 37℃ for 1 h, and absorbance readings at 340 nm were conducted every minute. The results are shown in the image below.<br>
 +
   Comparing the absorbance curves obtained, it was clear that the secreted tubulins had successfully polymerized into microtubules when GTP is added into the system.</p>
 +
 +
    <h4>OD<sub>340</sub> </h4>
 +
 +
 +
        <img src="https://static.igem.org/mediawiki/2017/6/6b/T--BNU-China--Results-340.png" alt="Sorry, the image is not supported by your browser.">
 +
        <h4>Figure 9 Absorbance curve of polymerization reaction at 340 nm.</h4>
 +
        <h4>Figure 10</h4>
  
     
 
 
          
 
          
  
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     <h3>Plasmid construction</h3>  
 
     <h3>Plasmid construction</h3>  
 
             <p>We have successfully constructed the following 11 parts that have been described in detail in the previous design page. <a href="https://2017.igem.org/Team:BNU-China/Design#title3">(Flagellar filament module)</a><br>
 
             <p>We have successfully constructed the following 11 parts that have been described in detail in the previous design page. <a href="https://2017.igem.org/Team:BNU-China/Design#title3">(Flagellar filament module)</a><br>
In display module, we constructed and validated the following 6 parts. They are pYD1-FliC <a href="">(BBa_K2220002)</a>, pYD1-XynA<a href="">(BBa_K2220004)</a>, pYD1-PETase<a href="">(BBa_K2220005)</a>, pYD1-BG<a href="">(BBa_K2220007)</a>, pYD1-EG<a href="">(BBa_K2220006)</a>, pYD1-CBH<a href="">(BBa_K2220008)</a>, which means to fuse the target gene sequences with AGA2 gene respectively. And we also constructed pYD1-FilC(eGFP) <a href="">(BBa_K2220003)</a> as our positive control. The length and sequence of each parts have been validated by sequencing. The length validation are presented on the part registry page.
+
            In display module, we constructed and validated the following 6 parts. They are pYD1-FliC <a href="">(BBa_K2220002)</a>, pYD1-XynA<a href="">(BBa_K2220004)</a>, pYD1-PETase<a href="">(BBa_K2220005)</a>, pYD1-BG<a href="">(BBa_K2220007)</a>, pYD1-EG<a href="">(BBa_K2220006)</a>, pYD1-CBH<a href="">(BBa_K2220008)</a>, which means to fuse the target gene sequences with AGA2 gene respectively. And we also constructed pYD1-FilC(eGFP) <a href="">(BBa_K2220003)</a> as our positive control. The length and sequence of each parts have been validated by sequencing. The length validation are presented on the part registry page.
 
             </p>
 
             </p>
  
            <p>In secretory module,we successfully constructed the following parts: pYCα-FliC-XynA <a href="">(BBa_K2220011)</a>, pYCα-FliC-BG <a href="">(BBa_K2220014)</a>, pYCα-FliC-EG <a href="">(BBa_K2220013)</a>, pYCα-FliC-CBH <a href="">(BBa_K2220015)</a>, and pYCα-FliC-eGFP <a href="">(BBa_K2220003)</a> as positive control. The lengths and sequences of each part has been validated by sequencing. The length validations are presented on the part registry page.
+
      <h3>Protein expression analysis-Fluorescence Microscopy</h3>
            </p>
+
          <p>Recombinant <i>S. cerevisiae</i> EBY100 strain harbouring pYD1-FliC(eGFP) plasmid was precultivated to mid-log growth phase and then induced for 24 h at 20℃ in SG-CAA medium. The expression of recombinant protein FliC(eGFP) can be obviously observed from fluorescence microscope field. </p>
 +
      <img src="https://static.igem.org/mediawiki/parts/2/21/T-BNU-China-1egfp.png" alt="Sorry, the image is not supported by your browser.">
 +
      <h4>Induced for 24h in SG-CAA medium;<br>
 +
        A,B recipient strain with empty plasmid; <br>
 +
        C bright-field micrograph of <i>S. cerevisiae</i> INVSc1 cells harbouring pYD1–FliC(eGFP);<br>
 +
        D fluorescence micrograph of <i>S. cerevisiae</i> INVSc1 cells harbouring  pYD1–FliC(eGFP). <br></h4>
 +
   
 +
      <h3>Function analysis- Enzyme activity assay</h3>
 +
 
 +
 
 
    
 
    
 
     <p><b>Secretory module</b></p>
 
     <p><b>Secretory module</b></p>
 +
 +
    <p>In secretory module,we successfully constructed the following parts: pYCα-FliC-XynA <a href="">(BBa_K2220011)</a>, pYCα-FliC-BG <a href="">(BBa_K2220014)</a>, pYCα-FliC-EG <a href="">(BBa_K2220013)</a>, pYCα-FliC-CBH <a href="">(BBa_K2220015)</a>, and pYCα-FliC-eGFP <a href="">(BBa_K2220003)</a> as positive control. The lengths and sequences of each part has been validated by sequencing. The length validations are presented on the part registry page.</p>
 +
 
   <h3>Protein expression analysis- Western blot</h3>
 
   <h3>Protein expression analysis- Western blot</h3>
 
     <img src="https://static.igem.org/mediawiki/2017/f/fb/T-BNU-China-results6new.png" alt="Sorry, the image is not supported by your browser.">
 
     <img src="https://static.igem.org/mediawiki/2017/f/fb/T-BNU-China-results6new.png" alt="Sorry, the image is not supported by your browser.">
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     <h3>Protein expression analysis- Western blot</h3>
 
     <h3>Protein expression analysis- Western blot</h3>
<img src="https://static.igem.org/mediawiki/parts/2/21/T-BNU-China-1egfp.png" alt="Sorry, the image is not supported by your browser.">
+
 
  
 
         <p>The image shows the results of a Western blot analysis carried out with an anti-His antibody. The recombinant proteins are expressed by S.cerevisiae INVSC1 pYCα-FilC(PETase) and pYCα-FliC(XynA) respectively. After 24h inducing,the recombinant proteins are extracted and analysed by Western blot
 
         <p>The image shows the results of a Western blot analysis carried out with an anti-His antibody. The recombinant proteins are expressed by S.cerevisiae INVSC1 pYCα-FilC(PETase) and pYCα-FliC(XynA) respectively. After 24h inducing,the recombinant proteins are extracted and analysed by Western blot
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<img src="https://static.igem.org/mediawiki/2017/7/76/T-BNU-China-2egfp.png" alt="Sorry, the image is not supported by your browser.">
 
<img src="https://static.igem.org/mediawiki/2017/7/76/T-BNU-China-2egfp.png" alt="Sorry, the image is not supported by your browser.">
  
<img src="https://static.igem.org/mediawiki/2017/5/59/T--BNU-China--1X.png" alt="Sorry, the image is not supported by your browser.">
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<img src="https://static.igem.org/mediawiki/2017/0/0d/T--BNU-China--Results-mjt.png" alt="Sorry, the image is not supported by your browser.">
<img src="https://static.igem.org/mediawiki/2017/8/8c/T--BNU-China--2beta-mGFP.png" alt="Sorry, the image is not supported by your browser.">
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<h4>木聚糖</h4>
 +
 
 
<img src="https://static.igem.org/mediawiki/2017/4/44/T--BNU-China--sq.jpg " alt="Sorry, the image is not supported by your browser.">
 
<img src="https://static.igem.org/mediawiki/2017/4/44/T--BNU-China--sq.jpg " alt="Sorry, the image is not supported by your browser.">
  

Revision as of 17:05, 1 November 2017

BNU-China ">

Results

Microtubule

Display module

Plasmid construction

We have accomplished the construction of two parts whose functions are described respectively in the previous design page (Microtubule module). They are (BBa_K2220019) and pYD1-β tubulin (BBa_K2220020), both parts have been validated by sequencing. The electrophoresis image of these two parts are shown as below (See Figure 1).
pYD1-β tubuiin was transfected into S. cerevisiae EBY100 by our team and validated its function by protein analysis, including Western blot and immunofluorescence microscopy(See Figure 2 and 3). Meanwhile, pYD1-α tubulin was transfected into S.cerevisiae EBY100 by FAFU-China, as part of collebration works.(Click to see more details)

Sorry, the image is not supported by your browser.

Figure 1 The electrophoresis image of 6 plasmids.

Protein expression analysis- Western blot

Recombinant S.cerevisiae EBY100 strain harbouring the pYD1-β tubulin plasmid was precultivated to mid-log growth phase and then induced by galactose. After 24h inducing,the supernatent from cell lysate of engineered EBY100-pYD1-β was analysed by Western blot.The image shows the results of a Western blot analysis carried out with an anti-V5 antibody.

Sorry, the image is not supported by your browser.

Figure 2 The partly results of a Western blot analysis carried out with an anti-V5 antibody.

Function analysis- Immunofluorescence microscopy

Recombinant S. cerevisiae EBY100 strain harbouring the pYD1–β tubulin plasmid was precultivated to mid-log growth phase and then induced for 24 h at 20℃. During the inducing period, cells equaling to 2 OD600 units were collected every two hours from 8 h to 24 h. To detect the displayed protein, immunofluorescence microscopy was performed, with mouse IgG against βI tubulin and donkey anti-mouse IgG conjugated with Cy3 as primary and second antibody respectively. Results showed that optimal detection of β-tubulin occurred at 12 h.

Sorry, the image is not supported by your browser.

Figure 3 Induced 12h in SG-CAA medium;
A,B recipient strain with empty plasmid;
C bright-field micrograph of S. cerevisiae EBY100 cells harbouring pYD1–β tubulin;
D immunofluorescence micrograph of S. cerevisiae EBY100 cells harbouring pYD1–β tubulin.

Secretory module

Plasmid construction

Four parts have been constructed, which are pYCα-α tubulin (BBa_K2220022), pYCα-β tubulin (BBa_K2220023), pYCα-mCherry-α tubulin (BBa_K2220024), pYCα-β-tubulin-mGFP (BBa_K2220025) and pYCα-mCherry (BBa_K2220021). All parts have been validated by sequencing.(See Figure 1)

Protein expression analysis- Western blot

Sorry, the image is not supported by your browser.

Figure 4 An obvious color of mCherry produced by our engineered yeast harbouring vector pYCα-mCherry-α .

Recombinant S. cerevisiae INVSc1 strain harboring pYCα-α tubulin, pYCα-β tubulin, pYCα-mCherry and pYCα-mCherry-α tubulin plasmid were precultivated to mid-log growth phase respectively and then induced for 48 h at 30℃. The recombinant proteins were extracted and analysed by Western blot. The image shows the results of a Western blot analysis carried out with an anti-V5 antibody.

Sorry, the image is not supported by your browser.

Figure 5 Western blot analysis of the supernatent from cell lysate of engineered yeasts mentioned above, carried out with an anti-V5 antibody.

Furthermore, it has been proven that our recombinant proteins can be secreted normally and worked as it expected. Firstly, the secretion function of part pYCα-mCherry have been proven by western blot analysis (See Figure 5). And then we test the dynamic behavior of our recombinant proteins mCherry-α tubulin and β tubulin, described in the following functional analysis.

Sorry, the image is not supported by your browser.

Figure 6 The results of Western blot analysis carried out with an anti-V5 antibody.
Lane A the purified supernatant of S.cerevisiae INVSc1 harboring pYCα-mCherry culture, induced for 12 hours in SG-Ura.
Lane B the supernatent from cell lysate of S.cerevisiae INVSc1 harboring pYCα-mCherry (without purified), induced for 12 hours in SG-Ura.

Protein expression analysis- Fluorescence microscopy

Recombinant S. cerevisiae INVSc1 strain harbouring the pYCα–mCherry-α tubulin or pYCα–mCherry plasmid was precultivated to mid-log growth phase respectively and then induced for 20 h at 30℃. To detect the protein expression of our engineered yeast, fluorescence microscopy was performed. As image shown below, the expression rate of mCherry is almost up to 100%.

Sorry, the image is not supported by your browser.

Figure 7 Induced 20h in SG-Ura medium;
A,B recipient strain with empty plasmid;
C bright-field micrograph of S. cerevisiae INVSc1 cells harbouring pYCα–mCherry-α;
D fluorescence micrograph of S. cerevisiae INVSc1 cells harbouring pYCα–mCherry-α;
E bright-field micrograph of S. cerevisiae INVSc1 cells harbouring pYCα–mCherry;
F fluorescence micrograph of S. cerevisiae INVSc1 cells harbouring pYCα–mCherry.

Recombinant S. cerevisiae INVSc1 strain harbouring pYCα–β tubulin-mGFP plasmid was precultivated to mid-log growth phase and then induced for 18 h at 30℃ in SG-Ura medium. The expression of recombinant protein can be obviously observed from fluorescence microscope field.

Sorry, the image is not supported by your browser.

Figure 8 Induced 18h in SG-Ura medium;
A,B recipient strain with empty plasmid;
C bright-field micrograph of S. cerevisiae INVSc1 cells harbouring pYCα–β tubulin-mGFP;
D fluorescence micrograph of S. cerevisiae INVSc1 cells harbouring pYCα–β tubulin-mGFP.

From the images above, we can conclude that all of our parts can work as it expected, including display or secretion of recombinant proteins. Then, we test the function of our upgraded display system.

Function analysis- OD340 test & Electron microscopy

Tubulin polymerization assay is based on an adaption of the original method of Shelanski et al.(1973) and Lee at al.(1977). Light at wavelength of 340 nm is scattered by microtubules proportionally to the concentration of polymerized microtubule. Purified α and β tubulins secreted by engineered INVSc1 were mixed together and incubated at 37℃ for 1 h, and absorbance readings at 340 nm were conducted every minute. The results are shown in the image below.
  Comparing the absorbance curves obtained, it was clear that the secreted tubulins had successfully polymerized into microtubules when GTP is added into the system.

OD340

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Figure 9 Absorbance curve of polymerization reaction at 340 nm.

Figure 10

意义-讨论

Flagellar Filament

Display module

Plasmid construction

We have successfully constructed the following 11 parts that have been described in detail in the previous design page. (Flagellar filament module)
In display module, we constructed and validated the following 6 parts. They are pYD1-FliC (BBa_K2220002), pYD1-XynA(BBa_K2220004), pYD1-PETase(BBa_K2220005), pYD1-BG(BBa_K2220007), pYD1-EG(BBa_K2220006), pYD1-CBH(BBa_K2220008), which means to fuse the target gene sequences with AGA2 gene respectively. And we also constructed pYD1-FilC(eGFP) (BBa_K2220003) as our positive control. The length and sequence of each parts have been validated by sequencing. The length validation are presented on the part registry page.

Protein expression analysis-Fluorescence Microscopy

Recombinant S. cerevisiae EBY100 strain harbouring pYD1-FliC(eGFP) plasmid was precultivated to mid-log growth phase and then induced for 24 h at 20℃ in SG-CAA medium. The expression of recombinant protein FliC(eGFP) can be obviously observed from fluorescence microscope field.

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Induced for 24h in SG-CAA medium;
A,B recipient strain with empty plasmid;
C bright-field micrograph of S. cerevisiae INVSc1 cells harbouring pYD1–FliC(eGFP);
D fluorescence micrograph of S. cerevisiae INVSc1 cells harbouring pYD1–FliC(eGFP).

Function analysis- Enzyme activity assay

Secretory module

In secretory module,we successfully constructed the following parts: pYCα-FliC-XynA (BBa_K2220011), pYCα-FliC-BG (BBa_K2220014), pYCα-FliC-EG (BBa_K2220013), pYCα-FliC-CBH (BBa_K2220015), and pYCα-FliC-eGFP (BBa_K2220003) as positive control. The lengths and sequences of each part has been validated by sequencing. The length validations are presented on the part registry page.

Protein expression analysis- Western blot

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figure 7 The results of a Western blot analysis carried out with an anti-His antibody

Protein expression analysis- Western blot

The image shows the results of a Western blot analysis carried out with an anti-His antibody. The recombinant proteins are expressed by S.cerevisiae INVSC1 pYCα-FilC(PETase) and pYCα-FliC(XynA) respectively. After 24h inducing,the recombinant proteins are extracted and analysed by Western blot

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木聚糖

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