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

Latest revision as of 22:22, 6 December 2019

JiangNan

Project Demonstrate

Throughout the project, we screened two inducible promoters, mutated to obtain four phage resistance parts, and found a phage resistance part from the literature, all of which were derived from E. coli BL21. We used reporter genes to detect the effectiveness of inducible promoters, and overexpression of resistance proteins to verify the effect of proteins on cell growth. We assembled the resistance parts and promoters to obtain a strong strain that is immune to T4 phage.

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1. Inducible Promoters P_putA and P_glcF Can Respond to T4 Phage Infection

We obtained phage-inducible promoters P_putA and P_glcF by transcriptomics data, ligated these two different time-responsive inducible promoters to the fluorescent genes gfp and mCherry, respectively, and transformed them into E. coli BL21. The two strains BL21-P_putA-gfp and BL21-P_glcF-mCherry were cultured overnight at 37 ° C for about 12-16 hours, then transferred to fresh LB medium at 1%, cultured for about 2 hours. After that added 1% freshly centrifuged T4 phage solution, and shaken at 37 ° C for 30 min. Then take the 10 μL to make tablets, and fluorescence observation was performed by a laser confocal microscope. At the same time, we set up a mutant strain without phage as a control.

From the results, we can find that the strains E. coli BL21-P_putA-gfp and E. coli BL21-P_glcF-mCherry without phage showed no signs of fluorescence. The two bacteria infected with phage showed obvious fluorescence. But overall, the number of bacteria that show fluorescence was not that much, because not every bacterium was infected with T4 phage. This indicated that the promoters we selected is silent in the absence of phage infestation and does not affect the expression of subsequent proteins.

2. The Effectiveness of T4 Phage Resistance Proteins

We found a resistance protein, AbpAB, from the literature, and found that the protein only reduced phage sensitivity. To obtain a strain that is fully immunized against the T4 phage, we mutated and sequenced E. coli BL21 to obtain four key anti-phage-related genes gntR, rzpD, yhjH, nuoE.

According to the advice of corporate stakeholders, if the Genetic Modified (GM) strain is to be applied in industry, our components cannot have a great influence on bacterial growth. Since it is not possible to directly see from the figure which element has the least influence on the growth of the bacteria, we use the Grey Relation Analysis（GRA） method to analyze the growth curve of the bacteria connecting the various components. We used the Entropy Weight Method (EWM) method to determine the weight of each growth point to select the most similarly modified strain (the highest correlation), which is the component that has the least impact on bacterial growth. At the same time, after consulting the industry experts, we revised the weights according to the experts' recommendations to evaluate the components again, making them more in line with the real situation of production, that is, the most suitable components for industrial production. Using GRA's two evaluations of the four components at different weights, we selected the component gntR to cascade abpAB to construct a stronger resistant strain for better industrial performance.

Overexpression of these four genes, further experimental results show that gntR has the best anti-phage effect. The experimental results are also consistent with the model prediction, and gntR has better anti-phage effect. Gene gntR is related to GntR family transcriptional regulator and galactonate operon transcriptional repressor. The specific mechanism is still unclear, and this remains to be explored. But according to the literature, AbpAB can impair the synthesis of late gene transcripts, which resulted in poor expression of late proteins and consequently no phage propagation, and impair the synthesis of the phage DNA. Also, AbpAB have no effect on the bacterial growth. As for the GntR, we believe that it affects the normal infection of phage by regulating cellular metabolism.

We connect gntR with abpAB on pET28a, and transformed them into E. coli BL21. We co-expressed abpAB and gntR, and subsequently obtained a recombinant strain that is immune to phage.

3. Constitutive Expression of Resistance Proteins

In the case of determining that the combination resistance protein is effective, we choose the constitutive promoter P_rsmH to constitutively express the resistance protein in an attempt to verify whether the resistance protein has an effect on cell growth. First we linked this constitutive promoter to gfp, demonstrating the validity of this constitutive promoter. The effect of overexpression of the resistance protein AbpAB on growth was then verified. The results showed that P_rsmH had a good effect, and overexpression of AbpAB had no significant effect on the growth of E. coli BL21.

4. The Effectiveness of The Overall Gene Circuit

We ligated the combined resistance protein gene and the kill switch P-1 after the latent phage-inducible promoter and the burst-inducible promoter, and performed the phage infection assay on the LB agar plate, and got very good resistance.

In addition, we inoculated E. coli BL21and recombinant E. coli BL21-pET28a-P_putA-abpAB-gntR-P_glcF-P-1 in LB liquid medium to raise the logarithmic growth phase, i.e. OD 0.6-0.8 . Then the fresh phage solution was inoculated at the same time and culture was continued for 1-2 h. As a result, it was found that the recombinant grew well.

5. Application of Phage Resistant Strain in Fermentation Growth

We cooperated with NINGXIA EPPEN BIOTECH CO.,LTD to carry out small-scale and pilot test fermentation experiments of resistant strain in the special fermentation laboratory of Jiangnan University. This ensures that our experiments are controllable without any phage and engineered bacteria leaking.
We transferred the constructed plasmid into a production strain producing γ-aminobutyric acid (GABA).
The fermentation laboratory is subjected to UV irradiation and ozone fumigation prior to formal fermentation to remove phage that may be present. TheE. coli BL21-pET28a-P_putA-abpAB-gntR-P_glcF-P-1, E. coli BL21-pET28a-P_putA-abpAB and the control (E. coli BL21) were added to 1% T4 phage about 6 hours after inoculation, and the fermentation was continued for 10 hours. During the fermentation, the OD600 was measured, and the effects of the phage on the three were observed.

Then we used whole-cell transformation with a combination of resistant strain E. coli BL21-pET28a-P_putA-abpAB-gntR-P_glcF-P-1 and we got a good whole-cell transformation ability of the resistant strain (Figure 13).

From the results, our resistant composite part has great advantages in the production of γ-aminobutyric acid and are not threatened by T4 phage. The productivity of γ-aminobutyric acid is 278.3 g/L, and the molar conversion rate is really high, reaching 98.4%, which means that the circuit we built can be used in production without any impact (Table 1).

6. Models for Future Work

The phage-induced promoters are vital in our genetic circuit, which would response the phage stimulation and start transcription of ant-P and P-1 (antimicrobial peptide) against the phage infection. And the phage-induced promoters we used were selected from E. coli BL21, so there might be some potential problems such as leakage and inclusion body due to the inappropriate promoter strength. Thus we developed a quantitative design method for phage -induced promotors based on strength prediction using Artificial Neural Network (ANN). The model allows us to choose or design promotors with desired strength without extra experiments.

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                  <br/>
                  <div class="fm_22">
-                     Throughout the project, we screened two inducible promoters, mutated to obtain six phage resistance
+                     Throughout the project, we screened two inducible promoters, mutated to obtain four phage resistance
                      parts, and found a phage resistance part from the literature, all of which were derived from <i>E.
                      coli</i>
@@ Line 154: / Line 154: @@
                      parts and promoters to obtain a strong strain that is immune to T4 phage.
                  </div>
+                <br/>                <br/> <br/> <br/> <br/> <br/>                <br/>
                  <div class="split"></div>
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          <div class="centers">
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-                 <b>Inducible Promoters P<sub><i>putA</i></sub> and P<sub><i>glcF</i></sub> Can Respond toT4 Phage
+                 <b>1. Inducible Promoters P<sub><i>putA</i></sub> and P<sub><i>glcF</i></sub> Can Respond to T4 Phage
                      Infection</b>
              </div>
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                  transcriptomics data, ligated
                  these two
-                 different time-responsive inducible promoters to the fluorescent genes <i>gfp</i> and <i>mcherry</i>,
+                 different time-responsive inducible promoters to the fluorescent genes <i>gfp</i> and <i>mCherry</i>,
                  respectively,
                  and transformed them into <i>E. coli</i> BL21. The two strains BL21-P<sub><i>putA</i></sub>-gfp and
-                 BL21-P<i><sub>glcF</sub>-mcherry</i>
+                 BL21-P<i><sub>glcF</sub>-mCherry</i>
                  were
                  cultured overnight at 37 ° C for about 12-16 hours, then transferred to fresh LB medium at 1%, cultured
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              <div class="fm_22">
                  From the results, we can find that the strains <i>E. coli</i> BL21-P<i><sub>putA</sub>-gfp</i> and
-                 <i>E. coli</i> BL21-P<i><sub>glcF</sub>-mcherry</i>
+                 <i>E. coli</i> BL21-P<i><sub>glcF</sub>-mCherry</i>
                  without phage showed
                  no signs of fluorescence. The two bacteria infected with phage showed obvious fluorescence. But overall,
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              <img src="https://static.igem.org/mediawiki/2019/6/67/T--JiangnanU_China--project_demonstrate_1_%282%29.png"
-                  alt="Phage-infection" style="width: 100%;height: auto">
+                  alt="Phage-infection" style="width: 80%;height: auto;align:center"></div>
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+            <div align="center">
              <img src="https://static.igem.org/mediawiki/2019/1/1f/T--JiangnanU_China--project_demonstrate_9.png"
-                  alt="Phage-infection" style="width: 100%;height: auto">
+                  alt="Phage-infection" style="width: 80%;height: auto;align:center">
+            </div>
              <!--第二部分-->
              <div class="split"></div>
              <div class="blue_shadow">
-                 <div class="fb_72"><b>2.The Effectiveness of T4 Phage Resistance Proteins</b></div>
+                 <div class="fb_48"><b>2. The Effectiveness of T4 Phage Resistance Proteins</b></div>
                  <br/>
                  <div class="fm_22">
@@ Line 226: / Line 229: @@
                      sequenced <i>E. coli</i> BL21 to obtain four key anti-phage-related genes <i>gntR, rzpD, yhjH,
                      nuoE</i>.
-                     <br/>
+                     <br/><br/>
                      According to the advice of corporate stakeholders, if the Genetic Modified (GM) strain is to be
                      applied in industry, our components cannot have a great influence on bacterial growth. Since it is
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-                 style="width: 100%;height: auto">
-            <div class="split_small"></div>
+<br/>
+            <div class="row" style="padding=2%">
+                <img src="https://static.igem.org/mediawiki/2019/1/15/T--JiangnanU_China--4phage.png"
+                     style="width: 50%;height: 420px;">
+                <img src="https://static.igem.org/mediawiki/2019/c/c0/T--JiangnanU_China--anti-phage-data2.png"
+                     style="width: 40%;height: 350px;">
+            </div>
+<br/><br/><br/>
              <div class="fm_22">
                  We connect <i>gntR</i> with <i>abpAB</i> on pET28a, and transformed them into <i>E. coli</i> BL21. We
@@ Line 279: / Line 293: @@
                  <i>gntR</i>, and subsequently obtained a recombinant strain that is immune to phage.
              </div>
+<br/><br/><br/>
             <div class="split_small"></div>
+           <div align="center">
              <img src="https://static.igem.org/mediawiki/2019/5/5c/T--JiangnanU_China--project_demonstrate_4%282%29.png"
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              <div class="blue_shadow">
-                 <div class="fb_72"><b>3.Constitutive Expression of Resistance Proteins</b></div>
+                 <div class="fb_48"><b>3. Constitutive Expression of Resistance Proteins</b></div>
                  <br/>
                  <div class="fm_22">
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+            <div align="center">
              <img src="https://static.igem.org/mediawiki/2019/3/3b/T--JiangnanU_China--project_demonstrate_12.png"
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+                  style="width: 80%;height: auto;align:center">
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              <!--第四部分-->
              <div class="split"></div>
-             <div class="fb_72"><b>4. The Effectiveness of The Overall Gene Circuit</b></div>
+             <div class="fb_48"><b>4. The Effectiveness of The Overall Gene Circuit</b></div>
              <br/>
              <div class="fm_22">
-                 We ligated the combined resistance protein gene and the kill switch P-1 (P-1 part链接)after the latent
+                 We ligated the combined resistance protein gene and the kill switch <a href="http://parts.igem.org/Part:BBa_K628000" style="color:red;"alt="">P-1</a> after the latent
                  phage-inducible promoter and the burst-inducible promoter, and performed the phage infection assay
                  on
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+            <div align="center">
              <img src="https://static.igem.org/mediawiki/2019/6/69/T--JiangnanU_China--project_demonstrate_7_%282%29.png"
-                  style="width: 80%;height: auto">
+                  style="width: 90%;height: auto;align:center">
+                 </div>
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              <div class="fm_22">
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              </div>
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+            <div align="center">
              <img src="https://static.igem.org/mediawiki/2019/3/3f/T--JiangnanU_China--project_demonstrate_14.png"
-                  style="width: 80%;height: auto">
+                  style="width: 70%;height: auto;align:center"></div>
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              <div class="split"></div>
              <div class="blue_shadow">
-                 <div class="fb_72"><b>5.Application of Phage Resistant Strain in Fermentation Growth</b></div>
+                 <div class="fb_48"><b>5. Application of Phage Resistant Strain in Fermentation Growth</b></div>
                  <br/>
                  <div class="fm_22">
-                     We cooperated with <a href="http://nxyp.xafangao.com" style="color:red;"alt="">NINGXIA EPPEN BIOTECH CO.,LTD</a>
+                     We cooperated with <a href="http://nxyp.xafangao.com" style="color:#ff8c00;"alt="">NINGXIA EPPEN BIOTECH CO.,LTD</a>
                       to carry out small-scale
                      and pilot test fermentation experiments of resistant strain in the special fermentation laboratory
@@ Line 370: / Line 393: @@
                      fermentation to remove phage that may be present. The<i>E. coli</i>
                      BL21-pET28a-P<i><sub>putA</sub>-abpAB-gntR</i>-P<i><sub>glcF</sub>-P-1, E. coli</i> BL21-pET28a-P<i><sub>putA</sub>-abpAB</i>
-                     and the control (E. coli
+                     and the control (<i>E. coli</i>
                      BL21) were added to 1% T4 phage about 6 hours after inoculation, and the fermentation was continued
                      for 10 hours. During the fermentation, the OD600 was measured, and the effects of the phage on the
                      three were observed.
-                     <br/>
+                     <br/><br/>
                      Then we used whole-cell transformation with a combination of resistant strain <i>E. coli</i>
                      BL21-pET28a-P<i><sub>putA</sub>-abpAB-gntR</i>-P<i><sub>glcF</sub>-P-1</i> and we got a good
                      whole-cell transformation ability of the
-                     resistant strain (Figure 12).
+                     resistant strain (Figure 13).
-                     <br/>
+                     <br/><br/>
                      From the results, our resistant composite part has great advantages in the production of
                      γ-aminobutyric acid and are not threatened by T4 phage. The productivity of γ-aminobutyric acid is
 .3 g/L, and the molar conversion rate is really high, reaching 98.4%, which means that the
-                     circuit we built can be used in production without any impact (Figure 13).
+                     circuit we built can be used in production without any impact (Table 1).
                  </div>
              </div>
              <div class="split_small"></div>
+            <div align="center">
              <img src="https://static.igem.org/mediawiki/2019/f/fd/T--JiangnanU_China--project_demonstrate_15.png"
-                  style="width: 100%;height: auto">
+                  style="width: 70%;height: auto;align:center">
+                 </div>
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-             <img src="https://static.igem.org/mediawiki/2019/3/30/T--JiangnanU_China--project_demonstrate_16.png"
+            <div align="center">
-                  style="width: 100%;height: auto">
+             <img src="https://static.igem.org/mediawiki/2019/thumb/8/83/T--JiangnanU_China--fajiao.png/1200px-T--JiangnanU_China--fajiao.png"
+                  style="width: 80%;height: auto;align:center"></div>
+            <div class="split_small"></div>
+            <div align="center">
+            <img src="https://static.igem.org/mediawiki/2019/4/47/T--JiangnanU_China--guan.png"
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              <!--            第六部分-->
              <div class="split"></div>
-             <div class="fb_72"><b>6.Models for Future Work</b></div>
+             <div class="fb_48"><b>6. Models for Future Work</b></div>
              <br/>
              <div class="fm_22">
@@ Line 410: / Line 441: @@
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              <img src="https://static.igem.org/mediawiki/2019/8/88/T--JiangnanU_China--project_demonstrate_17.png"
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