Line 209: | Line 209: | ||
<div class="note-content"> | <div class="note-content"> | ||
<h2>Wet Lab</h2> | <h2>Wet Lab</h2> | ||
− | <p>In microtubule part, we intended to construct 8 vectors, they are pYD1- | + | <p>In microtubule part, we intended to construct 8 vectors, they are pYD1-α-tubulin、pYD1-β-tubulin、pYCα-α-tubulin、pYD1-mCherry(positive control)、pYCα-β-tubulin、pYCα- mCherry-α-tubulin、pYCα-β-tubulin-mGFP、pYCα-mCherry(positive control).</p> |
<p>Searched DNA sequences (flic、PETase、XynA、BG、EG、CBH)</p> | <p>Searched DNA sequences (flic、PETase、XynA、BG、EG、CBH)</p> | ||
<h2>Dry Lab</h2> | <h2>Dry Lab</h2> | ||
Line 239: | Line 239: | ||
<div class="note-content"> | <div class="note-content"> | ||
<h2>Wet Lab</h2> | <h2>Wet Lab</h2> | ||
− | <p>As sequencing results show, we had successfully constructed pYD1-α and pYD1-mCherry. We continued constructing the rest plasmids ( pYD1- | + | <p>As sequencing results show, we had successfully constructed pYD1-α and pYD1-mCherry. We continued constructing the rest plasmids ( pYD1-β-tubulin、pYCα-α-tubulin、pYCα-β-tubulin、pYCα- mCherry-α-tubulin、pYCα-β-tubulin-mGFP、pYCα-mCherry).</p> |
<h2>Dry Lab</h2> | <h2>Dry Lab</h2> | ||
<p>We learned as many as possible modeling which maybe useful for our work.</p> | <p>We learned as many as possible modeling which maybe useful for our work.</p> | ||
Line 258: | Line 258: | ||
<div class="note-content"> | <div class="note-content"> | ||
<h2>Wet Lab</h2> | <h2>Wet Lab</h2> | ||
− | <p>We successfully constructed recombined plasmids(pYCα- | + | <p>We successfully constructed recombined plasmids(pYCα-α-tubulin、pYCα-β-tubulin、pYCα- mCherry-α-tubulin、pYCα-mCherry). We constructed pYD1-β once again.</p> |
<p>Continued transforming recombined plasmids in Saccharomyces cerevisiae (EBY100 & invsc1) competent cells using chemical transforming method.</p> | <p>Continued transforming recombined plasmids in Saccharomyces cerevisiae (EBY100 & invsc1) competent cells using chemical transforming method.</p> | ||
<h2>Dry Lab</h2> | <h2>Dry Lab</h2> | ||
Line 280: | Line 280: | ||
<p>pYD1-β was constructed successfully.</p> | <p>pYD1-β was constructed successfully.</p> | ||
<p>Plasmids were digested by enzymes, and we had a gel electrophoresis to prove true.</p> | <p>Plasmids were digested by enzymes, and we had a gel electrophoresis to prove true.</p> | ||
− | <p>To get recombined plasmids(pYCα- | + | <p>To get recombined plasmids(pYCα-FliC(PETase)、pYCα-FliC(XynA)、pYCα-FliC(BG)、pYCα-FliC(EG)、pYCα-FliC(CBH)) containing corresponding enzyme, we fused flic-N respectively with five enzymes(PETase、XynA、BG、EG、CBH) through PCR to get a part of target gene. Then we infused the part of target gene with flic-C and plasmids digested by enzymes. These plasmids could express secretory proteins. Screened strains on LB plate (added Ampicillin). Sent sequencing.</p> |
− | <p>Recombined plasmid pYD1-flic-Mgfp was constructed in the same way with pYCα- | + | <p>Recombined plasmid pYD1-flic-Mgfp was constructed in the same way with pYCα-FliC(PETase)、pYCα-FliC(XynA)、pYCα-FliC(BG)、pYCα-FliC(EG)、pYCα-FliC(CBH).</p> |
<p>We tried electronic transformation way to transform plasmids into yeast competent cells due to the fact that we always failed in chemical transformation way.</p> | <p>We tried electronic transformation way to transform plasmids into yeast competent cells due to the fact that we always failed in chemical transformation way.</p> | ||
<h2>Dry Lab</h2> | <h2>Dry Lab</h2> | ||
Line 291: | Line 291: | ||
<div class="note-content"> | <div class="note-content"> | ||
<h2>Wet Lab</h2> | <h2>Wet Lab</h2> | ||
− | <p>Sent recombined plasmids including | + | <p>Sent recombined plasmids including pYDF-eGFP、pYCα-FliC(PETase)、pYCα-FliC(XynA)、pYCα-FliC(BG)、pYCα-FliC(EG) and pYCα-FliC(CBH) sequencing.</p> |
<p>We succeeded in electronic transformation way, transforming pYD1-mCherry into yeast competent cells and screening on SD plate (added Leu). </p> | <p>We succeeded in electronic transformation way, transforming pYD1-mCherry into yeast competent cells and screening on SD plate (added Leu). </p> | ||
<h2>Dry Lab</h2> | <h2>Dry Lab</h2> | ||
Line 302: | Line 302: | ||
<h2>Wet Lab</h2> | <h2>Wet Lab</h2> | ||
<p>We transformed pYD1-mCherry into yeast competent cells EBY100 in electronic transformation way and screened on SD plate (added Leu), expanding culture.</p> | <p>We transformed pYD1-mCherry into yeast competent cells EBY100 in electronic transformation way and screened on SD plate (added Leu), expanding culture.</p> | ||
− | <p>Plasmids ( pYCα- | + | <p>Plasmids ( pYCα-FliC(PETase)、pYCα-FliC(XynA)、pYCα-FliC(BG)、pYCα-FliC(EG)、pYCα-FliC(CBH))had successful sequenced.</p> |
<p>Reconstructed pYD1-flic-Mgfp.</p> | <p>Reconstructed pYD1-flic-Mgfp.</p> | ||
<h2>Dry Lab</h2> | <h2>Dry Lab</h2> | ||
Line 312: | Line 312: | ||
<div class="note-content"> | <div class="note-content"> | ||
<h2>Wet Lab</h2> | <h2>Wet Lab</h2> | ||
− | <p>We transformed pYD1- | + | <p>We transformed pYD1-α-tubulin、pYD1-β-tubulin into yeast competent cells EBY100 successfully.</p> |
− | <p>We constructed | + | <p>We constructed pYDF-eGFP successfully.</p> |
− | <p>We transformed | + | <p>We transformed pYDF-eGFP into yeast competent cells EBY100 in electronic transformation way and screened on SD plate (added leu), expanding culture.</p> |
</div> | </div> | ||
</div> | </div> | ||
Line 328: | Line 328: | ||
<div class="note-content"> | <div class="note-content"> | ||
<h2>Wet Lab</h2> | <h2>Wet Lab</h2> | ||
− | <p>We transformed pYCα- | + | <p>We transformed pYCα-α-tubulin、pYCα-β-tubulin、pYCα- mCherry-α-tubulin、pYCα-β-tubulin-mGFP、pYCα-mCherry (positive) into yeast competent cells invsc1 that was cultured on SD plates including leucine, tryptophan, histidine to screen.</p> |
− | <p>A strong reducing agent DDT was added to the cell culture medium of EBY100 to break the disulfide bond. Then we extracted the Saccharomyces cerevisiae EBY100 which were successfully transformed in plasmids | + | <p>A strong reducing agent DDT was added to the cell culture medium of EBY100 to break the disulfide bond. Then we extracted the Saccharomyces cerevisiae EBY100 which were successfully transformed in plasmids pYDF-eGFP. The protein in the supernatant was extracted and use coomassie blue staining to prove true. The protein was successfully extracted and the coomassie blue staining experiment succeeded.</p> |
</div> | </div> | ||
</div> | </div> | ||
Line 336: | Line 336: | ||
<div class="note-content"> | <div class="note-content"> | ||
<h2>Wet Lab</h2> | <h2>Wet Lab</h2> | ||
− | <p>We successfully transformed plasmids(pYCα- | + | <p>We successfully transformed plasmids(pYCα-α-tubulin、pYCα-β-tubulin、pYCα- mCherry-α-tubulin、pYCα-mCherry) into invsc1.</p> |
</div> | </div> | ||
</div> | </div> | ||
Line 343: | Line 343: | ||
<div class="note-content"> | <div class="note-content"> | ||
<h2>Wet Lab</h2> | <h2>Wet Lab</h2> | ||
− | <p>Saccharomyces cerevisiae that was transformed in plasmids(pYCα- | + | <p>Saccharomyces cerevisiae that was transformed in plasmids(pYCα-α-tubulin、pYCα-β-tubulin、pYCα- mCherry-α-tubulin、pYCα-mCherry) successfully expressed the target protein.</p> |
</div> | </div> | ||
</div> | </div> | ||
Line 350: | Line 350: | ||
<div class="note-content"> | <div class="note-content"> | ||
<h2>Wet Lab</h2> | <h2>Wet Lab</h2> | ||
− | <p>Through coomassie blue staining, target proteins expressed by pYD1- | + | <p>Through coomassie blue staining, target proteins expressed by pYD1-α-tubulin、pYD1-β-tubulin were successfully tested . Western Blot was used in chemical coloration to confirm the target protein.</p> |
<p>We constructed models to simulate the actual working state of Tubulin and Flagellum.</p> | <p>We constructed models to simulate the actual working state of Tubulin and Flagellum.</p> | ||
</div> | </div> | ||
Line 359: | Line 359: | ||
<h2>Wet Lab</h2> | <h2>Wet Lab</h2> | ||
<p>The effect of substrate DAB staining on protein detection was not ideal in Western blot. We attempted to use a more sensitive ECL color-developing method and achieved successfully.</p> | <p>The effect of substrate DAB staining on protein detection was not ideal in Western blot. We attempted to use a more sensitive ECL color-developing method and achieved successfully.</p> | ||
− | <p>Saccharomyces cerevisiae that was transformed in plasmids(pYD1- | + | <p>Saccharomyces cerevisiae that was transformed in plasmids(pYD1-α-tubulin、pYD1-β-tubulin) successfully expressed the target protein in cells.</p> |
</div> | </div> | ||
</div> | </div> | ||
Line 373: | Line 373: | ||
<div class="note-content"> | <div class="note-content"> | ||
<h2>Wet Lab</h2> | <h2>Wet Lab</h2> | ||
− | <p>We transformed pYCα- | + | <p>We transformed pYCα-α-tubulin、pYCα-β-tubulin、pYCα- mCherry-α-tubulin、pYCα-β-tubulin-mGFP、pYCα-mCherry (positive) into yeast competent cells invsc1 that was cultured on SD plates including leucine, tryptophan, histidine to screen.</p> |
</div> | </div> | ||
</div> | </div> | ||
Line 380: | Line 380: | ||
<div class="note-content"> | <div class="note-content"> | ||
<h2>Wet Lab</h2> | <h2>Wet Lab</h2> | ||
− | <p>Through coomassie blue staining, target proteins expressed by pYCα- | + | <p>Through coomassie blue staining, target proteins expressed by pYCα-α-tubuin、pYCα-β-tubulin、pYCα- mCherry-α-tubulin、pYCα-β-tubulin-mGFP、pYCα-mCherry (positive) were successfully tested . Western Blot in ECL color-developing method confirmed the target protein.</p> |
</div> | </div> | ||
</div> | </div> | ||
Line 387: | Line 387: | ||
<div class="note-content"> | <div class="note-content"> | ||
<h2>Wet Lab</h2> | <h2>Wet Lab</h2> | ||
− | <p>Through coomassie blue staining, target proteins expressed by pYCα- | + | <p>Through coomassie blue staining, target proteins expressed by pYCα-FliC(PETase)、pYCα-FliC(XynA)、pYCα-FliC(BG)、pYCα-FliC(EG)、pYCα-FliC(CBH) were successfully tested . Western Blot in ECL color-developing method confirmed the target protein.</p> |
</div> | </div> | ||
</div> | </div> | ||
Line 396: | Line 396: | ||
<div class="note-content"> | <div class="note-content"> | ||
<h2>Wet Lab</h2> | <h2>Wet Lab</h2> | ||
− | <p>Through coomassie blue staining, target proteins expressed by pYCα-FliC | + | <p>Through coomassie blue staining, target proteins expressed by pYCα-FliC(BG)、pYCα- FliC(EG)、pYCα-FliC(CBH) were successfully tested . Western Blot in ECL color-developing method confirmed the target protein.</p> |
<h2>Dry Lab</h2> | <h2>Dry Lab</h2> | ||
<p>The effect of tubulin concentration and GTP concentration on the length and intensity of microtubule polymerization was analyzed by establishing ordinary differential equations.</p> | <p>The effect of tubulin concentration and GTP concentration on the length and intensity of microtubule polymerization was analyzed by establishing ordinary differential equations.</p> | ||
Line 407: | Line 407: | ||
<div class="note-content"> | <div class="note-content"> | ||
<h2>Wet Lab</h2> | <h2>Wet Lab</h2> | ||
− | <p>Through coomassie blue staining, target proteins expressed by pYCα-FliC | + | <p>Through coomassie blue staining, target proteins expressed by pYCα-FliC(PETase)、pYCα-FliC(XynA) were successfully tested . Western Blot in ECL color-developing method confirmed the target protein.</p> |
</div> | </div> | ||
</div> | </div> | ||
Line 417: | Line 417: | ||
<h2>Wet Lab</h2> | <h2>Wet Lab</h2> | ||
<p>Make the standard curve of XynA enzyme activity.<br /> | <p>Make the standard curve of XynA enzyme activity.<br /> | ||
− | The activity of XynA enzyme expressed by pYCα-FliC | + | The activity of XynA enzyme expressed by pYCα-FliC(XynA) was successfully tested.<br /> |
Purified proteins for polymerization in vitro.</p> | Purified proteins for polymerization in vitro.</p> | ||
<h2>Dry Lab</h2> | <h2>Dry Lab</h2> | ||
Line 429: | Line 429: | ||
<div class="note-content"> | <div class="note-content"> | ||
<h2>Wet Lab</h2> | <h2>Wet Lab</h2> | ||
− | <p>The activity of XynA enzyme expressed by pYD1-FliC | + | <p>The activity of XynA enzyme expressed by pYD1-FliC(XynA) was successfully tested.<br /> |
Western Blot in ECL color-developing method confirmed the target protein (expressed by pYCα-FliC (XynA) and pYCα-mcherry) purified from supernatant.<br /> | Western Blot in ECL color-developing method confirmed the target protein (expressed by pYCα-FliC (XynA) and pYCα-mcherry) purified from supernatant.<br /> | ||
Attempt to polymerize microtubule and flagellar filaments in vitro.</p> | Attempt to polymerize microtubule and flagellar filaments in vitro.</p> |
Revision as of 02:15, 2 November 2017
Week 1 (March.19 - March.25)
Wet Lab
Read excellent literatures about synthetic biology and projects on iGEM Official Website.
Week 2 (March.26 - April.01)
Wet Lab
We discussed with our instructors about the project designing and decided to improve Saccharomyces cerevisiae surface display technology. Then we read iGEM projects about Saccharomyces cerevisiae surface display.
Week 3 (April.02 - April.08)
Wet Lab
We had a brainstorm about yeast surface display.
Week 4 (April.09 - April.15)
Wet Lab
After discussion, we set our initial project theme that displaying human tubulins on the surface of Saccharomyces cerevisiae. Moreover, we read more literatures about tubulins.
Week 5 (April.16 - April.22)
Wet Lab
We visited Mr Meng who is the doctor of Chinese Academy of Sciences and discussed our project with him. Through the discussion, we found it difficult to keep tubulins lasting polymerization in vitro. So we attempted to look for more stable materials. At last, we found flagellin which can polymerize spontaneously in vitro.
Week 6 (April.23 - April.29)
Wet Lab
Our experiment was discussed and designed. We divided the display system into two parts: the display modules and the secretory modules. With the special structure of surface display system, we could display the particular subunit onto the Saccharomyces cerevisiae surface as a linkage site and secrete other subunits into the extracellular environment to create a subunit-rich surroundings. With the optimal concentration of subunits, GTP and other ions, those subunits could reconstitute into microtubules and flagellum. In this way, we could finally display the microtubule and flagellum on the cell surface. And then, we could use this upgraded system to facilitate small molecules screening.
Dry Lab
Built a mathematical model to test the theoretical possibility of polymerization for tubulins and flagellins in vitro.
Week 7 (April.30 - May.06)
Wet Lab
In microtubule part, we intended to construct 8 vectors, they are pYD1-α-tubulin、pYD1-β-tubulin、pYCα-α-tubulin、pYD1-mCherry(positive control)、pYCα-β-tubulin、pYCα- mCherry-α-tubulin、pYCα-β-tubulin-mGFP、pYCα-mCherry(positive control).
Searched DNA sequences (flic、PETase、XynA、BG、EG、CBH)
Dry Lab
Tried to find the most appropriate length for linker to improve the possibility of polymerization.
Week 8 (May.07 - May.13)
Wet Lab
Obtained the target genes sequence(α-tubulin、β-tubulin、mCherry、GFP)and plasmids (pYD1:used to display, pYCα:used to secrete). We designed primers by using snapgene and sent them to the company for synthesis.
Designed and optimized DNA sequences of flagellin and enzymes(PETase、XynA、BG、EG、CBH). Send them to America for synthesis.
Dry Lab
We studied the mechanisms of tubulin and flagellin polymerization.
Week 9 (May.14 - May.20)
Wet Lab
Plasmids were digested by enzymes, and we had an agarose gel electrophoresis to prove true.
We used PCR to amplify target genes (α-tublin、β-tublin、mCherry、GFP) and used agarose gel electrophoresis to prove true. Then, we utilized infusion technology to ligate target genes with pYD1 or pYCα,and had an agarose gel electrophoresis to prove true. Moreover, we transformed vectors we constructing into competent Escherichia coli cells(DH5α). Screened on LB plate(added Ampicillin). Sent to the company to make sure the sequence.
Dry Lab
We discussed the main modeling problem in our project.
Week 10 (May.21 - May.27)
Wet Lab
As sequencing results show, we had successfully constructed pYD1-α and pYD1-mCherry. We continued constructing the rest plasmids ( pYD1-β-tubulin、pYCα-α-tubulin、pYCα-β-tubulin、pYCα- mCherry-α-tubulin、pYCα-β-tubulin-mGFP、pYCα-mCherry).
Dry Lab
We learned as many as possible modeling which maybe useful for our work.
Week 11 (May.28 - June.03)
Wet Lab
According to the growing curve we measured, Saccharomyces cerevisiae competent cells were made up, and we attempted to transform recombined plasmids in it using chemical transforming method.
Continued constructing plasmids.
Dry Lab
We learned as many as possible modeling which maybe useful for our work.
Week 12 (June.04 - June.10)
Wet Lab
We successfully constructed recombined plasmids(pYCα-α-tubulin、pYCα-β-tubulin、pYCα- mCherry-α-tubulin、pYCα-mCherry). We constructed pYD1-β once again.
Continued transforming recombined plasmids in Saccharomyces cerevisiae (EBY100 & invsc1) competent cells using chemical transforming method.
Dry Lab
We discussed to make sure what problem we were about to solve.
Week 13-15 (June.11 - July.01)
Wet Lab
Obtained the synthetic DNA flagellins and enzymes including PETase、XynA、BG、EG and CBH.
We prepared for the Final Exam so we stopped the experiments.
Dry Lab
We discussed to make sure what method we were about to use and what model we were about to build.
Week 16 (July.02 - July.08)
Wet Lab
pYD1-β was constructed successfully.
Plasmids were digested by enzymes, and we had a gel electrophoresis to prove true.
To get recombined plasmids(pYCα-FliC(PETase)、pYCα-FliC(XynA)、pYCα-FliC(BG)、pYCα-FliC(EG)、pYCα-FliC(CBH)) containing corresponding enzyme, we fused flic-N respectively with five enzymes(PETase、XynA、BG、EG、CBH) through PCR to get a part of target gene. Then we infused the part of target gene with flic-C and plasmids digested by enzymes. These plasmids could express secretory proteins. Screened strains on LB plate (added Ampicillin). Sent sequencing.
Recombined plasmid pYD1-flic-Mgfp was constructed in the same way with pYCα-FliC(PETase)、pYCα-FliC(XynA)、pYCα-FliC(BG)、pYCα-FliC(EG)、pYCα-FliC(CBH).
We tried electronic transformation way to transform plasmids into yeast competent cells due to the fact that we always failed in chemical transformation way.
Dry Lab
We established models using statistical mechanics describing the process of tubulin polymerization in vitro.
Week 17 (July.09 - July.15)
Wet Lab
Sent recombined plasmids including pYDF-eGFP、pYCα-FliC(PETase)、pYCα-FliC(XynA)、pYCα-FliC(BG)、pYCα-FliC(EG) and pYCα-FliC(CBH) sequencing.
We succeeded in electronic transformation way, transforming pYD1-mCherry into yeast competent cells and screening on SD plate (added Leu).
Dry Lab
Built a mathematical model to show the process of polymerization for flics in vitro.
Week 18 (July.16 - July.22)
Wet Lab
We transformed pYD1-mCherry into yeast competent cells EBY100 in electronic transformation way and screened on SD plate (added Leu), expanding culture.
Plasmids ( pYCα-FliC(PETase)、pYCα-FliC(XynA)、pYCα-FliC(BG)、pYCα-FliC(EG)、pYCα-FliC(CBH))had successful sequenced.
Reconstructed pYD1-flic-Mgfp.
Dry Lab
After collecting data, we constructed a three-dimensional model of tubulin polymerization, in which the independent variables were temperature, concentration, and energy GTP.
Week 19 (July.23 - July.29)
Wet Lab
We transformed pYD1-α-tubulin、pYD1-β-tubulin into yeast competent cells EBY100 successfully.
We constructed pYDF-eGFP successfully.
We transformed pYDF-eGFP into yeast competent cells EBY100 in electronic transformation way and screened on SD plate (added leu), expanding culture.
Week 20 (July.23 - July.29)
Wet Lab
We transformed plasmid pYD1-mCherry (positive) into Saccharomyces cerevisiae EBY100 and observed that the extracted protein have red fluorescence. The expression of target protein in EBY100 was successfully. A strong reducing agent DDT was added to the cell culture medium of EBY100 to break the disulfide bond. Then the target protein mCherry displayed on the Saccharomyces cerevisiae surface was separated from Saccharomyces cerevisiae EBY100, the protein in the supernatant was extracted and the fluorescence was observed.
Week 21 (July.30 - August.05)
Wet Lab
We transformed pYCα-α-tubulin、pYCα-β-tubulin、pYCα- mCherry-α-tubulin、pYCα-β-tubulin-mGFP、pYCα-mCherry (positive) into yeast competent cells invsc1 that was cultured on SD plates including leucine, tryptophan, histidine to screen.
A strong reducing agent DDT was added to the cell culture medium of EBY100 to break the disulfide bond. Then we extracted the Saccharomyces cerevisiae EBY100 which were successfully transformed in plasmids pYDF-eGFP. The protein in the supernatant was extracted and use coomassie blue staining to prove true. The protein was successfully extracted and the coomassie blue staining experiment succeeded.
Week 22 (August.06 - August.12)
Wet Lab
We successfully transformed plasmids(pYCα-α-tubulin、pYCα-β-tubulin、pYCα- mCherry-α-tubulin、pYCα-mCherry) into invsc1.
Week 23 (August.13 - August.19)
Wet Lab
Saccharomyces cerevisiae that was transformed in plasmids(pYCα-α-tubulin、pYCα-β-tubulin、pYCα- mCherry-α-tubulin、pYCα-mCherry) successfully expressed the target protein.
Week 24 (August.20 - August.26)
Wet Lab
Through coomassie blue staining, target proteins expressed by pYD1-α-tubulin、pYD1-β-tubulin were successfully tested . Western Blot was used in chemical coloration to confirm the target protein.
We constructed models to simulate the actual working state of Tubulin and Flagellum.
Week 25 (August.12 – September.02 )
Wet Lab
The effect of substrate DAB staining on protein detection was not ideal in Western blot. We attempted to use a more sensitive ECL color-developing method and achieved successfully.
Saccharomyces cerevisiae that was transformed in plasmids(pYD1-α-tubulin、pYD1-β-tubulin) successfully expressed the target protein in cells.
Week 26 (September.03 - September.09)
Western Blot in ECL color-developing method confirmed the target protein was expressed.
Week 27 (September.10 - September.16)
Wet Lab
We transformed pYCα-α-tubulin、pYCα-β-tubulin、pYCα- mCherry-α-tubulin、pYCα-β-tubulin-mGFP、pYCα-mCherry (positive) into yeast competent cells invsc1 that was cultured on SD plates including leucine, tryptophan, histidine to screen.
Week 28 (September.17 - September.23)
Wet Lab
Through coomassie blue staining, target proteins expressed by pYCα-α-tubuin、pYCα-β-tubulin、pYCα- mCherry-α-tubulin、pYCα-β-tubulin-mGFP、pYCα-mCherry (positive) were successfully tested . Western Blot in ECL color-developing method confirmed the target protein.
Week 29 (September.24 - September.30)
Wet Lab
Through coomassie blue staining, target proteins expressed by pYCα-FliC(PETase)、pYCα-FliC(XynA)、pYCα-FliC(BG)、pYCα-FliC(EG)、pYCα-FliC(CBH) were successfully tested . Western Blot in ECL color-developing method confirmed the target protein.
Week 30 (October.1 - October.7)
Wet Lab
Through coomassie blue staining, target proteins expressed by pYCα-FliC(BG)、pYCα- FliC(EG)、pYCα-FliC(CBH) were successfully tested . Western Blot in ECL color-developing method confirmed the target protein.
Dry Lab
The effect of tubulin concentration and GTP concentration on the length and intensity of microtubule polymerization was analyzed by establishing ordinary differential equations.
Week 31 (October.8 - October.15)
Wet Lab
Through coomassie blue staining, target proteins expressed by pYCα-FliC(PETase)、pYCα-FliC(XynA) were successfully tested . Western Blot in ECL color-developing method confirmed the target protein.
Week 32 (October.16 - October.23)
Wet Lab
Make the standard curve of XynA enzyme activity.
The activity of XynA enzyme expressed by pYCα-FliC(XynA) was successfully tested.
Purified proteins for polymerization in vitro.
Dry Lab
Simulation of the efficiency of flagellin aggregation on yeast surface by flagellin concentration and yeast concentration.
Week 33 (October.24 - November.1)
Wet Lab
The activity of XynA enzyme expressed by pYD1-FliC(XynA) was successfully tested.
Western Blot in ECL color-developing method confirmed the target protein (expressed by pYCα-FliC (XynA) and pYCα-mcherry) purified from supernatant.
Attempt to polymerize microtubule and flagellar filaments in vitro.
Dry Lab
The relationship between flagellin polymerization and time was used to guide the culture time of yeast.
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