Difference between revisions of "Team:Kyoto/Discussion"

 
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<div class="box27">
 
<div class="box27">
     <span class="box-title"><font face="Segoe UI">仲里 一応 訳中</font></span>
+
     <span class="box-title"><font face="Segoe UI">Table of contents</font></span>
 
     <ul class="index1">
 
     <ul class="index1">
             <li><a href="#seminor"><font color="#fffafa"><font face="Segoe UI">1) iGEM seminor at Kyoto university</font></a></li>
+
             <li><a href="#Discussion1">1) Summary of our research</font></a></li>
             <li><a href="#Workshop"><font color="#fffafa"><font face="Segoe UI">2) Workshop with high school students</font></a></li>
+
             <li><a href="#Discussion2">2) Performance and application of "Swallowmyces cerevisiae"</font></a></li>
            <li><a href="#Presentation"><font color="#fffafa"><font face="Segoe UI">3) Presentation at ISS</font></a></li>
+
             <li><a href="#Discussion3">3) Biocontainment system </font></a></li>
             <li><a href="#Learning"><font color="#fffafa"><font face="Segoe UI">4) Learning Lounge</font></a></li>
+
 
              
 
              
 
</ul>
 
</ul>
 
</div>
 
</div>
 +
<br><br><br>
  
 +
<h5 id="Discussion1">1)Summary of our research</h5>
  
<h5 id="summary">1) The summary</h5>
+
<p>
 +
We worked on the construction of the yeast “Swallowmyces cerevisiae” which absorbs NaCl from solution and adjusts the salt concentration of the solution. We created a gene-disrupted strain designed to accumulate Na+ inside the cell, expressed the chaperones, produced the compatible solute to reduce the damage the cells receive from high salt concentration, and added various genes for sequestering Na+ in vacuoles to the collection of BioBrick parts. With the help of mathematical modeling, we optimized the system, and eventually produced a yeast that retains averagely 80 mM of Na+ into the cell. Also, we performed the model experiment that this device really absorbed Na+ from the solution and demonstrated the decrease of Na+ in solution by it.
 +
</p>
  
<p>Pine-wilt disease, which is spreading all over the world, is one of the major plant diseases causing severe economic damage. A significant amount of money and labor are required for the treatment of forests each year. We focused on the cause of the disease, a nematode called <i>B. xylophilus</i>, and started our “B. x. Busters” project designed to create a new genetically modified microorganism exterminating <i>B. xylophilus</i>. We searched for a carrier of RNAi by feeding and revealed that under laboratory conditions, <i>B. xylophilus</i> preys on <i>S. cerevisiae</i> by sucking up the yeast’s insides using a straw-like stylet. We developed a reporter distinguishing <i>B. xylophilus</i> which ate <i>S. cerevisiae</i> by recording green fluorescence in the digestive track of <i>B. xylophilus</i> in live microscopy. In addition, we constructed a plasmid for <i>S. cerevisiae</i> expressing dsRNA, characterized its expression, and observed <i>B. xylophilus</i> which preyed on <i>S. cerevisiae</i> expressing dsRNA. These results, combined with our integrated Human Practices, could bring about promising new methodology in the fight against pine-wilt disease.</p>
+
<br><br><br>
 +
<h5 id="Discussion2">2)Performance and application of "Swallowmyces cerevisiae"</h5>
  
<h5 id="method">2) The method of RNAi by feeding</h5>
+
<p> Our early purpose was to produce this device lowering the salt concentration of the aqueous solution in the test tube and assist the operation of other devices by it.
 +
</p>
 +
<br>
 +
<p>
 +
Our pilot experiments showed the repertoires of proteins nonspecifically interacting with GFP are different between a solution with a salt concentration of 1000 mM and a solution with 500 mM. As can be inferred from this example, if we really aim the effect of helping functions of other devices, it is worth working on the desalination from solution of NaCl concentration 1000mM with a little up from the current salt concentration range. The current system is still the first prototype, and it seems to be necessary to add various improvements after this.
 +
</p>
 +
<br>
 +
<p>There are several possible suggestions for concrete improvement. </p>
 +
<br>
 +
<p>
 +
First of all, it will be necessary to raise the halotolerance of yeast. Since wild-type yeast has multiple pumps exhausting Na+ outside, the yeast can grow even in the solution of NaCl concentration 1000 mM (inhibition of the growth is seen though). However, in order to accumulate Na+ inside of yeast, it is necessary to turn off these pumps. As seen in this study, yeasts of such strains become sensitive even to solution of very low NaCl concentrations. It is necessary to improve so that such susceptible yeast can grow with maintaining the ability to take Na+ from the external solution, even if the salt concentration is higher than the present situation.
 +
</p>
 +
<br>
 +
<p>
  
<p>First, by feeding RNAi we aimed to knockdown the AK1 gene of <i>B. xylophilus</i>, since a previous study claimed success in targeting this gene with soaking RNAi [1]. However, we couldn’t reproduce any fatal effect to <i>B. xylophilus</i> just by soaking in RNA solution. Instead, we chose to feed <i>B. xylophilus</i> with <i>S. cerevisiae</i> expressing dsRNA by the conditional Gal1 promoter (BBa_K517001). We spread <i>S. cerevisiae</i> cultured in galactose medium onto no-nutrient agar medium containing no carbon source and fed it to <i>B. xylophilus</i>. This low nutrient condition prevents miscellaneous germs from proliferating, but at the same time the <i>S. cerevisiae</i> also lack nutrients. It probably led to autophagy. Under these conditions, it’s possible that low dosages of dsRNA were given to <i>B. xylophilus</i> than we had initially anticipated. We recognize that we have plenty of room for improvement, optimizing the agar culture condition and preparing <i>S. cerevisiae</i> which maintaining dsRNA expression more stably for a longer period of time.</p>
 
  
  
<h5 id="dsRNA">3) Where is dsRNA in <i>S. cerevisiae</i>?  Do <i>B. xylophilus</i> suck up dsRNA?</h5>
 
  
<p> Our experiments confirmed SKI2Δ <i>S. cerevisiae</i> contains more dsRNA than wild type yeast. SKI complex is found in the cytoplasm [2],[3].In wild type yeast, SKI complex degrades dsRNA. Therefore, our results suggest that the dsRNA is partially in the cytoplasm. However, the results of Xenopus oocyte microinjection suggested that almost all the dsRNA is present in the nucleus. From our live imaging, it was not possible to see the yeast nucleus passed through the small diameter of the nematode’s stylet. If <i>B. xylophilus</i> doesn’t eat the yeast nucleus, the dsRNA will not reach the nematode’s body. Our further research confirmed that we could use the HIV Rev-RRE nuclear export pathway to help export dsRNA into the cytoplasm. Therefore, we predict that <i>S. cerevisiae</i> which has this function would improve dsRNA nuclear export to the cytoplasm, increasing the effective dose to predator <i>B. xylophilus</i>.</p>
 
  
<p>The eGFP feeding reporter we established provided us with ideas for optimizing RNAi by feeding. For instance, we could express a histone-eGFP fusion protein in <i>S. cerevisiae</i> and verify if the nucleus of <i>S. cerevisiae</i> is in fact eaten by <i>B. xylophilus</i>. Extracting DNA or RNA derived from <i>S. cerevisiae</i> will reveal whether <i>B. xylophilus</i> eats the yeast nucleus by identifying the nucleic acid of <i>S. cerevisiae</i> in the intestinal track.</p>
 
  
<h5 id="is">4) Is feeding RNAi effective?</h5>
+
In this experiment, mangrin and ZrGPD1 were used and had the effect of increasing salt tolerance. In this project, regarding these, we merely expressed the sequence in nature using the constitutive promoters as it was. Searching for sequences that are more effective against salt tolerance or modifying expression levels and localization signals will leave room for further modification that leads to further salt tolerance increase. Also, ZrGPD1 acts as a compatible solute by producing a large amount of glycerol. But, in addition to this factor, there is a report that giving yeast high salt tolerance succeeded by simultaneously expressing the glycerol transporters encoded by ZrFPS1, in the past reports.[1] This time we tried to clone this factor, but it did not succeed. By adding such a tool, salt tolerance of yeast may improve dramatically.
<p>In <i>C. elegans</i>, since a dsRNA-specific bidirectional channel (SID-1) is expressed in the cell membrane [4], it is known that feeding RNAi occurs efficiently. Interestingly, human and Drosophila preserve proteins with similar functions [5]. As we were unable to reproduce published soaking RNAi results with <i>B. xylophilus</i>, we examined whether such channel proteins even existed in B. xylophilus using BLAST search.<p>
+
</p>
 +
<br>
 +
<p>
 +
Secondly, there is a method of positively flowing external Na+ into the cell by utilizing a transporter on the cell membrane. Using AtHKT1 of the Arabidopsis thaliana, we observed mildly elevated Na+ uptake into the cells this time. It is known that this factor, when expressed in Arabidopsis thaliana, causes remarkable salt tolerance, for example, from facts confirmed when that homologues of ice plant which is a salt tolerant plant containing it were cloned and it expressed in <i>A. thaliana</i> in the past. We tried cloning this McHKT2 this time, but we also could not make it succeed. By adding this factor to the tool box, the desalination at a higher level is expected to be possible.
 +
</p>
 +
<br>
 +
<p>
 +
Third, as a group of factors functioning on the vacuole membrane, there is a possibility of improvement. All of these are membrane proteins, and for many factors, only by changing the expression plasmid to a high copy plasmid, apparent inhibition of proliferation has been observed. Membrane proteins are synthesized on the membrane of the endoplasmic reticulum, maturated through intricate processing and folding in the endoplasmic reticulum, and transported to the target organelle (vacuole). Overexpression of a foreign gene may negatively affect cell proliferation by competing with the synthesis of important membrane proteins inherent in the cell. In addition, since genes expressed in plants are expressed in yeast, it is impossible to avoid the fact that many molecules that cause abnormality in maturation in the course of synthesis will appear. Under current conditions, there is a possibility that the protein synthesis activity of the cell may be decreased due to activation of ERAD and so on. In order to construct a more efficient system, it will be necessary to tune the delicate expression level of these related genes.
 +
</p>
 +
<br>
 +
<p>
 +
In this way, a much more efficient biological desalination method than current levels may be accomplished by not only improvement of individual elements but also utilization of mathematical models and repetition of combination optimization.
 +
</p>
 +
<br><br><br>
  
<p>When examining <i>C. elegans</i> SID-1 (GenBank: AF 478687.1) as a query, it seems that there is no highly homologous sequence in the <i>B. xylophilus</i> reference genome. As far as we consider it, the results we obtained seem to be reasonable, but we cannot exclude the possibility that the <i>B. xylophilus</i> draft genome is incomplete.</p>
 
  
<p>We also researched <i>Meloidogyne incognita</i> which is nematode with a stylet like <i>B. xylophilus</i>. Similar to <i>B. xylophilus</i>, we could not find SID-1 homologues in <i>M. incognita</i>. Interestingly, there is a report that remarkable effect was obtained in <i>M. incognita</i> with feeding RNAi using plants [6],[7]. We hypothesize that <i>M. incognita</i> has another RNAi enabling protein and RNAi reaction is occurring differently from <i>C. elegans</i>.</p>
+
<h5 id="Discussion3">3)Biocontainment system  </h5>
 +
<p>
 +
The conjugations of cell or between cells using SdrG-Fgβ binding was hardly visible in this project. This may be because, as we mentioned in the results, we did not give these devices enough time to combine. We need to combine them for a longer time and clarify in future experiment whether these pairs can actually be used for purpose.
 +
</p>  
 +
<br>
 +
<p>
 +
This time, we tried to introduce a system of SdrG-FgBeta to add new tools. And, in addition to the SdrG-FgBeta system, there are other known systems known as pairs of proteins that induce cooperative binding. The most famous are the pair of Spy-tag and Spy catcher. This is a proven pair, reported to form a covalent bond each other by contact in a short time, and also included in the distribution kit of iGEM. It is important not only to stick to SdrG-Fgβ but also to try to adhere between cells by other methods. If we can introduce multiple binding pairs, we will be able to design cell aggregation by changing the selection of "handles" that are expressed for each cell.
 +
</p>
 +
<br>
 +
<p>With respect to <i>Escherichia coli</i>, a paper that "Assembling E. coli with each other using nanobody's surface display" has been reported recently.[2] We succeeded in fixing yeast surface-displayed flag tag fusion protein, with magnetic beads conjugated with anti-Flag antibody this time. By replacing the same display system with a pair of nanobody-antigen described in this document, it is expected that the cell assembly of budding yeast can be freely controlled.
 +
</p>
 +
<br>
 +
<p>
 +
Also, if the aggregation system is to be actually used as a method of biocontainment at the actual sites, indirect assemblies using something small molecules may be more effective than yeasts do not directly assemble. If all of yeasts expressed the nanobody targeting the same small molecule, it will be able to aggregate yeast efficiently by the administration of a small molecule to the population.
 +
</p>
  
<p>Finally, we considered that the mechanism of RNAi is relevant for selecting target genes. For example, if dsRNA cannot be transported from the intestinal tract to other cells of the body, it is necessary to select a gene expressed in the intestine as a target. RNAi targeting a gene such as a digestive enzyme or channel protein could result in starvation of the nematodes, reducing their fitness. As an alternative, it may be possible to engineer yeast that express a transporter to assist with dsRNA delivery to other tissues.</p>
+
<br><br>
  
 
+
<div class="reference">
<h5 id="genes">5) Targeting essential nematode genes</h5>
+
<p>We tried to confirm whether RNAi by feeding has a fatal effect on <i>B. xylophilus</i> survival. However, we had no method to know the difference between life and death except for judging from the movement of <i>B. xylophilus</i> and, to make matters worse, dead <i>B. xylophilus</i> quickly dried-up and became difficult to detect. Therefore, it may be required to select a target gene (such as dpy [8]) which expressed an obvious change in phenotype without killing, to establish the effect of RNAi by feeding in the future.</p>
+
 
+
<h5 id="future">6) Future</h5>
+
  <p>In the beginning, we intended to develop our “B. x. Busters” yeast as a biological pesticide, but we may need to solve many problems in advance, such as biosafety. As we described in our Human Practice (<a href="https://2017.igem.org/Team:Kyoto/Discussion_HP">https://2017.igem.org/Team:Kyoto/Discussion_HP</a>), a promising strategy, attempting to create genetically-engineered pine trees expressing RNAi, is proposed. Our yeast system should be ideal for screening target genes and effective RNAi. RNAi by feeding with <i>S. cerevisiae</i> with optimization should reduce the time required for growing plants and would help us to realize our plan earlier. Accordingly, we plan to further improve our “B. x. Busters” and establish more effective RNAi by feeding. In addition to SKI2, we should verify the effect that other RNA metabolism-related factors may have on dsRNA accumulation. We can also use the Rev-RRE system to promote nuclear export, and improve our eGFP maker. When it comes to <i>E. coli</i>, many kinds of safety systems for using genetically-engineered <i>E. coli</i> in the environment have already been considered. Developing such systems for <i>S. cerevisiae</i> may bring about the possibility of their use not only in laboratories, but also in our environment.</p>
+
 
         <h6>Reference</h6>
 
         <h6>Reference</h6>
 
           <ul class="reference">
 
           <ul class="reference">
            <li>[1] X. rong Wang, X. Cheng, Y. dong Li, J. ai Zhang, Z. fen Zhang, and H. rong Wu, “Cloning arginine kinase gene and its RNAi in <I>Bursaphelenchus xylophilus</I> causing pine wilt disease,” Eur. J. Plant Pathol., vol. 134, no. 3, pp. 521–532, 2012.</li>
+
<li>[1]Hou,Lihua Wang,Meng Wang,Cong Wang,Chunling Wang,Haiyong (2013) Analysis of salt-tolerance genes in zygosaccharomyces rouxii, <i>Applied Biochemistry and Biotechnoloogy</i> 1417-1425 </li>
            <li>[2] F. Halbach, P. Reichelt, M. Rode, and E. Conti, “The yeast ski complex: Crystal structure and rna channeling to the exosome complex,” Cell, 2013.</li>
+
<li>[2]C.Mcmahon, A.Baier, R.Pascolutti et al. (2018) Yeast surface display platform for rapid discovery of conformationally selective nanobodies <i>Nature Structural & Molecular Biology</i> Vol.25</li><br>
            <li>[3] K. Kalisiak et al., “A short splicing isoform of HBS1L links the cytoplasmic exosome and SKI complexes in humans,” Nucleic Acids Res., vol. 45, no. 4, 2017.</li>
+
          </ul></div>
<li>[4] J. D. Shih and C. P. Hunter, “SID-1 is a dsRNA-selective dsRNA-gated channel,” vol. 17(6), pp. 1057–1065, 2011.</li>
+
<li>[5] M. O. Elhassan, J. Christie, and M. S. Duxbury, “Homo sapiens Systemic RNA Interference-defective-1 Transmembrane Family Member 1 (SIDT1) Protein Mediates Contact-dependent Small RNA Transfer and MicroRNA-21-driven Chemoresistance ,” J. Biol. Chem., 2011.</li>
+
<li>[6] T. K. Dutta, P. K. Papolu, P. Banakar, D. Choudhary, A. Sirohi, and U. Rao, “Tomato transgenic plants expressing hairpin construct of a nematode protease gene conferred enhanced resistance to root-knot nematodes.,” Front. Microbiol., vol. 6, p. 260, 2015.</li>
+
<li>[7] B. C. Yadav, K. Veluthambi, and K. Subramaniam, “Host-generated double stranded RNA induces RNAi in plant-parasitic nematodes and protects the host from infection,” Mol. Biochem. Parasitol., vol. 148, pp. 219–222, 2006.</li>
+
<li>[8] A. P. Page and I. L. Johnstone, “The cuticle,” WormBook, vol. 1.138.1, 2007.</li>
+
<br>
+
<br>
+
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Latest revision as of 00:42, 7 December 2018

Team:Kyoto/Project - 2018.igem.org




1)Summary of our research

We worked on the construction of the yeast “Swallowmyces cerevisiae” which absorbs NaCl from solution and adjusts the salt concentration of the solution. We created a gene-disrupted strain designed to accumulate Na+ inside the cell, expressed the chaperones, produced the compatible solute to reduce the damage the cells receive from high salt concentration, and added various genes for sequestering Na+ in vacuoles to the collection of BioBrick parts. With the help of mathematical modeling, we optimized the system, and eventually produced a yeast that retains averagely 80 mM of Na+ into the cell. Also, we performed the model experiment that this device really absorbed Na+ from the solution and demonstrated the decrease of Na+ in solution by it.




2)Performance and application of "Swallowmyces cerevisiae"

Our early purpose was to produce this device lowering the salt concentration of the aqueous solution in the test tube and assist the operation of other devices by it.


Our pilot experiments showed the repertoires of proteins nonspecifically interacting with GFP are different between a solution with a salt concentration of 1000 mM and a solution with 500 mM. As can be inferred from this example, if we really aim the effect of helping functions of other devices, it is worth working on the desalination from solution of NaCl concentration 1000mM with a little up from the current salt concentration range. The current system is still the first prototype, and it seems to be necessary to add various improvements after this.


There are several possible suggestions for concrete improvement.


First of all, it will be necessary to raise the halotolerance of yeast. Since wild-type yeast has multiple pumps exhausting Na+ outside, the yeast can grow even in the solution of NaCl concentration 1000 mM (inhibition of the growth is seen though). However, in order to accumulate Na+ inside of yeast, it is necessary to turn off these pumps. As seen in this study, yeasts of such strains become sensitive even to solution of very low NaCl concentrations. It is necessary to improve so that such susceptible yeast can grow with maintaining the ability to take Na+ from the external solution, even if the salt concentration is higher than the present situation.


In this experiment, mangrin and ZrGPD1 were used and had the effect of increasing salt tolerance. In this project, regarding these, we merely expressed the sequence in nature using the constitutive promoters as it was. Searching for sequences that are more effective against salt tolerance or modifying expression levels and localization signals will leave room for further modification that leads to further salt tolerance increase. Also, ZrGPD1 acts as a compatible solute by producing a large amount of glycerol. But, in addition to this factor, there is a report that giving yeast high salt tolerance succeeded by simultaneously expressing the glycerol transporters encoded by ZrFPS1, in the past reports.[1] This time we tried to clone this factor, but it did not succeed. By adding such a tool, salt tolerance of yeast may improve dramatically.


Secondly, there is a method of positively flowing external Na+ into the cell by utilizing a transporter on the cell membrane. Using AtHKT1 of the Arabidopsis thaliana, we observed mildly elevated Na+ uptake into the cells this time. It is known that this factor, when expressed in Arabidopsis thaliana, causes remarkable salt tolerance, for example, from facts confirmed when that homologues of ice plant which is a salt tolerant plant containing it were cloned and it expressed in A. thaliana in the past. We tried cloning this McHKT2 this time, but we also could not make it succeed. By adding this factor to the tool box, the desalination at a higher level is expected to be possible.


Third, as a group of factors functioning on the vacuole membrane, there is a possibility of improvement. All of these are membrane proteins, and for many factors, only by changing the expression plasmid to a high copy plasmid, apparent inhibition of proliferation has been observed. Membrane proteins are synthesized on the membrane of the endoplasmic reticulum, maturated through intricate processing and folding in the endoplasmic reticulum, and transported to the target organelle (vacuole). Overexpression of a foreign gene may negatively affect cell proliferation by competing with the synthesis of important membrane proteins inherent in the cell. In addition, since genes expressed in plants are expressed in yeast, it is impossible to avoid the fact that many molecules that cause abnormality in maturation in the course of synthesis will appear. Under current conditions, there is a possibility that the protein synthesis activity of the cell may be decreased due to activation of ERAD and so on. In order to construct a more efficient system, it will be necessary to tune the delicate expression level of these related genes.


In this way, a much more efficient biological desalination method than current levels may be accomplished by not only improvement of individual elements but also utilization of mathematical models and repetition of combination optimization.




3)Biocontainment system

The conjugations of cell or between cells using SdrG-Fgβ binding was hardly visible in this project. This may be because, as we mentioned in the results, we did not give these devices enough time to combine. We need to combine them for a longer time and clarify in future experiment whether these pairs can actually be used for purpose.


This time, we tried to introduce a system of SdrG-FgBeta to add new tools. And, in addition to the SdrG-FgBeta system, there are other known systems known as pairs of proteins that induce cooperative binding. The most famous are the pair of Spy-tag and Spy catcher. This is a proven pair, reported to form a covalent bond each other by contact in a short time, and also included in the distribution kit of iGEM. It is important not only to stick to SdrG-Fgβ but also to try to adhere between cells by other methods. If we can introduce multiple binding pairs, we will be able to design cell aggregation by changing the selection of "handles" that are expressed for each cell.


With respect to Escherichia coli, a paper that "Assembling E. coli with each other using nanobody's surface display" has been reported recently.[2] We succeeded in fixing yeast surface-displayed flag tag fusion protein, with magnetic beads conjugated with anti-Flag antibody this time. By replacing the same display system with a pair of nanobody-antigen described in this document, it is expected that the cell assembly of budding yeast can be freely controlled.


Also, if the aggregation system is to be actually used as a method of biocontainment at the actual sites, indirect assemblies using something small molecules may be more effective than yeasts do not directly assemble. If all of yeasts expressed the nanobody targeting the same small molecule, it will be able to aggregate yeast efficiently by the administration of a small molecule to the population.



Reference
  • [1]Hou,Lihua Wang,Meng Wang,Cong Wang,Chunling Wang,Haiyong (2013) Analysis of salt-tolerance genes in zygosaccharomyces rouxii, Applied Biochemistry and Biotechnoloogy 1417-1425
  • [2]C.Mcmahon, A.Baier, R.Pascolutti et al. (2018) Yeast surface display platform for rapid discovery of conformationally selective nanobodies Nature Structural & Molecular Biology Vol.25