|
|
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| <li>To make the project applicable in real life, we designed a device with modified engineering bacteria inside, which can be placed in soil to attract and kill nematodes. | | <li>To make the project applicable in real life, we designed a device with modified engineering bacteria inside, which can be placed in soil to attract and kill nematodes. |
| </li> | | </li> |
− | <li>Assuming there is a farmland, we took advantage of gas diffusion model and nematodes’ movement analogue simulation to find the best position where for the device to be placed in this hypothetical farmland. | + | <li>Assuming there is a farmland, we took advantage of gas diffusion and nematodes’ movement analogue simulation to find the best position for the device to be placed. |
| </li> | | </li> |
− | <li>We established a database to broaden the scope of our applications, combined with our methods, to kill more different pests. We hope that the new environment-friendly method, based on principles of synthetic biology, could be shared with and improved by the researchers all over the world. | + | <li>We established a database to broaden the scope of our applications, combined with our methods, to kill more different pests. We hope this new environment-friendly method, based on principles of synthetic biology, could be shared with and improved by the researchers all over the world. |
| </li> | | </li> |
| </ol> | | </ol> |
| + | |
| <h2 id="design">Design</h2> | | <h2 id="design">Design</h2> |
| <h3>Device 1.0</h3> | | <h3>Device 1.0</h3> |
| <p>In order to enable our project to be applied in real environment, we designed and made Device 1.0. Because the productivity of attracting substance by <em>E.coli</em> is limited and the price of man-made attracting substance is quite high. We choose low-cost CO<sub>2</sub> as our assistant attracting substance since it was demonstrated that carbon dioxide has a function of attracting nematodes. | | <p>In order to enable our project to be applied in real environment, we designed and made Device 1.0. Because the productivity of attracting substance by <em>E.coli</em> is limited and the price of man-made attracting substance is quite high. We choose low-cost CO<sub>2</sub> as our assistant attracting substance since it was demonstrated that carbon dioxide has a function of attracting nematodes. |
| </p> | | </p> |
− | <p>Our device has four areas. The first area is carbon dioxide generating area. We produce CO<sub>2</sub> by mixing limestone and diluted hydrochloric acid together, which is widely used in industry. The second area is <em>E.coli</em> culturing area. It includes a medium inside the device - to culture modified engineering bacteria. The third area is light controlling area, which includes a LED light. When it is turned on, red emission will activate the promoter and bacterial cells will express attracting substance; while the LED light is turned off, toxalbumin will be produced. The forth area is made up of a cuboid outer shell, which can support our device. | + | <p>Our device has four areas. The first area is CO<sub>2</sub> generating area. We produce CO<sub>2</sub> by mixing limestone and dilute hydrochloric acid together, which is widely used in industry. The second area is <em>E.coli</em> culturing area. It includes a medium inside the device - to culture modified engineering bacteria. The third area is light controlling area, which includes a LED light. When it is turned on, red emission will activate the promoter and bacterial cells will express attracting substance; while the LED light is turned off, toxalbumin will be produced. The forth area is made up of a cuboid outer shell, which can support the device. |
| </p> | | </p> |
| <figure class="text-center"> | | <figure class="text-center"> |
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| </figcaption> | | </figcaption> |
| </figure> | | </figure> |
− | <p>The figure above shows our product – Device 1.0. Meanwhile, we simulate our device in the lab to show our system is able to work under real-world conditions. | + | <p>The figure above shows our product – Device 1.0. We have simulated our device in the lab and our results show that our system is able to work under real-world conditions. |
| </p> | | </p> |
| | | |
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| </video> | | </video> |
| | | |
− | <p>There are 8 steps to apply our device in farmland just as it is showed in the video above. And all the procedures below were conducted in a fume hood. | + | <p>There are 8 steps to apply our device in farmland as shown in the video above. And the procedures below were conducted in a fume hood. |
| </p> | | </p> |
| | | |
| <ul> | | <ul> |
| <li>Step 1. We gathered a box of soil from our farmland.</li> | | <li>Step 1. We gathered a box of soil from our farmland.</li> |
− | <li>Step 2. We applied culture medium onto slide glasses. Unfortunately, because of the limitation of our wet lab condition, we didn’t apply real engineering bacteria this time.</li> | + | <li>Step 2. We applied culture medium onto slide glasses.</li> |
| <li>Step 3. We gathered several small stones used as CaCO<sub>3</sub> and put them into the test tube.</li> | | <li>Step 3. We gathered several small stones used as CaCO<sub>3</sub> and put them into the test tube.</li> |
| <li>Step 4. We added HCl into the separating funnel.</li> | | <li>Step 4. We added HCl into the separating funnel.</li> |
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| <p>After discussion among team members about device 1.0, we found several deficiencies. First of all, the size of our device is so limited that the reaction substrate (limestone and diluted hydrochloric acid) is not enough to generate CO<sub>2</sub> constantly. Replenishing the reaction substrate frequently will greatly increase the cost. Secondly, the space utilization percentage is low on the slide medium; as a result, the production of both attractant and toxalbumin is low. Lastly, LED tube is sizable and needed to be powered constantly, thus not suitable for farmland. In device 2.0, we improved device 1.0 in those three aspects mentioned above. Indeed, we need to further improve our device. | | <p>After discussion among team members about device 1.0, we found several deficiencies. First of all, the size of our device is so limited that the reaction substrate (limestone and diluted hydrochloric acid) is not enough to generate CO<sub>2</sub> constantly. Replenishing the reaction substrate frequently will greatly increase the cost. Secondly, the space utilization percentage is low on the slide medium; as a result, the production of both attractant and toxalbumin is low. Lastly, LED tube is sizable and needed to be powered constantly, thus not suitable for farmland. In device 2.0, we improved device 1.0 in those three aspects mentioned above. Indeed, we need to further improve our device. |
| </p> | | </p> |
− | <p>Firstly, we assume that modified engineering bacteria can produce ideal concentration of attractant and toxalbumin (the ideal concentration is in reasonable range). Then, considering the problem of space utilization rate and the fact that E.coli can only grow on the surface of the medium, we changed the medium’s shape to sphericity to reach the highest space utilization percentage. Meanwhile, our device has been shaped to sphericity too, and the LED light has been moved to the center so that the whole surface can get the radiation evenly. A design like this enable us to use mini LED light bulb, and use solar energy instead of electricity as our power resource. This change fulfill our aim to save money and energy, which is also more economical and enviromentally friendly. | + | <p>Firstly, we assume that engineering bacteria can produce ideal concentration of attractant and toxalbumin (the ideal concentration is in reasonable range). Then, considering the problem of space utilization rate and the fact that <em>E.coli</em> can only grow on the surface of the medium, we changed the medium’s shape to sphericity to reach the highest space utilization percentage. Meanwhile, our device has been shaped to sphericity too, and the LED light has been moved to the center so that the whole surface can get the radiation evenly. A design like this enable us to use mini LED light bulb, and use solar energy instead of electricity as our power resource. This change fulfills our aim to save money and energy, which is also more economical and enviromentally friendly. |
| </p> | | </p> |
| <figure class="text-center"> | | <figure class="text-center"> |
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| </figcaption> | | </figcaption> |
| </figure> | | </figure> |
− | <p>We also made a video to show the inner structure of device 2.0. </p>
| |
| <video controls> | | <video controls> |
| <source src="https://static.igem.org/mediawiki/2015/9/95/BNU-MODELING-DEVICE2.0.mp4" type="video/mp4"> | | <source src="https://static.igem.org/mediawiki/2015/9/95/BNU-MODELING-DEVICE2.0.mp4" type="video/mp4"> |
| </video> | | </video> |
− | <p>As shown above, device 2.0 has two shells – outer shell and inner shell. There are tiny holes on the outer shell, which allow nematodes to enter the device. The holes are designed to block other soil organisms from entering. The red LED light can be supplied with the power from solar power pane, which will be put on the surface of the farmland. And we can achieve remote control by using radio technology. | + | <p>As shown above, device 2.0 has two shells – an outer shell and inner shell. There are tiny holes on the outer shell, which allow nematodes to enter the device. The holes are biosynthetically designed to prevent other soil organisms from entering. The red LED light can be supplied with the power from solar power pane, which will be put on the surface of the farmland. And we can achieve remote control by using radio technology. |
| </p> | | </p> |
| | | |
| <h2 id="simulation">Simulation <small>Modeling in farmland</small></h2> | | <h2 id="simulation">Simulation <small>Modeling in farmland</small></h2> |
− | <p>After we improved our device, we want to figure out how we can put our device into practice in farmland, and whether our device would be more efficient and economical than the methods used currently used in killing nematodes (crop-dusting mostly). In order to answer these two questions, especially the second one, we need to conduct a simulation of the movement of nematodes to determine the most suitable place in the farmland to place our device. Our modeling process is given below: | + | <p>With these improvements to our device, we want to figure out how we can put our technology into practice in farmland, and whether our device would be more efficient and economical than the methods used currently used in killing nematodes (crop-dusting mostly). In order to answer these two questions, especially the second one, we need to conduct a simulation of the movement of nematodes to determine the most suitable place in the farmland to place our device. Our modeling process is given below: |
| </p> | | </p> |
| <h3>Modeling assumptions | | <h3>Modeling assumptions |
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| <li>Engineering bacteria in our device are able to produce enough limonene as we need. | | <li>Engineering bacteria in our device are able to produce enough limonene as we need. |
| </li> | | </li> |
− | <li>The creeping speed of nematode is fixed as 290μm/ s. | + | <li>The creeping speed of nematode is fixed as 290 \(\mu\)m/ s. |
| </li> | | </li> |
| <li>Nematodes move on a 2D plane. Because the movement range of nematodes is within 10cm and the distance between two devices is much longer than 10cm, we can ignore the depth. | | <li>Nematodes move on a 2D plane. Because the movement range of nematodes is within 10cm and the distance between two devices is much longer than 10cm, we can ignore the depth. |
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| <h3>Explanation of symbols | | <h3>Explanation of symbols |
| </h3> | | </h3> |
| + | <h5>Table 1. Explanation of symbols</h5> |
| + | |
| <table class="table table-condensed "> | | <table class="table table-condensed "> |
| <tbody> | | <tbody> |
− | <tr>
| |
− | <th>Table 1. Explanation of symbols
| |
− | </th>
| |
| </tr> | | </tr> |
| <tr> | | <tr> |
− | <td>Symbol</td> | + | <th>Symbol</th> |
− | <td>Meaning | + | <th>Meaning |
− | </td> | + | </th> |
− | <td>Symbol</td> | + | <th>Symbol</th> |
− | <td>Meaning</td> | + | <th>Meaning</th> |
| </tr> | | </tr> |
| <tr> | | <tr> |
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| </tr> | | </tr> |
| <tr> | | <tr> |
− | <td>L</td> | + | <td>N</td> |
− | <td>The longest distance between nematodes and the equipment</td> | + | <td>Distance between two equipment</td> |
| <td>S</td> | | <td>S</td> |
| <td>Distance between two devices</td> | | <td>Distance between two devices</td> |
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| </h3> | | </h3> |
| | | |
| + | <h5>Table 2. Data sources</h5> |
| <table class="table table-condensed "> | | <table class="table table-condensed "> |
| <tbody> | | <tbody> |
| <tr> | | <tr> |
− | <th>Table 2. Data sources | + | <th>Variable</th> |
| + | <th>Value |
| </th> | | </th> |
− | </tr>
| + | <th>Symbol</th> |
− | <tr>
| + | |
− | <td>Variable</td>
| + | |
− | <td>Value
| + | |
− | </td>
| + | |
− | <td>Symbol</td> | + | |
| </tr> | | </tr> |
| <tr> | | <tr> |
| <td>Nematodes’ movement velocity</td> | | <td>Nematodes’ movement velocity</td> |
− | <td>290</td> | + | <td>290 \(\mu\)m/s</td> |
| <td>Xu J X, Deng X. Biological modeling of complex chemotaxis behaviors for <em>C. elegans</em> under speed regulation—a dynamic neural networks approach[J]. Journal of computational neuroscience, 2013, 35(1): 19-37.</td> | | <td>Xu J X, Deng X. Biological modeling of complex chemotaxis behaviors for <em>C. elegans</em> under speed regulation—a dynamic neural networks approach[J]. Journal of computational neuroscience, 2013, 35(1): 19-37.</td> |
| </tr> | | </tr> |
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| <td>Nematodes’ density</td> | | <td>Nematodes’ density</td> |
| <td>\(1.89 \times {10^6 m^3}\)</td> | | <td>\(1.89 \times {10^6 m^3}\)</td> |
− | <td>Junli Zhang. Distribution and identification of sweet potato, soybean and vegetables plant-parasitic nematodes species in Hebei Province[D][D]. ,2004.</td> | + | <td>Zhang JL. Distribution and identification of parasitic nematodes in sweet potato, soybean and vegetables in Hebei Province[D]. ,2004.</td> |
| </tr> | | </tr> |
| <tr> | | <tr> |
| <td>The lowest concentration</td> | | <td>The lowest concentration</td> |
| <td>\(99.3\space g/m^3\)</td> | | <td>\(99.3\space g/m^3\)</td> |
− | <td>Qiuhong Niu. New mechanism of attracting and killing nematodes by Bacillus nematocida B16. ,2009.</td> | + | <td>Niu QH. New mechanism of B16 Bacillus nematocida to attract and kill nematodes. Yunnan: Yunnan University, 2009.</td> |
| </tr> | | </tr> |
| <tr> | | <tr> |
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| <h3>Model solution | | <h3>Model solution |
| </h3> | | </h3> |
− | <p>Considering that we need to control the density of nematodes in a proper range, we hope to do this by killing all the mature nematodes within certain period of time under the identical condition. Because different species of nematodes have different life cycles, our attraction time vary. We define d as the half time of which nematodes grow from eggs to larvae. We plan to apply our “attract – and – kill” process in two rounds. We will attract nematodes into our device in time d and kill them in time d. We found that all nematodes are killed after two “slaughters”. Additionally, it takes time for nematodes to reach the device, so we can determine the distance between the devices we place according to the three-day-period and the crawl speed of nematodes. | + | <p>Considering that we need to control the density of nematodes in a proper range, we hope to do this by killing all the mature nematodes within certain period of time under the identical condition. Because different species of nematodes have different life cycles, our attraction times vary. We define <em>d</em> as the half time of which nematodes grow from eggs to larvae. We plan to apply our “attract – and – kill” process in two rounds. We will attract nematodes into our device in time <em>d</em> and kill them in time <em>d</em>. We found that all nematodes are killed after two “slaughters”. Additionally, it takes time for nematodes to reach the device, so we can determine the distance between the devices we place according to the three-day-period and the crawl speed of nematodes. |
| </p> | | </p> |
| | | |
| </p> | | </p> |
− | <p>$$L = V\times{T}$$</p> | + | <p>$$L = V \times {T}$$</p> |
| | | |
| <p>Let L be the longest distance between nematodes and the equipment, V is nematodes’ crawl speed, and T is time nematodes need to develop into adult. | | <p>Let L be the longest distance between nematodes and the equipment, V is nematodes’ crawl speed, and T is time nematodes need to develop into adult. |
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| <figure class="text-center"> | | <figure class="text-center"> |
| <img src="https://static.igem.org/mediawiki/2015/1/16/BNU-MODELING-DEMO.jpg" /> | | <img src="https://static.igem.org/mediawiki/2015/1/16/BNU-MODELING-DEMO.jpg" /> |
− | <figcaption>Fig.4 the schematic diagram of how we plan to put our device in farmland | + | <figcaption>Fig.4 The schematic diagram of how we plan to put our device in farmland |
| </figcaption> | | </figcaption> |
| </figure> | | </figure> |
− | <p>As shown above, the white circles represent the devices of colon bacillus, while the bigger circles represent diffusion, with the same odorousness in a circle. What’s more, squares ABCD are the simplified farmland. It’s obvious that in this farmland (do not consider points on the sides of the square), point F is the farthest point away from the four equipment. Based on the longest distance between nematodes and the equipment which has been acquired in the 1) question, | + | <p>As shown above, the white circles represent the devices of colon bacillus, while the bigger circles represent diffusion, with the same odorousness in a circle. What’s more, squares ABCD are the simplified farmland. It’s obvious that in this farmland (do not consider points on the sides of the square), point F is the farthest point away from the four equipment. Based on the longest distance between nematodes and the equipment which has been acquired in the first question, |
| </p> | | </p> |
− | <p class="text-center">we obtain:\(AB = {2\sqrt{2}EF} = D\)</p> | + | <p class="text-center">we obtain:\(AB = {2\sqrt{2}EF} = N\)</p> |
− | <p class="text-center">N is the distance between two equipment. | + | <p class="text-center"><em>N</em> is the distance between two equipment. |
| </p> | | </p> |
| <p>Then we get the results of the relationship between attraction time and distance between two devices: | | <p>Then we get the results of the relationship between attraction time and distance between two devices: |
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| <tbody> | | <tbody> |
| <tr> | | <tr> |
− | <td>Running Time of Attractant(Days)</td> | + | <th>Attraction time(Day)</th> |
− | <td>Distance between Divices</td> | + | <th>Distance between two divices(m)</th> |
| </tr> | | </tr> |
| <tr> | | <tr> |
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| <p>$$C_1 = C_0/4$$</p> | | <p>$$C_1 = C_0/4$$</p> |
| | | |
− | <p>C<sub>1</sub> is the superposed odorousness diffused from the device, C<sub>0</sub> is the lowest attractant concentration. | + | <p>Where C<sub>1</sub> is the superposed odorousness diffused from the device, C<sub>0</sub> is the lowest attractant concentration. |
| </p> | | </p> |
| | | |
− | <p>We get the 3-D gas diffusion model according to Fick Law, and then we simplify the question into 1-D situation according to isotropy. | + | <p>According to Fikc's Law, We obtain a 3-D gas diffusion model. Since the three dimensions have no difference between each other, we simplify the question into a 1-D situation according to isotropy. |
| </p> | | </p> |
| | | |
− | <p>According to the Fick’s Law, we get the 3-D gas diffusion model. Since the three dimension has no difference between each other, we simplify the question into 1-D situation according to isotropy. | + | <p>According to Fick’s Law, points out that during the process of unsteady diffusion, at a distance of <em>x</em> Since the three dimension has no difference between each other, we simplify the question into 1-D situation according to isotropy. |
| </p> | | </p> |
| <p>A brief introduction to the Fick’s Law: It points out that during the process of unsteady diffusion, at a distance of x, the change rate of concentration to time is equal to the negative value of the change rate of diffusion flux to distance. Its mathematical expression is as follows: | | <p>A brief introduction to the Fick’s Law: It points out that during the process of unsteady diffusion, at a distance of x, the change rate of concentration to time is equal to the negative value of the change rate of diffusion flux to distance. Its mathematical expression is as follows: |
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| <p>$$\frac{\partial C_{A}}{\partial t} = D_{A}\frac{\partial ^2 C_{A}}{\partial x^2}$$</p> | | <p>$$\frac{\partial C_{A}}{\partial t} = D_{A}\frac{\partial ^2 C_{A}}{\partial x^2}$$</p> |
| | | |
− | <p class="text-center">Boundary value condition is: C(t,0)==N | + | <p class="text-center">Boundary value condition is: <em>C(t,0)==N</em> |
| </p> | | </p> |
| | | |
− | <p>C(x,t) is the concentration at the distance of x from gas source in t, N0 is the concentration of gas source, D is the diffusion coefficient. | + | <p><em>C(x,t)</em> is the concentration at the distance of x from gas source in t, <em>N<sub>0</sub></em> is the concentration of gas source, <em>D</em> is the diffusion coefficient. |
| </p> | | </p> |
| | | |
| <p>According to the model above, we obtain the gas diffusion model in 3D. And according to the principle of isotropy, we simplify the problem in 1D. | | <p>According to the model above, we obtain the gas diffusion model in 3D. And according to the principle of isotropy, we simplify the problem in 1D. |
− | <p>Then we obtain the solution | + | <p>We then obtain the solution |
| </p> | | </p> |
| </p> | | </p> |
Line 256: |
Line 252: |
| <p>$$erf(x) = \frac{2}{\sqrt{\pi}}\int^{x}_{0}e^{-\lambda^{2}}d\lambda$$</p> | | <p>$$erf(x) = \frac{2}{\sqrt{\pi}}\int^{x}_{0}e^{-\lambda^{2}}d\lambda$$</p> |
| | | |
− | <p>Then we can obtain the arithmetic solution.</p> | + | <p>We may then can obtain the arithmetical solution.</p> |
| + | <figure class="text-center"><img src="https://static.igem.org/mediawiki/2015/f/f5/BNU-Farmland.png"> |
| + | <figcaption>Fig.5 The schematic diagram of Device 2.0 placement in farmland |
| + | </figcaption> |
| + | </figure> |
| <video controls> | | <video controls> |
| <source src="https://static.igem.org/mediawiki/2015/5/53/BNU-modeling-movement_simulation.mp4" type="video/mp4"> | | <source src="https://static.igem.org/mediawiki/2015/5/53/BNU-modeling-movement_simulation.mp4" type="video/mp4"> |
| </video> | | </video> |
− | <p>The explanations of simulation: In the video above, we built up a simulation model of the movement of nematode using the cellular automaton in MATLAB. It shows how nematode moves in a real farmland with the device. We built up a 301×301 matrix in MATLAB, in place of a 20m*20m piece of farmland. The proportion of virtual nematode and real nematode is 0.0084.</p> | + | <p>The explanations of simulation: In the video above, we built up a simulation model of the movement of nematodes using the cellular automaton in MATLAB. It shows how nematode moves in a real farmland with the device. We built up a 301×301 matrix in MATLAB, in place of a 20m×20m piece of farmland. The proportion of virtual nematode and real nematode is 0.0084.</p> |
− | <p>We assume that the nematode is distributed randomly at the beginning. The rules of the movement are as follows: | + | <p>The nematodes is distributed randomly at the beginning. The rules of the movement are as follows: |
| </p> | | </p> |
| <ol> | | <ol> |
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| </li> | | </li> |
| </ol> | | </ol> |
− | <p>We did the different simulation experiments with one device in the farmland and two devices in the farmland separately. | + | <p>We did the different simulation experiments with one device in the farmland and four devices in the farmland separately. |
| </p> | | </p> |
| <h2 id="database">Database</h2> | | <h2 id="database">Database</h2> |
− | <p>In order to apply our idea and method to kill more agricultural pests, we established a database, we hope to take a better use of the new environmental friendly method from the synthetic biology aspect and share it with researchers all over the world. Our database contains 3 daughter databases: attractant, pests and toxalbumins bases. We will update relevant information about the engineering bacteria we designed to kill the pests in our database. Currently, our database contains the biobrick we established in this project and the one established by team ZJU-CHINA. | + | <figure class="text-center"><img src="https://static.igem.org/mediawiki/2015/3/3d/BNU-DB.png"> |
| + | <figcaption>Fig 6. Homepage of our database website |
| + | </figcaption> |
| + | </figure> |
| + | <p>In order to apply our hypothesis and methodology to more agricultural pests control, we established a database, we hope to take a better use of this new environmental-friendly method from the context synthetic biology and share it with researchers all over the world. Our database contains 3 daughter databases: attractant, pests and toxalbumins bases. We will update relevant information about the engineering bacteria we designed to kill the pests in our database. Currently, our database contains the biobrick we established in this project and the one established by team ZJU-CHINA. |
| </p> | | </p> |
| <p>All the users have the permission to edit and add new contents, and we welcome everyone to use and enrich our database! | | <p>All the users have the permission to edit and add new contents, and we welcome everyone to use and enrich our database! |
| </p> | | </p> |
| <p class="text-center"> | | <p class="text-center"> |
− | Our link address is: | + | Our link address is: https://bnu-igem.herokuapp.com/ |
| </p> | | </p> |
| <p class="text-center">All the users have the permission to edit and add new contents, and we welcome everyone to use and enrich our database! | | <p class="text-center">All the users have the permission to edit and add new contents, and we welcome everyone to use and enrich our database! |
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| <img src="https://static.igem.org/mediawiki/2015/9/99/BNU-MODELING-SHARE.png" /> | | <img src="https://static.igem.org/mediawiki/2015/9/99/BNU-MODELING-SHARE.png" /> |
| </figure> | | </figure> |
| + | <div class="reference"> |
| + | <ol> |
| + | <li>Liang W, Li Q, Chen L, et al. Effects of elevated atmospheric CO2 on nematode trophic groups in a Chinese paddy-field ecosystem[J]. Ying yong sheng tai xue bao= The journal of applied ecology/Zhongguo sheng tai xue xue hui, Zhongguo ke xue yuan Shenyang ying yong sheng tai yan jiu suo zhu ban, 2002, 13(10): 1269-1272. |
| + | </li> |
| + | <li>Gaugler R, Lebeck L, Nakagaki B, et al. Orientation of the entomogenous nematode Neoaplectana carpocapsae to carbon dioxide[J]. Environmental Entomology, 1980, 9(5): 649-652. |
| + | </li> |
| + | <li>Yeates G W, Newton P C D, Ross D J. Response of soil nematode fauna to naturally elevated CO 2 levels influenced by soil pattern[J]. Nematology, 1999, 1(3): 285-293. |
| + | </li> |
| + | <li>Feng Z, Cronin C J, Wittig J H, et al. An imaging system for standardized quantitative analysis of C. elegans behavior[J]. BMC bioinformatics, 2004, 5(1): 115. |
| + | </li> |
| + | <li> Ye H Y, Ye B P, Wang D Y. Molecular control of memory in nematode Caenorhabditis elegans[J]. Neuroscience bulletin, 2008, 24(1): 49-55.</li> |
| + | <li>Li SQ. Study on biological characteristics and control of banana root knot nematodes[D]. Nanning: College of agriculture, Guangxi University, 2002. |
| + | </li> |
| + | </ol> |
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