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                <div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>No one knows since when did humans begin to attempt to domesticate honeybees, just like no one knows exactly how important these little creatures can be to human civilization and world environment. </div>

                <div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>Honeybees may be most famous for the stored honey they serve up, but there are a few more useful things they do as well. They produce beeswax, which gives us the manufactures of candles and many other sorts of products. They produce royal jelly, which is extremely famous for preserving people’s health. Moreover, they pollen plants, which is the most fundamental ecological process and makes everything in nature possible.</div>

                <div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>Today, in China, apiculture is a vital economic generator for the country, producing average 245,000 metric tons and estimating at 238,000 metric tons of consumption in honey per year. In America, it creates 210,000 direct jobs for people, and it is a crucial element of U.S agriculture, which relies on apiculture for pollination. it is impossible to define the economic value of apiculture.

According to a data released by Times, almost 1/3 of food of the world is dependent on honeybee’s pollination. If all the honeybees die out, thousands of plants will follow, which could leads to millions of people starving in the following years. </div>

                <div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>Einstein once said that’if all the bees die out, humans will follow a few years later.’  It is unsettling to inform you that, honeybees have started to disappear. In recent years，beekeepers have witnessed an annual 30% losses in their colonies. For the Europe alone, bees are greatly declining, from 5 million hives in 1988 to 2.5 million today. Since 2006, a phenomenon called Colony Collapse Disorder has spread to every corner of the world. We don’t exactly know what is causing it. The only thing we know is that it is pretty serious, and measures must be taken immediately.</div>

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                  <div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>Sacbrood Virus has been a scourge to apiculture over the world for almost half of a century. Sacbrood Virus is a typical RNA virus. It causes failure of larval pupation, and results in larval death. With SBV accumulating beneath larval skin, Infected larva changes in color from pearly white to pale yellow, forming a brown gondola-shaped scale after death. Different Sacbrood virus samples originate from various geographic regions. In China, it is classified as Chinese Sacbrood Virus (CSBV). According to a research from Jilin University, in some provinces of China, 60 percent of bee tribes carries CSBV, and the death rate of larvae is almost 100 percent during outbreaks. </div>

                <div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>CSBV is one of the main causes of the significant decrease of Chinese honeybee populations in the past 40 years. So far, no effective control method exists for this bee disease, besides the prevention strategy, the only one beekeepers adopting currently. FAFU-China team aims to investigate the possibility of controlling this disease through silence of CSBV’s RdRp (RNA-dependent RNA polymerase) gene by using RNA-interference technology.</div>

                <div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>The RNA-interference naturally exists in many eukaryotes, including honeybees. It plays an crucial role in defending somatic cells against viruses. The biological process is known for it’s ability to inhibit gene expression by causing the destruction or silence of specific messenger-RNA molecule.</div>

                <div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>Double-stranded ribonucleic acid (dsRNA) molecules is essential to RNA-interference. In the very beginning, the Dicer enzyme initiates the biological process by cleaving dsRNA into small interfering RNA (siRNA). Next, the small interfering RNAs are soon separated into two single strands. The positive-strand which is also known as guide-RNA is then integrated into an active RNA-induced silencing complex, RISC. RISC can bind to it’s target mRNA by base-pairing and cleave it, preventing the mRNA from producing a protein.</div>

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                <div><B>Theory<B></div>

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                <center><div><B>Replication of CSBV<B></div></center>

                <div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>As a typical RNA virus, CSBV’s replication process is initiated once the messenger RNAs of CSBV, which is CSBV’s original genetic information, are injected into somatic cells. However, a essential complex for the replication of genetic information of CSBV is lacked in the somatic cells of honeybees, RNA dependent RNA polymerase, RdRp in short. RdRp can be synthesized directly by ribosome of honeybees using mRNA of RdRp as temperate. With the existence of RdRp, the replication of genetic information of CSBV can be completed and CSBV will soon spread out infect the whole organism. </div>

                <div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>This year，FAFU-China aims to investigate the possibility of controlling this disease by inhibiting the expression of RdRp gene through RNA-interference.</div>

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                <center><div><B>CSBV.Silencer 1.0<B></div></center>

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                <div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>We designed a engineered bacteria capable of producing double-stranded RNA of RNA dependent RNA polymerase （RdRp）to initiate the process of RNA-interference. We inserted the RdRp gene into plasmid L4440, and inserted T7 promoters in the upstreams of both strands of the plasmid. two contemporary messenger-RNAs of RdRp can be synthesized simultaneously after T7 polymerases detect the promoters in both strands and start the transcription from 5 prime to 3 prime.</div>

                <div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>The contemporary messenger RNAs will then bind together into double stranded RNA by base-pairing. Long dsRNA of RdRp is then cleaved by Dicer enzyme and short small interfering RNA is formed. small interfering RNA will soon separate into two single strands. One is called passenger RNA, which is soon degraded. And the other strand called guide RNA will then integrated into an RNA Induced Silencing Complex, RISC in short. RISC then binds to the specific sequence of mRNA of RdRp and destruct it, thereby preventing it from being used as translation template to produce RdRp. </div>

                <div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>We transferred plasmid L4440 into E.coli so that dsRNA of RdRp can be largely produced. Then we mixed our product, CSBV.Silencer, into forage of honeybees, and feed it to infected hives. After the infected honeybees take in CSBV.Silencer, the replication process of CSBV in will be destructed in the somatic cells of honeybees, for the essential RdRp complex can not be formed. </div>

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                <center><div><B>CSBV.Silencer 2.0<B></div><center/>

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<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>On the basis of CSBV.Silencer 1.0, we decided to improve our product,out of two concerns. </div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>In the field of food industry, safety concern is always a sensitive problem. E.coli is always taken as  potential pathogen by consumers unconsciously，and because of that, we decided to replace E.coli by Yeast which originally exists in honey. </div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>If we want to transfer CSBV.Silencer into honeybees, we need to consider the influence imposed by immune system and digest system. We need to find a way to prevent our product from being degraded by immune cells and digestive solution. The need to enable the engineered bacteria getting through the digest system without being harmed also requires us to replace the E.coli by using eukaryote as carrier. </div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>However, if we want to use eukaryotic system to produce the dsRdRp, there is still a problem needed to be solved. In eukaryotic system, there is no T7 polymerase, which causes failure in transcription of L4440, leading dsRdRp unable to be synthesized. To solve this, we have another plasmid capable of producing T7 polymerase, PyES2. </div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>After galactose induces Gal1 promoter, activating RNA polymerase to transcript the gene of T7 RNA polymerase, mRNA of T7 RNA polymerase can be expressed and T7 polymerase is produced. the produced T7 polymerase can go back to the T7 promoter in the upstream, and continue making more T7 polymerases. The circulation of making T7 polymerase ensures the abundance of T7 polymerases, which actually accelerates the process of producing dsRdRp. </div>

                <div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>Our next product, CSBV·Silencer 2.0, will be the engineered yeast containing plasmid PyES2 and plasmid L4440. However, in this stage, we have only come up with the idea and are still trying to recombine the plasmid PyES2. As long as we have the recombined plasmid PyES2 ready, we will then transfer PyES2 and L4440 into yeast, and have our product applied to practice.</div>

                <div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>Meanwhile,we noticed that IPTG could induce the expression of dsRdRp in HT115, and galactose could improve the efficiency of GAL1 in eukaryotic system</div>

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                <center><div><B>Easier to spread<B></div><center/>

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                <div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>Eusocial insects like ants, honeybees, bumble, termites have the habit of cooperative care of young. The larvae in the family are unable to forage and feed themselves, and because of that, the food delivered by workers are essential. this habit enables CSBV.Silencer flow through the whole insect family rapidly.Through the mechanism, CSBV.Silencer can be diffused easily and the effect can be detected rapidly.</div>

                <div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>Similarly, the mechanism can be adopted in the prevention of other virus disease of eusocial insects or biological control. We are planning to develop a medicine of termite control through silence of certain gene. We predict that the medicine can be delivered with food throughout the whole colony, and achieve the purpose of pest control.</div>

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                <div style="text-align:left">Whole RNA Extraction</div>

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                <div style="text-align:left">We use Trizol to extract the whole RNA of CSBV,and the detail protocol is showed as bellow:</div>

                <div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>1.Take 50-100mg tissue stored in -80℃ or liquid nitrogen. Grind the tissue into powder in mortar with liquid nitrogen. Transfer the powder into a 1.5ml EP tube(RNase-Free).</div>

                <div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>2.Add 500μl Trizol, vortex to mix thoroughly and let the tube sit at room temperature for 10 min.</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>3.Centrifuge at 12,000 x g for 10 min at 4℃.Transfer the supernatant into a new 1.5ml EP tube(RNase-Free).</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>4.Add 100μl chloroform, vigorously shake with hand for 15s and then let the tube sit at room temperature for 10 min.</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>5.Centrifuge at 12,000 x g for 15 min at 4℃. Transfer the upper colourless aqueous phase into a new 1.5ml EP tube(RNase-Free).</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>6.Add 250μl isopropanol, turn the tube upside down many times for around 10 min, and let it sit at room temperature for 10 min until the white floccule arise,and then centrifuge at 12,000 x g for 10 min at 4℃.</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>7.Discard the supernatant,add 500μl,75%ethanol with DEPC,and mix thoroughly.Centrifuge at 7,500 x g for 5 min at 4℃ and discard the supernatant.</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>8.Dry it at room temperature or in the bechtop for 15 min.</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>9.Add 15-20μl RNase-Free water to dissolve RNA when the precipitate become transparent.</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>10.Store RNA at -80℃.</div>

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<div style="text-align:left">RT-PCR and PCR</div>

<div style="text-align:left">We amplify DNA of CSBV by RT-PCR and PCR. And the detail systems and programs are showed as bellow:</div>

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<div style="text-align:left">1.RT-PCR（using M-MLV Reserve Transcriptase kit bought from Promega company</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:350px;"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>Component</span>Volume(μl)</div><!--有问题，4,4,2，要跟volume对齐。-->

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:350px;"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>Whole RNA of CSBV</span>4.0</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:350px;"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>dNTP Mixture(10mM)</span>4.0</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:350px;"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>Reserve primer</span>2.0</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:350px;"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>70℃ pre-denaturation</span>10min</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:350px;"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>Component(add in order) </span>Volume(μl)</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:350px;"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>5×M-MuLV buffer</span>4.0</div>  <!--版面啊版面啊版面啊。-->

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:350px;"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>RNase free water</span>4.5</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:350px;"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>M-MLV Reserve Transcriptase</span>1.0</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:350px;"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>42℃</span>1h</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:350px;"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>72℃</span>15mins</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>Store cDNA at -20℃</div>

<div style="text-align:left">2.PCR</div>

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<div style="text-align:left">(1)System(50μl)</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:350px;"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>10×PCR Buffer</span>5.0μl</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:350px;"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>Template(cDNA)</span>2.0μl</div>

<div style="text-align:left">We use GoTaq? qPCR Master Mix Kit(buy from Promega company) and Eppendrof Mastercycler? ep realplex Real-Time PCR to do qPCR.</div>

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<div style="text-align:left">(1)System(20μl)</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:350px;"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>SYBR Premix Ex TaqTM  2×mix</span>10.0μl</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:350px;"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>Template(cDNA)</span>1.0μl</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:350px;"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>Primer F</span>0.4μl</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:350px;"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>Primer R</span>0.4μl</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:350px;"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>RNase-Free water</span>8.2μl</div>

<div style="text-align:left"><span style="display:-moz-inline-box; display:inline-block; width:350px;"><span style="display:-moz-inline-box; display:inline-block; width:25px;"></span>Volume</span>20.0μl</div>

<div style="text-align:left">(2)Program </div>

<div style="text-align:left">We use E.Z.N.A. Plasmid DNA Mini Kit I bought from OMEGA bio-tek company to <div style="text-align:left">extract plasmids and the detail protocol is showed as bellow:</div>

<div style="text-align:left">5. Transfer suspension into a new 1.5 mL microcentrifuge tube.</div>

<div style="text-align:left">6. Add 250 mL Solution II. Invert and gently rotate the tube several times to obtain a clear lysate. A 2-3 minute incubation may be necessary.(Avoid vigorous mixing)</div>

<div style="text-align:left">8. Centrifuge at maximum speed (≥13,000 x g) for 10 minutes. A compact white pellet will form. Promptly proceed to the next step.</div>

<div style="text-align:left">9. Insert a HiBind DNA Mini Column into a 2 mL Collection Tube.</div>

<div style="text-align:left">10. Transfer the cleared supernatant from Step 8 by CAREFULLY aspirating it into the HiBind DNA Mini Column. Be careful not to disturb the pellet and that no cellular debris is transferred to the HiBind DNA Mini Column.</div>

<div style="text-align:left">11. Centrifuge at maximum speed for 1 minute.</div>

<div style="text-align:left">12. Discard the filtrate and reuse the collection tube. </div>

<div style="text-align:left">13. Add 500 mL HB Buffer.</div>

<div style="text-align:left">14. Centrifuge at maximum speed for 1 minute.</div>

<div style="text-align:left">15. Discard the filtrate and reuse collection tube.</div>

<div style="text-align:left">16. Add 700 mL DNA Wash Buffer.</div>

<div style="text-align:left">17. Centrifuge at maximum speed for 1 minute.</div>

<div style="text-align:left">18. Discard the filtrate and reuse the collection tube.</div>

<div style="text-align:left">19. Centrifuge the empty HiBind DNA Mini Column for 2 minutes at maximum speed to dry the column matrix. </div>

<div style="text-align:left">20. Transfer the HiBind DNA Mini Column to a clean 1.5 mL microcentrifuge tube.</div>

<div style="text-align:left">21. Add 30-100 μl Elution Buffer or sterile deionized water directly to the center of the column membrane.</div>

<div style="text-align:left">22. Let sit at room temperature for 1 minute.</div>

<div style="text-align:left">23. Centrifuge at maximum speed for 1 minute.</div>

<div style="text-align:left">We use E.Z.N.A. Gel Extraction Kit bought from OMEGA bio-tek company to recover our target fragments after AGE and the detail protocol is showed as bellow:</div>

<div style="text-align:left">1. Perform agarose gel/ethidium bromide electrophoresis to fractionate DNA fragments. Any type or grade of agarose may be used. However, it is strongly recommended that fresh TAE buffer or TBE buffer be used as running buffer. Do not reuse running buffer as its pH will increase and reduce yields. </div>

<div style="text-align:left">2. When adequate separation of bands has occurred, carefully excise the DNA fragment of interest using a wide, clean, sharp scalpel. Minimize the size of the gel slice by removing extra agarose.</div>

<div style="text-align:left">3. Determine the appropriate volume of the gel slice by weighing it in a clean 1.5 mL microcentrifuge tube. Assuming a density of 1 g/mL, the volume of gel is derived as follows: a gel slice of mass 0.3 g will have a volume of 0.3 mL.</div>

<div style="text-align:left">4. Add 1 volume Binding Buffer (XP2).</div>

<div style="text-align:left">5. Incubate at 60°C for 7 minutes or until the gel has completely melted. Vortex or shake the tube every 2-3 minutes.</div>

 

 

 

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                <center><div>CSBV.Silencer 2.0</center>

 

 

 

<div id="Notebook"></div>

 

 

 

 

 

                <div style="text-align:left">Today we made RT-PCR with four sets of reverse specific primers and the RNA of CSBV to synthesize homologous cDNA(CSBV Helicase、Protease、VP1 and RdRp respectively). Then dsDNAs was amplified with four sets of specific primers by PCR. It went through smoothly. So far, we got the target fragments successfully. Also,we used GFP F/R to amplify GFP gene. </div>

 

              <center><div>2015.6.10</div></center>

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                <div style="text-align:left">We utilized T7 RiboMAXTM Express RNAi System kit and dsDNAs as templates to synthesize dsRNAs(dsHelicase、dsProtease、dsVP1、dsRdRp and dsGFP), but there were only dsHelicase and dsGFP we could get. We tried again and still failed. It took our whole day to find the reason. Tomorrow we will ask our advisor for some solutions and do it one more time.</div>

                <center><div>2015.6.12</div></center>

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                <div style="text-align:left">After figuring out the problem, we eventually got the all right dsRNAs. Another part, we began to prepare the larvae of Chinese honeybee which was offered by our institute of bees.

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                <div style="text-align:left">We put dsRNAs into fodder of the larvae of the honeybee to feed them. Then after 12h, we fed them another fodder with CSBV extracting solution. We did so twice before they got normal fodder. </div>

                  <center><div>2015.6.17</div></center>

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                <div style="text-align:left">During three days, we observed the change of percentage of pupation and collect and analyse data. Meanwhile,RT-qPCR was done to detect the effect of different dsRNAs to CSBV. According to the result, we found that dsRdRp made a remarkable influence on the replication of CSBV. So we decided to use dsRdRp to inference CSBV.</div>

                <center><div>2015.6.19</div></center>

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                <div style="text-align:left">We used cDNA of RdRp and specific primers(Not1-F/Pst1-R、EcoR1-F/Pst1-R) to synthesize RdRp gene. However, after agarose gel electrophoresis(AGE), we could not find our target fragment.</div>

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                <div style="text-align:left">We changed a better DNA polymerase and set the annealing temperature to 60℃. Finally we got the RdRp gene.</div>

                <div style="text-align:left">We picked the colonies to do PCR and sent the positive sequencing(M13).</div>

                <div style="text-align:left">Today we got the result of sequencing. After comparing with data in NCBI, we only had two 100 percent samples.

We started to do double enzyme digestion(Not1 and Pst1、EcoR1 and Pst1) to cut vector L4440、pSB1C3 and RdRp-T recombinant plasmid.

                <div style="text-align:left">We made RdRp gene link with T vector in 25℃, 15min and then transformed it into DH5α,a kind of competent cell, which was cultured in 37℃,overnight.</div>

                <div style="text-align:left">We made it! And we immediately did gel recovery. Then we began to link RdRp with L4440 and pSB1C3 using T4 ligase, 4℃, overnight.

                <div style="text-align:left">We did transformation. However,we forgot to make LB medium with CmRR. So the transformation of RdRp-pSB1C3 could only be done tomorrow.

                <div style="text-align:left">Today there was two news. The good one was we successfully got recombinant plasmid RdRp-L4440 while the bad one was nothing grew on the plate with CmRR. We thought maybe it was because RdRp did not link with pSB1C3 successfully. Anyway we would do it again tomorrow.

                <div style="text-align:left">On the one hand, we still could not link RdRp with pSB1C3 so that there still nothing on the plate. We wonder if it was because of the efficiency of ligase or anything.

                <div style="text-align:left">Today we decided to constract RdRp-pSB1C3 again, because we thought T7 RNAP-pSB1C3 may be not a new part any more. So, we did linking. We decided if it is failed just like before this time. We had to change T4 into a faster ligase..</div>

                <center><div>2015.7.29</div></center>

 

 

 

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