Difference between revisions of "Team:CPU CHINA/Demonstrate"

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<h1 style="font-size:2.3rem;text-align:center">"The AND gate is a basic digital logic gate that implements logical conjunction. A HIGH output (1) results only if all the inputs to the AND gate are HIGH (1)."</h1>
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<h3 style="text-align:right;font-size:2rem;">——Wikipedia</h3>
 
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     I am <i>Promoter Hulc!</i> Click me!
 
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<h1>A gene therapy strategy to target hepatocellular carcinoma based on conditional RNA interference
 
<h1>A gene therapy strategy to target hepatocellular carcinoma based on conditional RNA interference
 
<h2>1.Description
 
<h2>1.Description
<h4>As described in the Background page, we know spatial and/or temporal regulation of RNAi is of significant importance for basic research as well as practical applications of RNAi. For this reason, we design a gene therapy strategy to target hepatocellular carcinoma based on conditional RNA interference.
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<h3>1.1 Key procedures</h3>
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<h4>As described in <a href="https://2018.igem.org/Team:CPU_CHINA/Background"><u>Background</u></a> , spatial and/or temporal regulation of RNAi is of significant importance for basic research as well as practical applications. Since disease-specific promoters only have high activity in pathogenic cells, our RNAi becomes conditional and specific for pathogenic cells as we put genes of the RdRp and non-coding RNAs behind them (Figure 1). When the two devices become transcriptionally activated together, RNA interference occurs. This actually forms a logical “AND” gate - it behaves according to the truth table on the right.
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<h4>As shown in the following figure, there are <b>three key procedures</b> in our conditional RNAi gene therapy:
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<center><image src=https://static.igem.org/mediawiki/2018/e/ec/T--CPU_CHINA--hp-demonstrate1.png></image></center>
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<h4>A. Drosha can’t cleavage pri-miRNA (green) which is bind with the inhibitory strand (yellow) in this stage, with no RNAi (Figure A).
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<h4>B. SLD3, a short template competent for RNA synthesis by NS5B, is located in the 3’end of the inhibitory strand. NS5B, as the RNA dependent RNA polymerase, can interact with the 2’-OH and 3’-OH of the two base cytosines in the 3’end of the SLD3. And then, RNA synthesis, inhibitory strand as template, will happen. NS5B separates the inhibitory strand from the pri-miRNA and the latter will be cleavaged by Drosha and Dicer successively (Figure B).
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<center><image src=https://static.igem.org/mediawiki/2018/e/e5/T--CPU_CHINA--hp-demonstrate2.png></image></center>
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<h4>C. For Tet-off system, when tetracycline (Tc) or Doxycycline (Dox) is absence, transcription factor tTA will bind to transcription activator TRE, which will activate downstream--miRNA sponge expression. MiRNA sponge will absorb the miRNA targeting MAP4K4 to block RNAi. When Tc or Dox is present, they will bind to tTA which leads to conformation exchange of this protein, thus will not bind to TRE, which result in non-coding of downstream genes (Figure C).
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<h3>1.2 Features</h3>
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<center><img src="https://static.igem.org/mediawiki/2018/9/9b/T--CPU_CHINA--DEMO-1.png"></center>
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<center><h5>Figure 1. The “AND” gate based on disease-specific promoters</h5></center>
<h4><b>1.2.1 Cancer-specific promoters</b></h4>
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<h4>Our gene therapy strategy utilize two cancer-specific promoters (one HCC-specific) to open an AND-gated system to target HCC, the selectivity supposed to be extremely high.
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<h4>HTERT is the core promoter of human telomerase reverse transcriptase (hTERT) gene. It’s one of the most known cancer-specific promoters. A number of factors, like c-Myc, HIF-1, regulate the hTERT promoter, most of which comprise tumor suppressor gene products.
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<h4>Long non-coding RNA (lncRNA), highly up-regulated in liver cancer(Hulc) plays an important role in
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tumorigenesis,is one of the most up-regulated genes in hepatocellular carcinoma.Hulc promote is acutually the core promoter of this gene. 
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<h4>Hence, Only tumor cells (malignant ones especially) can express NS5B and “open” the AND gate, releasing miRNA that damage themselves.
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<h4><b>1.2.2 Controlled by small molecule</b></h4>
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<h3>1.1 Key procedures
<h4>Our gene therapy strategy is controlled by a small molecule.
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<h4>As we mentioned above, tet-off system adjust the coding of miRNA sponge. This system is highly specific, the level of gene expression induced by it is relative to the dosage of the inducer and time, which can make adjusting the design accurately come true and is safety when we apply it in human.  
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<h4>DROSHA can’t cleave pri-miRNA (green) when the latter binds with the inhibitory strand (yellow), which means no RNAi (Figure 2A).  
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<h4>SLD3 is a short template competent for <i>de novo</i> RNA synthesis. It is located at the 3’ end of the inhibitory strand. NS5B, the RNA dependent RNA polymerase, interacts with the 2’-OH and 3’-OH of the two cytosines at the 3’ end of the SLD3 sequence, then starts RNA polymerization using the RNA promoter and the inhibitory strand as the template. It separates the inhibitory strand from the pri-miRNA, exposing the single-stranded area. The Microprocessor then recognizes this substrate and cleaves it into precursor miRNAs, which eventually would become mature miRNAs (Figure 2B).
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<h4><b>1.2.3 Apply on other disease</b></h4>
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<center><img src="https://static.igem.org/mediawiki/2018/3/3c/T--CPU_CHINA--DEMO-2.1.png"></center>
<h4>Our gene therapy strategy has the flexibility to be adapted to target any mRNA and, if there are disease-specific promoters, other diseases.
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<h4>Remarkably, such disease-specific approach would be suitable other diseases. Not only the target can be any messenger RNA. But also the promoters (“keys” to the AND gate) here can be replaced with other disease-specific promoters, in gene therapy for the corresponding diseases.
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<h3>1.3 Plasmids construction</h3>
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<center><img src="https://static.igem.org/mediawiki/2018/c/c3/T--CPU_CHINA--DEMO-2.2.png"></center>
<h4>PlasmidⅠincluding hTERT promoter activate transactivation protein tTA for TRE promoter and NS5B to separate pri-miRNA and inhibitory strand. We load a nuclear location sequence (NLS) to the N terminal of NS5B (NS5B<sup>NLS</sup>) to transport the RdRP into the nucleus to duplicate the inhibitory strand and release pri-miRNA.
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<center><h5>Figure 2. The key procedures of the design</h5></center>
<h4>PlasmidⅡcontains HULC promoter, pri-miRNA to silence MAP4K4 and the inhibitory strand of pri-miRNA. If the parts work, the pri-miRNA will not processed further because the combination of inhibitory strand.
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<h4>tTA, Tet with downstream sponge are located in these two plasmids separately. Under the control of Tc or Dox, the two prats can regulate the expression of sponge. Sponge will regulate the miRNA targeting MAP4K4 to influence the level of MAP4K4 translation.
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<center><image src=https://static.igem.org/mediawiki/2018/f/fd/T--CPU_CHINA--hp-demonstrate0.png></image></center>
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<h2>2.Results</h2>
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<h4>In the Tet-off system (Figure 2C), when Tetracycline (Tc) or Doxycycline (Dox) is absent, tetracycline transactivator (tTA) binds with the tetracycline response element (TRE), which then activates the downstream gene expression of a miRNA sponge. MiRNA sponge absorbs the miRNA targeting MAP4K4 to again block the RNAi pathway. When Tc or Dox is present, tTA changes its conformation to bind with them, thus preventing the downstream genes from expression.
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<h4>To engineer our parts, we chose pIRES and pcDNA3.1 as backbones for the plasmidⅠandⅡvectors, respectively. And we constructed the plasmids containing partial parts to detect the function of system. Here the plasmids we used involed p1 (pIRES-hTERT-tTA-NS5B<sup>NLS</sup>), p-H (pcDNA3.1-HULC-pri-miRNA(MAP4K4)), p-H* (pcDNA3.1-HULC- hulc-pri-miRNA), p-H-U6 (pcDNA3.1-HULC-pri-miRNA(MAP4K4)-U6-inhSi-pri-miRNA), p-H*-U6 (pcDNA3.1-HULC-pri-miRNA-U6-inhSi-pri-miRNA) and p2 (pcDNA3.1-HULC-pri-miRNA(MAP4K4)-U6-inhSi-pri-miRNA-tre-sponge).
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<h3>2.1 Determine the activity of the promoters
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<h4>To improve the selectivity of our therapy system, we utilize hTERT, the cancer-specific promoter, and HULC, the HCC-specific promoter, to open an AND-gated system to target HCC. pGL3-Basic vector is a promoterless vector for measuring the activity of promoter with a luciferase assay. We  determined the activity of the two promoters by it.
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<center><image style="width:40% !important" src=https://static.igem.org/mediawiki/2018/3/31/T--CPU_CHINA--hp-demonstrate4.png></image></center>
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<h5><center>Figure1. The activity of the promoters</center></h5>
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<h3>2.2 Function verifiction of NS5B
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<h3>1.2 Features
<h4>We applied indirect immunofluorescence to prove the expression (Figure2 A) and nuclear translocation (Figure2 B) of NS5B<sup>NLS</sup>.
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<center><image style="width:40% !important" src=https://static.igem.org/mediawiki/2018/1/1e/T--CPU_CHINA--hp-demonstrate5.png></image></center>
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<h5><center>Figure2. The expression and nuclear translocation of NS5B<sup>NLS</sup></center></h5>
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<b><h4>1.2.1 Cancer-specific promoters</b>
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<h4>Our gene therapy strategy utilizes two cancer-specific promoters (one HCC specific) to open an AND-gated system to target HCC.
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<h4><i>hTERT</i> promoter is the core promoter of human telomerase reverse transcriptase gene. It is one of the most well-known cancer-specific promoters. A number of factors like cellular transcriptional activator c-Myc, HIF-1 as well as the repressors p53, WT1, and Menin, most of which comprise tumor suppressor gene products, have been identified to directly or indirectly regulate the hTERT promoter, contributing its exclusive up-regulation in cancer.
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<h4><i>HULC</i> encodes a long non-coding RNA (lncRNA) and plays an important role in tumorigenesis. It is one of the most up-regulated genes in hepatocellular carcinoma and such activation, like the one for <i>hTERT</i>, is at transcriptional level. Here we only use a 132bp <i>HULC</i> core promoter because literature suggests that the most proximal 84nt of the <i>Hulc</i> gene contains several transcription factor binding sites and is capable of initiating transcription just fine.
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<h4>When these two promoters work together, which only happens in tumor cells (especially malignant ones), the AND gate is “opened”, releasing miRNA and damaging themselves.
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<b><h4>1.2.2 Controlled by small molecules</b>
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<h4>Our gene therapy strategy can be controlled by a small-molecule drug.
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<h4>As we mentioned above, the Tet-off system can also adjust the amount of functional miRNA, which should be instructive for individual drug administration <i>in vivo</i>.
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<b><h4>1.2.3 Wide application on other diseases</b>
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<h4>The gene therapy strategy shown here is actually a proof of concept. As a RNA interference strategy, it has its inherent flexibility to be adapted to target any messenger RNAs and to other disease settings as long as there are corresponding disease-specific promoters. This is discussed in detail in <i>Application</i>(link) page.
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<h3>1.3 Plasmid construction
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<h4>PlasmidⅠcontains <i>hTERT</i> promoter, transactivator <i>tTA</i> and RNA dependent RNA polymerase <i>NS5B</i>. We loaded a nuclear location sequence (NLS) to NS5B (NS5B<sup>NLS</sup>) for this protein to be transported into the nucleus. PlasmidⅡcontains the HULC promoter, genes encoding the pri-miRNA and the inhibitory strand. Notably, <i>tTA</i> and <i>TRE</i> are located separately in two plasmids (Figure 3). More information can be found in <a href="https://2018.igem.org/Team:CPU_CHINA/Parts"><u><i>Part</i></u></a>.
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<center><image src="https://static.igem.org/mediawiki/2018/4/48/T--CPU_CHINA--DEMO-3.png"></center>
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<center><h5>Figure 3. Plasmid construction of our system</h5></center>
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<h2>2.Results
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<h4>To apply our parts, we chose pIRES and pcDNA3.1 as backbones for the plasmidⅠandⅡ vectors, respectively. But before connecting all the parts, we constructed plasmids containing only some of the parts to verify the proper function of each part. Here the plasmids we used involve p1 (pIRES-hTERT-tTA-NS5B<sup>NLS</sup>), p-H(pcDNA3.1-HULC-pri-miRNA), p-H-U6(pcDNA3.1-HULC-pri-miRNA-U6-inhSi-pri-miRNA), and p2 (pcDNA3.1-HULC-pri-miRNA(MAP4K4)-U6-inhSi-pri-miRNA-tre-sponge).
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<h3>2.1 Determine the promoters’ activity and specificity
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<h4>Our system includes two specific promoters: <i>hTERT</i> and <i>HULC</i>. We used pGL3-Basic vector, a promoter-less vector for the luciferase assay to determine the transcriptional activity of these <a href="https://2018.igem.org/Team:CPU_CHINA/Experiments?promoters=1"><u>promoters</u></a>. We added the promoters on pGL3-Basic vector and measure the OD value of the luciferase activity. We chose SV40, a highly activated promoter in both cancer cells (Figure 4A) and normal cells (Figure 4B) as positive control (PGL3-CON).
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<center><img src="https://static.igem.org/mediawiki/2018/6/64/T--CPU_CHINA--DEMO-4.png"></center>
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<center><h5>Figure 4. The efficacy and specificity of the cancer-specific promoters</h5></center>
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<h3>2.2 Function verification of NS5B
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<h4>Successful expression of NS5B<sup>NLS</sup> of p1 is first verified by western blot (data now shown). In Figure 5, the results of <a href="https://2018.igem.org/Team:CPU_CHINA/Experiments?IF=1"><u>immuno-fluorescence</a></u> shows the ability of nuclear translocation of NS5B<sup>NLS</sup> has improved. (See detailed information in <a href="https://2018.igem.org/Team:CPU_CHINA/Improve"><u><i>Improve</i></a></u>)
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<center><img src="https://static.igem.org/mediawiki/2018/6/6a/T--CPU_CHINA--DEMO-5.png" ></center>
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<center><h5>Figure 5. Location of NS5B</h5></center>
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<h3>2.3 Conditional RNA interference
 
<h3>2.3 Conditional RNA interference
<h4>To test the kill ability of this conditional RNA interference system, MTT assay was involved. The effect was obvious when introduced two plasmids to the cells under the control of Tetracycline (Tc) (Figure3 A).
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<center><image style="width:40% !important" src=https://static.igem.org/mediawiki/2018/0/01/T--CPU_CHINA--hp-demonstrate6.png></image></center>
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<h5><center>Figure3. MTT Assay</center></h5>
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<h4>To test the efficiency of our system, we performed quantitative <a href="https://2018.igem.org/Team:CPU_CHINA/Experiments?qPCR=1">PCR (qPCR)</a> on the effector miRNA and the targeted MAP4K4 <u>mRNA</u>(Figure 6A). Pri-miRNA analogue was successfully encoded and processed into miRNA, however, with the presence of the inhibitory strand, the amount of miRNA sharply decreased since DROSHA cannot cleave the pri-miRNA. This can be further confirmed in Figure 6B where a significant increase of mRNA was observed after expression of the inhibitory strand, which also indicates that our miRNA can successfully target MAP4K4.
<h4>To analysis the quantity of miRNA and its silencing effect to MAP4K4 mRNA, Real-time Quantitative Polymerase Chain Reaction (QPCR) was preformed. When the inhibitory strand worked, the expression of miRNA(MAP4K4) was reduced (Figure4 A) and MAP4K4 mRNA was increased (Figure4 B). As expected, when the two plasmids worked, MAP4K4 mRNA was increased (Figure4 B) because sponge could absorb the miRNA(MAP4K4).
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<h4>However, from Figure 6A and 7B we found that NS5B did not function as expected, the inhibitory strand hardly removed. Taken from the results discussed above this might be due to insufficient presence of NS5B in the nucleus. However, the efficiency of nucleus translocation can be improved with e.g. adding two NLSs, thus our system might still work. Efforts will be paid regarding this issue in the future.
<center><image style="width:60% !important" src=https://static.igem.org/mediawiki/2018/0/0a/T--CPU_CHINA--hp-demonstrate7.png></image></center>
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<h5><center>Figure4. The expression of miRNA(MAP4K4) (A) and MAP4K4 mRNA (B)</center></h5>
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<center><image src="https://static.igem.org/mediawiki/2018/c/c8/T--CPU_CHINA--DEMO-6.png"></center>
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<center><h5>Figure 6. The expression of miRNA(MAP4K4) (A) and MAP4K4 mRNA (B)</h5></center>
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<h4>For the Tet-off system, when the two plasmids worked together, we saw an increase of MAP4K4 mRNA (Figure 6B), which indicates successful down-regulation of the miRNA by the miRNA sponge.
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        <h3>References</h3>
 
<h5>[1] Cai, X., Hagedorn, C. H., & Cullen, B. R. (2004). Human micrornas are processed from capped, polyadenylated transcripts that can also function as mrnas. <i>RNA, 10</i>(12), 1957.
 
<h5>[1] Cai, X., Hagedorn, C. H., & Cullen, B. R. (2004). Human micrornas are processed from capped, polyadenylated transcripts that can also function as mrnas. <i>RNA, 10</i>(12), 1957.
 
<h5>[2] Amuthan, G. (2004). The microprocessor complex mediates the genesis of micrornas. <i>Nature, 432</i>(7014), 235-40.
 
<h5>[2] Amuthan, G. (2004). The microprocessor complex mediates the genesis of micrornas. <i>Nature, 432</i>(7014), 235-40.
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<h5>[13] Lee, K. J., Choi, J., Ou, J. H., & Lai, M. M. (2004). The c-terminal transmembrane domain of hepatitis c virus (hcv) rna polymerase is essential for hcv replication in vivo. <i>Journal of Virology, 78</i>(7), 3797.
 
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Latest revision as of 03:58, 8 December 2018

"The AND gate is a basic digital logic gate that implements logical conjunction. A HIGH output (1) results only if all the inputs to the AND gate are HIGH (1)."

——Wikipedia

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