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- | {| style="color:#1b2c8a;background-color:#0c6;" cellpadding="3" cellspacing="1" border="1" bordercolor="#fff" width="100%" align="center"
| + | Dude, right on there broreht. http://unmpfo.com [url=http://fvjkubo.com]fvjkubo[/url] [link=http://uwegjh.com]uwegjh[/link] |
- | !align="center"|[[Team:Tsinghua|HOME]]
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- | !align="center"|[[Team:Tsinghua/Team|Team]]
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- | !align="center"|[[Team:Tsinghua/Project|Project 1]]
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- | !align="center"|[[Team:Tsinghua/Project2|Project 2]]
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- | !align="center"|[[Team:Tsinghua/Parts|Parts]]
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- | !align="center"|[[Team:Tsinghua/Modelling|Modelling]]
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- | !align="center"|[[Team:Tsinghua/Notebook|Notebook]]
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- | !align="center"|[[Team:Tsinghua/Doodle|Doodle Board]]
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- | |}
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- | | + | |
- | == '''CdLocalizer''' ==
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- | '''Pathway'''
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- | How CI and Cd sensor work?
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- | [[Image:CdCI.jpeg]]
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- | Our construct
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- | [[Image:construct.jpeg]]
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- | | + | |
- | '''Experimental Procedure'''
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- | '''1. Reconstruct pUC18 plasmid, insert GFP to the downstream of lac promoter'''
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- |
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- | 1.1 Use touchdown PCR to amplify GFP and add degradation tag and terminator.
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- | Primers:
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- | Forward: 5’- GA GAATTC G AGCAAGGGCGAGGAGCTGTTCACCG -3’
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- | Reverse: 5’- CTTG CCCGGG TTATCACTTGTACAGCTCGTCCATGC -3’
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- | (''Template: provide by Guoqiang Chen’s lab in Tsinghua University'')
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- | 1.2 Cut pUC18 plasmid with EcoR I and KpnI. Purify the cut pUC18 from agarose gel with Kit.
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- | 1.3 Purify the PCR product GFP from agarose gel with Kit and cut with EcoR I and Kpn I.
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- | 1.4 Purify the cut GFP with column.
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- | 1.5 Run a gel to compare the concentrations of the fragment and vector in order to decide their volume in the ligation mixture.
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- | 1.6 Incubate the ligation mixture at 16 degree.
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- | 1.7 Use 10μl ligation mixture to transform 200μl DH5αcompetent cell, spread on the LB plate(Amp), and incubate at 37 degree over night.
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- | 1.8 Pick three clone to 5ml LB and shake at 37 degree for 12h, miniprep the reconstruct plasmid.
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- | 1.9 We sequenced the inserted part and it was right.
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- | '''2. Synthesize the Nde I-Pm(complementary chain)-Pst I-Xba I-cad-Spe I-RBS(strong)-CI+LVA tag-Sac II-T1, T2-BamH I (the Blue part is the synthesis sequence) sequence. We use synthesis because we cannot use PCR to get the sequence from Staphyloccocus aureus Rosenbach'''
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- | '''3. Insert CheZ(with tag and terminator) into the reconstruct pUC18(with GFP)'''
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- | 3.1 Extract the genome of E.coli DH5αstrain and use PCR amplify CheZ from it.
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- | Forward primer:
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- | 5’-GTCATGCC CA TATG CAACCATCAATCAAACCTGC-3’
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- | Reverse primer:
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- | 5’-AT AGG CCT AAATCCAAGACTATCCAACAAATCGTCCACCTGATC-3’
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- | 3.2 Purify the PCR product from gel and then cut with Nde I
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- | 3.3 Cut the pAcYc duet-1 plasmid with EcoR V and Nde I
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- | 3.4 Run a gel to compare the concentration of the vector and insertion in order to decide the their volumes in the ligation mixture
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- | 3.5 Ligate the vector and the cheZ, transformate DH5α and spread the LB plate(Chl).
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- | 3.6 Pick three clones to 5ml LB(Chl) and shake at 37 for 12h, then miniprep the reconstruct the plasmid.
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- | 3.7 Synthesize the Stu I-tag-Hind III-T0/T1T2-AatII sequence (with stick end), which contains CheZ’s tag and terminator. We firstly synthesized the sequence as two single strings, and then annealing them together as a double string DNA.
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- | The two single strings’ sequence is below:
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- | Forward
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- | 5’-CCT GCTGCAAACGACGAAAACTACGCTTTAGTAGCT TAA A AGCTT
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- | Stu I end LVA tag stop codon Hind III
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- | CGCAAAAAACCCCGCTTCGGCGGGGTTTTTTCGC GACGT-3’
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- | T0 Aat II end
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- | Reverse
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- | 5’- C GCGAAAAAACCCCGCCGAAGCGGGGTTTTTTGCG A AGCTT TTA
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- | Aat II end T0 Hind III stop codon
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- | (complementary)
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- | AGCTACTAAAGCGTAGTTTTCGTCGTTTGCAGC AGG
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- | LVA tag (complementary) Stu I end
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- | 3.8 Cut the pAcYcduet-1-cheZ plasmid with StuI and Aat II and column purify the vector
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- | 3.9 Run a gel to compare the concentration of the vector(pAcYcduet-1-cheZ) and insertion (Stu I-tag-Hind III-T0/T1T2-AatII) to make sure their volumes in the ligation mixture.
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- | 3.10 Ligate the two parts transformation spread plate pick 4 clones shake and get the reconstruct plasmid
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- | 3.11 We sequenced it and it was right.
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- | 3.12 Then we cut the whole CheZ-tag-terminator with NdeI and AatII and ligate the fragment into the pUC18-GFP vector, which is cut by the same two enzymes.
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- | 3.13 This sequenced this plasmid and the sequence was right.
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- | '''4. Cut the synthesized Nde I-Pm(complementary chain)-Pst I-Xba I-cad-Spe I-RBS(strong)-CI+LVA tag-Sac II-T1, T2-BamH I (the Blue part is the synthesis sequence) sequence with BamH I and Nde I, the same was done on the vector(pUC18-cheZ-tag-ter-GFP). Then ligate them together and got a new reconstruct plasmid. It was also sequenced.'''
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- | '''5. Put RBS-CI-tag into last vector.'''
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- | 5.1 Use PCR to amplify CI from lambda DNA, adding RBS to 5’ and tag to 3’
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- | First round primers:
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- | 5’-GAGGGGACAAactagt ATGAGCACAAAAAAGAAACCATTAACACAAGAGC-3’
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- | 5’-TCGTTTGCTGCAGGCCT gccaaacgtctcttcaggccactgac-3’
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- | Second round primers:
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- | 5’-C A CTAGT tctagaGAAAGAGGGGACAAactagt ATGAGCACAAAAAAGAAACC-3’
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- | 5’-ACT CCGC GG TTA AGCTGCTAAAGCGTAGTTTTCGTCGTTTGCTGCAGGCCT gccaaacgtctcttcagg
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- |
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- | We also did a point mutation with PCR to mutate a Hind III restriction cite.
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- | Forwad:
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- | 5’-GGCTCCAAGCCTAGCTTTCCTGACGGAATG-3’
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- |
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- | Reverve:
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- | 5’- cattccgtcaggaaagctaggcttggagcc-3’
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- | 5.2 Cut the RBS-CI-tag and the reconstructed vector with Sac II and Spe I and ligate them together.
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- | 5.3 Transformation the final plasmid to the ΔCheZ E.coli stain.
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- | Now we have the reconstructed bacteria!!!
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- | == '''DualReceptor''' ==
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- | 1. Project objects
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- | The aim of this project is to guide E.coli to a certain concentration of xylene/toluene, not too high or too low, so that the recombined E.coli can not only indicate the xylene/toluene pollution but also can survive in a not lethal concentration of pollution.
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- | 2. Pathway in the recombined E.coli
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- | [[Image:pathwayLYC.jpeg]] | + | |
- |
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- | Figure1. Pathway in the recombined E.coli
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- | When there is xylene/toluene in the environment, the xylR receptor binds to the xylene/toluene molecular and becomes a active transcription factor, which activate promoter Pu. As a result, cheZ and xylCMAB genes are transcripted and translated. The cheZ protein can make the E.coli to move to higher concentration of xylene/toluene.
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- | When the xylCMAB are activated, the several enzymes which degenerate toluene to benzoate are expressed. As a result, the benzoate can activate receptor xylS and activate promoter Pm and therefore induce the reverse transcription and an antisense mRNA is formed. The antisense mRNA will quickly block the original mRNA of cheZ, and therefore ceases the expression of cheZ protein. Then the E.coli would stay at the same place.
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- | The xylR, xylS, xylC, xylM, xylA, xylB gene and promoter Pu, Pm all come from Pseudomonas putida mt-2 plasmid pWW0. The original gene patterns are shown in the following figure.
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- | [[Image:pathway2.jpeg]]
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- | Figure2. Gene patterns in Pseudomonas putida mt-2 plasmid pWW0
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- | 3. Construct
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- | xylR and xylS will be constructed into pACYCDuet-1(Cm, p15A ori)
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- | Pu-xylCMAB and Pu-cheZ-Pm will be constructed into pUC18(Amp, pMB1 ori)
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- | Several couples of primers has been designed.
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- | Pu and Pm are nearly 200bp long each, and we use PCR to ligate them to the Pu-xylCMAB and Pu-cheZ-Pm.
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- | 4. Knockout of cheZ
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- | [[Image:knockout.jpeg]] | + | |
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- | One single colony has its cheZ knocked out, replacing by kana gene. (Line 3&7)
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- | Another colony is a wide type, and has a 700bp cheZ gene.(Line2&6)
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- | RP1616 is from a foreign lab(line1).
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- | Its 700bp cheZ gene has been replaced by a 300bp segment.
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- | == '''TheoRiboSwitch''' ==
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- | '''Recombinant Plasmids'''
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- | [[Image:CheZ15b.jpeg]]
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- | CheZ is introduced into this plasmid under the control of riboswitch.To help this operon to be transcripted in non-BL21 E.coli strains, the gene coding for prokaryotic T7 RNA polymerase under the control of an artificial promotor is also introduced into this plasmid.
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- | [[Image:LacI177.jpeg]]
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- | LacI with an LVA tag sequence is introduced into this plasmid.
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- | == '''Plate check''' ==
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- | == Procedure ==
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- | Swarming assay
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- | Experimental Procedure
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- | 1. Prepare the competent cells of different strains of E. Coli, e.g.
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- | BW25113, BW25113 (CheZ), Rp1616, BL21 etc. using standard method.
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- | (Calcium Chloride)
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- | 2. Tranform the competent cell with plasmids previously contructed,
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- | e.g. pET15b-TARS-CheZ, pET15b-CheZ-T7, PACYC177-TARS-lacI etc. in the
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- | following scheme:
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- | BW25113 BW25113(CheZ) BL21
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- | ...
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- | pET15b-TARS-CheZ Amp Kan+Amp Amp ...
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- | pET15b-CheZ-T7 Amp Kan+Amp Amp
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- | ...
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- | --- --- Kan
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- | --- ...
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- | 3. Apply 2uL bacteria medium to a 0.4% agar plate (60mm dish) in the
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- | presence or absence of Theophylline. The final concentration of the
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- | theophylline should be around 3~10mM. IPTG is also added to the system, to a
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- | final concentration of 5mM.
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- | 4. Incubate the plates in a 30 degrees C incubator for 10~24hrs and
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- | take photographs.
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- | 5. Compare the radius of the swarming plaque of each stain to test the
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- | efficacy of the molecular device transformed.
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- | Additional attractand gradient plates can also be used.
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- | == Results ==
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- | {| style="color:#1b2c8a;background-color:#0c6;" cellpadding="3" cellspacing="1" border="1" bordercolor="#fff" width="100%" align="center"
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- | !align="center"|[[Team:Tsinghua|HOME]]
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- | !align="center"|[[Team:Tsinghua/Team|Team]]
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- | !align="center"|[[Team:Tsinghua/Project|Project 1]]
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- | !align="center"|[[Team:Tsinghua/Project2|Project 2]]
| + | |
- | !align="center"|[[Team:Tsinghua/Parts|Parts]]
| + | |
- | !align="center"|[[Team:Tsinghua/Modelling|Modelling]]
| + | |
- | !align="center"|[[Team:Tsinghua/Notebook|Notebook]]
| + | |
- | !align="center"|[[Team:Tsinghua/Doodle|Doodle Board]]
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- | |}
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