Team:Edinburgh/Project/Bioelectric-Interface/Bio-electric-Interface-BioBricks-Cloning

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Figure 11: pSB1C3-ccm clones 1-6, digested with EcoRI. <br />
Figure 11: pSB1C3-ccm clones 1-6, digested with EcoRI. <br />
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Clones 1 and 5 show bands of expected size, the other clonse are too small <br /><br />
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Clones 1 and 5 show bands of expected size, the other clones are too small <br /><br />
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Figure 12: pSB1C3-ccm clones 1 and 5, testing internal restriction sites. <br />
Figure 12: pSB1C3-ccm clones 1 and 5, testing internal restriction sites. <br />

Revision as of 22:20, 26 September 2012

Bio-electric interface

Bio-electric interface BioBricks cloning

Procedure

- Microorganisms used: Escherichia coli JM109 and Shewanella oneidensis MR-1. Both organisms were obtained from cultures in Chris French’s lab at the University of Edinburgh. S. oneidensis cultures were grown on LB agar at room temperature not exceeding 30°C. Plates were subcultured each week. E. coli cultures were grown on LB agar at room temperature and subcultured by lab staff when needed.

- PCR: most PCR reactions were performed following OpenWetWare protocol CFrench: KodPCR. Optimal annealing temperature for S. oneidensis genes was found to be around 50-52°C while E. coli genes showed good results with annealing temperatures in range of 50-55°C. S. oneidensis cell suspension in sterile water was used as template for MtrA, MtrCAB, S. oneidensis ccmA-E and ccmF-H genes E. coli cell suspension in sterile water was used as template for napC and E. coli ccmA-H genes.

- polyA tailing: for several genes polyA tailing was performed using Taq polymerase and following protocol: 20 minutes denaturation at 95°C, followed by addition of Taq polymerase, followed by 15 minutes extension at 72°C.

- gel electrophoresis: gel analysis was used following OpenWetWare CFrench: AGE protocol except 0,5 TAE buffer was used rather that 1x TAE. Staining procedure involved SYBR-Safe.

- gel purification and DNA purification: for ccm and several ligation attempts for other genes the PCR samples were run on the gel then the appropriate bands were cut out and purified using standardised QIAquick Gel Extraction Kit. For pure PCR products OpenWetWare protocol CFrench: DNAPurification1 was used.

- Vectors used: For most reaction standard BioBrick vector pSB1C3 (provided by the registry) was used, except for samples that were subjected to polyA tailing which were then ligated into pGEM vector (Promega)

- Restriction digestion: Restriction digests were performed for PCR products along with vector digestion following OpenWetWare CFrench:restriction1 protocol. For enhanced efficiency varying ratio of insert to vector were used with optimum reached at about 3:1 to 5:1 ratio of insert digest to vector digest. Analytical restriction digests were also performed for miniprep samples using the original protocol.

- Ligation: Digested samples were mixed with 1 ul T4 ligase buffer and 1 ul T4 ligase and mixed with water to reach final volume of 20 ul if necessary. Alternatively, polyA tailed PCR sampels were mixed with pGEM vector and used directly for ligation.

- Fusion PCR: following the ligation the samples were used as template for fusion PCR, following KodPCR protocol using forward primer of the gene and reverse primer for the vector. Extension time was adjusted to the length of vector with insert.

- Transformation: Ligation and fusion PCR products were used to transform E coli JM109 competent cells using OpenWetWare protocol Cfrench:compcellprep1, protocol for preparation of competent cells and cell tansformation).

- Transformed cell selection: Transformed cells were spread on LB agar with chloramphenicol (for pSB1C3 vector) or LB agar with Carbenicillin, Xgal and IPTG. Following overnight incubation at 37°C white colonies were chosen (rather than red colonies from pSB1C3-RFP vector or blue colonies from pGEM vector) and subcultured on the plates containing the same medium.

- Miniprepping: Subcultures were used to set up overnight liquid cultures in 2,5 ml of LB. Miniprepping was performed using either OpenWetWare protocol Cfrench:minipreps1 or standarised QIAprep Spin MiniPrep Kit.. Minipreps were then restriction digested and run on the gel

- Sequencing: size confirmed minipreps were then sent for sequencing in the University of Edinburgh GenePool.

Results

NapC
- Throughout summer we have managed to clone napC gene from E coli (BBa_K917003). We have inserted the gene into the standard BioBrick vector pSB1C3 and submitted it to the parts registry. We have then linked napC gene to lac promoter (BBa_K917012) to characterise its functionality.

Figure 1: napC PCR


Figure 2: napC miniprep


Figure 3: pLac-napC construct analytical digestion with XbaI and PstI
Lanes 3, 4 = pSB1C3-Plac-lacZ'-napC, clones 1 and 2, digested with XbaI-PstI. Clone 2 looks as expected, clone 1 has an unexpected band around 0.6 kb.

MtrA
- We also managed to obtain MtrA gene (BBa_K917008) of S. oneidensis and cloned it into pSB1C3 plasmid.

Figure 4: MtrA PCR


Figure 5: MtrA transformation


Figure 6: MtrA miniprep

Obtained MtrA gene contains an internal PstI site which needs to be mutagenised prior to submission and use.

cymA
We have managed to clone cymA gene (BBa_K917009) from S. oneidensis. We have tested the gene for internal restriction sites and linked cymA gene to lac promoter (BBa_K917014) to characterise its functionality.

Figure 7: lanes 3, 4 = pSB1C3-cymA clones 1 and 2, analytically digested with EcoRI. Band has size correct for linearised plasmid with the gene(3kb)
lanes 5, 6 = pSB1C3-cymA clones 1 and 2, double digested with EcoRI/SpeI.


Figure 8: pSB1C3-cymA clones 1 and 2, testing internal restriction sites.
Lanes 1, 2 = clones 1 and 2, NdeI.
Lanes 3, 4 = clone 1, XbaI and XbaI/HindIII.
Lanes 5, 6 = clone 2, XbaI and XbaI/HindIII.
Gel results appear as expected


Figure 9: Lanes 4 to 6, pSB1C3-Plac-lacZ'-cymA clones 1-3, analytically digested with XbaI-PStI.
Clones 1 and 2 show bands of appropriate sizes.

ccm cytochrome maturation cluster of E. coli
We have cloned E. coli ccm gene cluster (BBa_K917006), analysed its internal restriction sites and linked it with lac promoter (BBa_K917013).

Figure 10: E coli ccm genes PCR (right lanes)


Figure 11: pSB1C3-ccm clones 1-6, digested with EcoRI.
Clones 1 and 5 show bands of expected size, the other clones are too small


Figure 12: pSB1C3-ccm clones 1 and 5, testing internal restriction sites.
Lanes 1, 2 = EcoRI/SpeI digestion.
Lanes 3, 4 = BamHI digestion.
Lanes 5, 6 = ClaI digestion.
Results appear as expected assuming 2 of the 3 ClaI sites are uncuttable due to overlapping dam methylation


Figure 13: Lanes 1, 2 = pSB1C3-Plac-lacZ'-ccm, clones 1 and 2, digested with XbaI-PstI.
Clone 2 looks as expected, clone 1 has an unexpected band around 0.6 kb.

MtrCAB and S. oneidensis ccm
- We have also obtained good quality pure PCR products of MtrCAB and ccm genes from S. oneidensis
Figure 14: MtrCAB PCR


Figure 15: ccm genes from S. oneidensis and E. coli

Discussion and conclusions

We managed to obtain napC, cymA, ccm and mtrA genes which are now ready for testing, using haem staining and half fuel cells. MtrA gene still contains and internal PstI site which has to be mutated out prior to submission. We have linked napC, ccm and cymA to lac promoter to test these new BioBricks using haem staining and half fuel cells with our current results as reference. However it is possible that the transformed cells will require multiple genes to function properly. Ccm genes are responsible for cytochrome maturation which is necessary for proper folding of multihaem cytochromes such as NapC, CymA and especially decahaem cytochrome MtrA.

The longer products (MtrCAB and ccm genes) seem to be more problematic to clone, with digestion/ligation step being the limiting factor, despite using several alternative techniques (polyA tailing, fusion PCR).
We had some success in cloning mtrCAB and S. oneidensis ccm genes which may enhance the efficiency of the system. We intend to clone these genes into the pSB1C3 vector (BBa_K917007), link them to a promoter and test them together in order to assess the efficiency of the system.

The complete electron export conduit should be able to reliably export electrons in response to an external stimulus. This system can be used to enhance the current biosensor systems. One possible application would be to link our system to arsenic promoter and construct a reliable, cheap arsenic biosensor which would generate easy to interpret data that can be stored on a computer.

Bibliography (expand)

1. Jensen, H. M., Albers, A. E., Malley, K. R., Londer, Y. Y. , Cohen, B. E., Helms, B. A., Weigele, P., Groves, J. T. & Ajo-Franklin, C. M. (2010). Engineering of a synthetic electron conduit in living cells. PNAS 107, 19213-19218

2. Stewart, V., Lu, Y. & Darwin, A. J. (2002). Periplasmic Nitrate Reductase (NapABC Enzyme) supports Anaerobic Respiration by Escherichia coli K-12. Journal of Bacteriology 184, 1314-1323

3. Marritt, S. J., Lowe, T. G., Bye, J., McMillan, D.G.G., Shi, L., Frederickson, J., Zachara, J., Richardson, D. J., Cheesman, M. R., Jeuken L.J.C. & Butt, J. N. (2012). A functional description of CymA, an electron-transfer hub supporting anaerobic respiratory flexibility in Shewanella. Biochemical Journal 444, 465-474

4. Richter, K., Schicklberger, M., Gescher, J. (2011). Dissimilatory reduction of extracellular electron acceptors in anaerobic respiration. Applied and Environmental Microbiology 78, 913-921

Close bibliography.