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Team:Paris Bettencourt/Experiments/Methodologies/Integration
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| + | <p style="display:block;"><u>pDCPKO</u> | ||
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Since cloning into B. subtilis with a replicative plasmid is not an easy task, we decided to construct an integrative plasmid which could give us a better efficiency. Moreover, we would observe less varialibity in gene expression than with a replicative plasmid. To achieve this goal, we designed and constructed a new biobricked integrative plasmid (pDCPKO) from pBGCS6 that we found in the Bacillus Genetic Stock Center. | Since cloning into B. subtilis with a replicative plasmid is not an easy task, we decided to construct an integrative plasmid which could give us a better efficiency. Moreover, we would observe less varialibity in gene expression than with a replicative plasmid. To achieve this goal, we designed and constructed a new biobricked integrative plasmid (pDCPKO) from pBGCS6 that we found in the Bacillus Genetic Stock Center. | ||
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| - | |+ | + | |+ pDCPKO (B.subtilis integrative plasmid) |
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| - | |[[File:pDCPKO | + | |[[File:pDCPKO.png|900px|center|]] |
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| - | <p>We | + | Photo plate |
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| + | <p style="display:block;"><u>pDG364</u> | ||
| + | </p> | ||
| + | <p>We also used the pDG364 integrative plasmid from Harald Putzer at <a href="http://www.ibpc.fr/">IBPC</a> which encodes a chloramphenicol acetyl transferase (cat) selectable in either E.coli or B.subtilis (chloramphenicol 5μg/ml), β-lactamase (bla) selectable in E.coli only (ampicillin 100μg/ml).</p> | ||
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Revision as of 23:04, 28 October 2011
Integrative plasmid
pDCPKO
Since cloning into B. subtilis with a replicative plasmid is not an easy task, we decided to construct an integrative plasmid which could give us a better efficiency. Moreover, we would observe less varialibity in gene expression than with a replicative plasmid. To achieve this goal, we designed and constructed a new biobricked integrative plasmid (pDCPKO) from pBGCS6 that we found in the Bacillus Genetic Stock Center.
 |
Into this plasmid, we cloned both 3' and 5' AmyE sequences created by the 2008 Imperial College of London iGEM team (<partinfo>K143001</partinfo> and <partinfo>K143002</partinfo>). In the design of our new pDCPKO plasmid, we placed our AmyE sequences in order to integrate the whole plasmid into B.subtilis. pDCPKO encodes a chloramphenicol acetyl transferase (cat) selectable in either E.coli or B.subtilis (chloramphenicol 5μg/ml), β-lactamase (bla) selectable in E.coli only (ampicillin 100μg/ml).).
 |
Photo plate
pDG364
We also used the pDG364 integrative plasmid from Harald Putzer at <a href="http://www.ibpc.fr/">IBPC</a> which encodes a chloramphenicol acetyl transferase (cat) selectable in either E.coli or B.subtilis (chloramphenicol 5μg/ml), β-lactamase (bla) selectable in E.coli only (ampicillin 100μg/ml).
 |
We designed primers with restriction site BamHI, which have been amplified by PCR into our parts. Finally, we cloned our parts into the plasmid pDG364 by cutting by BamHI and EcoRI.
Eventually, we cloned each of our parts into these plasmids in order to get our final construct into B.subtilis.
To integrate our integratives plasmids into B.subtilis, we chose to use two different methods. The first one is the starvation methos which one is based on the natural competence in B.subtilis. The second method used to integrate our integratives plasmids in B.subtilis is based on the electroporation.
Starvation
MDCH medium
- Phosphate-citrate buffer (10 x PC) 10 x concentrated stock solution contains per liter : K2H PO4 (anhydrous) 107 g; KH2 PO4 (anhydrous) 60 g; Trisodium citrate (5 H2O) 10 g.
- Dilute stock solution, check pH of 1 x PC buffer and adjust (if necessary) to pH=7. (1 x PC corresponds to Spizizen's salts without ammonium sulfate)
- 10 ml MD medium : 1 x PC buffer 9.2 ml; Glucose (50 %, w/v) 0.4 ml; L-tryptophan (5 mg/ml) 0.1 ml; Ferric ammonium citrate (2.2 mg/ml) 0.05 ml; Potassium aspartate or potassium glutamate (100 mg/ml) 0.25 ml; 1 M MgSO4 0.03 ml.
- Add 0,2mL of casein hydrolysate in the MD medium
- A 10 ml preculture is grown overnight at room temperature in LM broth (liquid LB medium supplemented with auxotrophic requirements and 3 mM MgSO4). MDCH medium is prepared by adding 0.2 ml 5 % casein hydrolysate to 10 ml MD. Use the preculture to inoculate MDCH medium at an OD600 of about 0.05. Grow this culture at 37° C with shaking to To (transition from exponential to stationary phase). Sometimes, To do not appears and we can see a decrease of the OD: do not use the culture. Advice: launch 2 or 3 culture for each strain.
- Add 1 volume of fresh MD medium without casein hydrolysate to 1 volume of culture. Continue shaking at 37° C for 1 hour.
- Make aliquots of 500μL
- Add DNA (up to 1μg) and continue shaking in the presence of DNA for 20 minutes. Eventually, allow for expression of antibiotic resistance for 20mn (as described inJ. Bacteriol. (1988), 170 : 5093-5101) and plate.
- Cm: 5μg/mL; Spec: 50 to 100μg/mL; Kan: 5μg/mL, Erm: 1μg/mL with 25μg/mL of Lincomycin
Electroporation
- Reagents and Equipment needed: Mannitol, Sorbitol, Trehalose, LB, glycerol (99,5%) DNA (50 ng/μL), B. subtilis strain for transformation Cuvette (2mm), Gene Pulser (Bio-rad) set on 200 ohms and 25 μF (≈ 5 ms pulses) and 2 to 2.5 kV Centrifuge set at 3000g and 10 minutes Micropipettes: P2, P200, P1000 Pipettes: 25 mL, 10 mL, 5 mL
Day 1: preparation
- Growth medium: LB + 0.5 mol.L-1 sorbitol → expected final volume: 52 mL for 1 cell culture (including 1 mL for taring the absorbance machine)
_ msorbitol ≈ 4,736 g
- Electro-poration medium: de-ionized water + 0.5 mol.L-1 sorbitol + 0.5 mol.L-1 mannitol + 0.5 mol.L-1 trehalose + 10% glycerol (v/v) → expected final volume: ≈ 40 mL for 1 round of poration
_ msorbitol = mmannitol ≈ 3,643 g
_ mtrehalose ≈ 7,566 g
_ Vglycerol (99,5 %) ≈ 4 mL
- Recovery medium: LB + 0.5 mol.L-1 sorbitol + 0.38 mol.L-1 mannitol → expected final volume: ≈ 1 ml per poly... tube (Approximately 10 tubes ≈ 11 ml total)
_ msorbitol ≈ 1,002 g
_ mmannitol ≈ 0,761 g
Sterilise the solution: Filtration or autoclave.
Inoculate a falcon containing 10 ml of LBA with your bacillus strain and let it grow overnight (37°C with shaking).
Day 2: electro-poration
1) Monitor the OD600 of your overnight culture
2) In a 500 ml erlenmeyer: dilute your culture into 50mL of Growth Medium so that the OD 600 is 0.01
3) Let the culture grow (37°C with shaking) until OD600 is between 0.85 and 1
4) Cool the cells on ice for 5 minutes.
5) NOTE: KEEP ALL YOUR MATERIAL ON ICE AND ALWAYS MANIPULATE ON ICE FROM NOW ON, KEEP AS STERILE AS POSSIBLE.
6) Distribute evenly the culture into two falcons and centrifuge at 3000g for 10 minutes.
7) Get rid of supernatant, tap the falcon upside down on a piece of paper and detach the pellet.
8) Add 20 mL of ice-cold electro-poration medium to one falcon, suspend the cells and transfer the content to the other falcon. Re-suspend.
9) Centrifuge 3000g for 10 minutes.
10) Repeat step 8 and 9 (in only one falcon) with 10 mL, 5 mL, 2.5 mL and finally add 0.625 mL (1/80 of initial volume).
11) During the centrifugation time, prepare the poly... tubes (label them) with recovery medium in them and put the cuvettes on ice: 1 of each at least has to be a control of cells without DNA, then 1 for each transformant you wish to make.
12) Transfer in a cuvette: 60 μL of cells + 1 μL of DNA (50ng/μL; none if control).
13) Pulse the cuvette.
14) Transfer immediately the content into the poly... tube (STERILE CONDITIONS).
15) Repeat 13, 14 and 15 for the number of prepared cuvettes.
16) Incubate the poly... tubes at 37°C for 3 to 6 hours.
17) Prepare plates with antibiotics (none for the control).
18) Note: ≈ 25 ml of LBA per petri dish, make sure the antibiotic is well diluted, labeling should be obvious.
19) Plate max 150 μL of transformed cells per petri dish and let grow overnight.
