Protocols
Protocol #0 : iGEM General Protocol
- Obtaining Biobricks
- EITHER on IDT →
- Order on IDT when the sequences are not too long (chemical synthesis).
- The received biobricks are lyophilized, they must be resuspended in water (cf protocole).
- OR by PCR →
- When sequences are too long and costly to order on IDT, or when a sequence must be added to an existing biobrick :
- Order primers
- synthesize sequence by PCR (cf protocole Q5)
- add the suffixes and prefixes during the synthesis « E, X » and « S, P » (E=EcoRI, X=XbaI, S=SpeI, P=PstI) and homologue sequences to plasmids
- Do a SLIC (cf protocole) to insert the wanted sequence in the wanted plasmid
- the Biobrick is obtained
- Transform the Bacteria with the Biobrick
- E/S Digestion of the Biobrick from the original plasmid and reinsertion in the E/S pre-restricted wanted plasmid.
- Transform the pre-cultivated competent cells, via a thermal shock (DH5-α, TGI, BL21).
- Add an LB-agar in a petri dish and cultivate the bacteria in rich medium added with antibiotics of interest.
- Test the Transformation
- Run the obtained bacteria culture DNA in a PCR and an electrophoresis gel (qualitative assessment)
- Purify plasmids (by miniprep Kit) from the previously obtained positive colonies.
- Do an E/P digestion verification to see if the inserted biobricks have the correct size (On only 100ng of plasmids)
- Assemble two biobricks
- “Digestion protocol BioBrick Assembly Kit” et “Ligation protocol BioBrick Assembly”
- Do an E/S digestion on the first biobrick and an X/P on the second
- Ligate the two biobricks then insert them into the plasmid
- Transforming Bacteria with a new BioBrick
- E/P Restriction of the biobrick and ligation into a E/P restricted plasmid
- Transform the pre-cultivated competent cells, via a thermal shock (DH5-α, TGI ou BL21).
- Pour an LB gel in a petri dish and cultivate the bacteria in an antibiotic rich medium
- Test the Transformation
- Run the obtained bacteria culture DNA in a PCR and pour an electrophoresis gel (qualitative assessment)
- Purify plasmids (by miniprep Kit) from the previously obtained positive colonies.
- Do an E/P digestion verification to see if the inserted biobricks have the correct size (On only 100ng of plasmids)
- Send to sequencing
- Repeat steps 4, 5, 6 until obtaining the wanted sequence
Protocol #1 : Preparation of competent bacteria cells
Note : Everything should be done in sterile conditions and on ice (4°C).
For 100ml of competent cells
- Grow a culture of bacteria in LB medium until it reaches OD600 = 0.5.
- While it grows, prepare Tbf1 and Tbf2 buffers.
- Centrifuge cells for 10 minutes at 3500g at 4°C
- Resuspend the pellet slowly in 50mL of Tfb1 buffer.
- Centrifuge 5 min at 3500g at 4°C.
- Resuspend the pellet in 8 mL of Tbf2 buffer.
- Incubate 15 min in ice.
- Aliquot 200µL of cell suspension in sterile eppendorf tubes and conserve it at -80°C.
Protocol #1bis : Preparation of Tbf1 and Tbf2 buffers
For 100 mL of culture:
Preparation of 50 mL of Tbf1 Buffer
| KAc 1M
|
1.5 mL
|
| MnCl2 0.5M
|
5 mL
|
| KCl 1 M
|
5 mL
|
| CaCl2 0.1M
|
5 mL
|
| Gly 80%
|
0.93 mL
|
| H2O
|
32.56 mL
|
Preparation of 8 mL of Tbf2 Buffer
| NaMOPS 0.2M
|
400 µL
|
| CaCl2 0.1M
|
6 mL
|
| KCl 1 M
|
8 mL
|
| Gly 80%
|
1.5 mL
|
| KCl 1M
|
80 µL
|
| H2O
|
500 µL
|
Protocol #2 : Transformations
Plasmids transformation
- Add 20 ng of plasmid to 100 μL of competent cells thawed in ice
- Incubate 30-45 min in ice
- Thermal shock : put tubes in the Thermomixer at 42°C for 2 min
- Incubate 5 min in ice
- Add 900 μL {of LB
- Incubate 1 hour at 37°C with agitation
- Spread 100 μL on LB limp (with antibiotic)
Ligation transformation
- Add 20 ng of ligation product to 100 μL of competent cells thawed in ice
- Incubate 30-45 min in ice
- Thermal shock : put tubes in the Thermomixer at 42°C during 2 min
- Incubate 5 min in ice
- Add 900 μL of LB
- Incubate 1 hour at 37°C with agitation
- Centrifuge 5 min at 5000 rpm
- Eliminate 850 μL of medium
- Spread 150 μL on LB limp (with antibiotic)
To make negative control, follow the same procedure but without adding plasmids and spreading 300 μL
Protocol #3 : Cloning protocol for IDT sequences
Resuspension
Resuspend gBlocks Gene fragment to a final concentration of 10 ng/µL in TE or AE (elution buffer).
The tube contain 1000 ng of gBlocks Gene fragment so you have to add 100µL of AE
Mix well, a vortex shall be used
Digestion E/P
1. Digest 100 ng in 50µL
| component
|
50 µL of reaction
|
| DNA
|
10 µL
|
| Buffer 2 (10X)
|
5 µL
|
| BSA (100X)
|
0.5 µL
|
| H2O
|
33 µL
|
| EcoRI
|
1 µL
|
| PstI
|
1 µL
|
2. Incubate for 45 min at 37°C
3. Incubate 20 min at 80°C (inactivation of restriction enzyme)
Ligation
1. Ligate 50 ng vector with a 3X molar excess of gBlocks Gene fragments in fresh T4 DNA ligase buffer diluted to 1X and 400 U T4 DNA ligase for a total volume of 20 µL
| component
|
20 µL of reaction
|
| PSBIC3 (or other vector) at 12.5 ng/µL
|
2 µL
|
| insert digested (at 37.5 ng/µL)
|
12 µL
|
| T4 Buffer
|
2 µL
|
| T4 ligase 400 U
|
1 µL
|
| H2O
|
3 µL
|
2. Incubate 2h at room temperature
Transformation
- Add 10 µL of ligation’s product to 100 µL of competent cells thawed in ice (TGI cells)
- Incubate 45 min in ice
- Thermal shock: put tubes in the thermomixer at 42°C during 2 min
- Incubate 5 min in ice
- Add 900 µL of LB
- Incubate 1 hour at 37°C with agitation
- Centrifuge 5 min at 5000 rpm
- Eliminate 850 µL of supernatant
- Suspend the pellet in the 150µL of remaining medium
- Spread 150 µL on LB limp (with antibiotic)
To make negative control, follow the same procedure but without add plasmids and spread 300 µL
Protocol #4 : Digestion and ligation for verification and BioBrick Assembly
Digestion (verification) protocol
| DNA
|
Between 50 and 100 ng
|
| EcoRI-HF
|
0.2 µL
|
| PstI
|
0.2 µL
|
| 10X NEBuffer 2
|
2 µL
|
| H2O
|
QS 20 µL
|
Incubate all digest reactions at 37°C for 1 hour and then add 3 µL of SES 4X and migrate 30 min at 150V on a 1% agarose gel.
Digestion protocol BioBrick Assembly Kit
Upstream part :
| Upstream part plasmid
|
500 ng
|
| EcoRI-HF
|
1 µL
|
| SpeI
|
1 µL
|
| 10X NEBuffer 2
|
5 µL
|
| H2O
|
To 50 µL
|
Downstream part, optional, for 3A strategy
| Downstream part plasmid
|
500 ng
|
| XbaI
|
1 µL
|
| PstI
|
1 µL
|
| 10X NEBuffer 2
|
5 µL
|
| H2O
|
To 50 µL
|
Destination plasmid :
| Destination plasmid
|
500 ng
|
| EcoRI-HF
|
1 µL
|
| PstI
|
1 µL
|
| DpnI
|
1 µL
|
| 10X NEBuffer 2
|
5 µL
|
| 100X BSA
|
0.5 µL
|
| H2O
|
To 50 µL
|
Incubate the three restriction digest reactions at 37°C for 10 minutes and then heat inactivate at 80°C for 20 minutes.
Ligation protocol BioBrick Assembly
| Upstream part digestion
|
2 µL
|
| Downstream part digestion
|
2 µL
|
| Destination plasmid digestion
|
2 µL
|
| 10X T4 DNA ligase buffer
|
2 µL
|
| T4 DNA ligase
|
1 µL
|
| H2O
|
11 µL
|
Incubate at RT for 1 hour.
#Protocol 5 : Generalised transduction using phage P1
Step1 : P1 lysat on the given strain
From a overnight starter, (3mL in 2YT medium + appropriated antibiotiques) from the strand holding the transduct mutation, make a 1/100 dilution in 3mL 2YT medium and add 150µL of Cacl2 0.1M ( without antibiotique corresponding of the transduct allele).
Incubate at 37°C (under agitation) until obtening a DO600=0.5-1 (more 0.5)
Add 150µL of a P1 lysat wt
Incubate at 37°C without agitation (water bath) during 20min
Incubate at 37°C under agitation during 3 or 4h (even overnight)
Divide the culture in 2 eppendorfs of 2mL (=2*1.5mL)
Add 150µL chloroform then vortex
Centrifuge 10min at 4°C and 6000rpm
Transfer 1mL supernatant into 2 news eppendorf of 2mL
Add 10µL chloroform (under a fumehood) in each eppendorf, vortex and keep at 4°C
(option: to increase the titration level, you can do a second cycle)
Step2 : Transduction P1
The eve, prepare a culture of the recipient strain in 3mL 2YT medium (+eventual appropriated antibiotique)
The D-day, start a culture from the recipient strain (1/50 dilution) in 3mL 2YT + 150µL of CaCl2 0.1M
( prepare the LB-citrate 5mM requiered and LBagar- appropriated AB + citrate 2mM petri dishes)
Incubate until reaching a DO600 = 1 or + (2.10^6 bact/mL)
Prepare 3 tubes eppendorf of 2mL (1 control with 500µL cells, 1 with 10µL P1 + 500µL cells, 1 with 100µL P1 + 500µL cells)
Infect during 20min at 37°C (heat wuthout agitation)
Add 1mL steril LB-citrate 5mM and heat at 37°C during 50min under agitation (700-750rpm)
Centrifuge 5min at 5000rpm (RT)
Remove supernatant sterilely with a P1000 and resuspend in 1mL steril LB-citrate 5mM
Spread on LBagar- appropried AB + 2mM citrate
Incubate ON at 37°C
Step3 : Clones isolation
Isolate clones on petri dishes (approprieted AB + citrate 2mM)
Incubate at 37°C
Step 4 : PCR screen and transplantation
Test clones by PCR
Transplant the good clones on LB-AB appropriate petri dishes
#Protocol 6 : Cadaverin HPLC analysis
Reaction of lysine and cadaverine produced by biotransformation with whole cells
The assays were performed in a total volume of 500µL, containing 500mM sodium acetate buffer (ph = 6.0), 10mM L-lysine, 0.1 mM pyridoxal-5-phosphate, and 20µL whole cells, at 37°C in a water bath. The reaction was stopped after 24h by the addition of 10µL ethanol. The reaction mixtures were centrifuged and the 30µL of supernatant was applied to derivatization to determine the amounts of residual lysine and product, i.e cadaverine.
Derivatization reaction
Diamine deritatives were obtained by the reaction of 180µL of borate buffer 0.05M (pH9), 60µL of 100% methanol, 47µL diethyl ethoxymethylenemalonate without any pretreatment. The samples were heated at 70)C for 2h to allow complete degradation of excess DEEMM and derivatization.
HPLC analysis
After derivatization with diethyl ethoxymethylmalonate, analyses were performed on a high performance liquid chromatograph (HPLC Agilent technologies, 1260 Infinity) consisting of a binary pump, an inline degasser, an autosampler and a column thermostat. Chromatographic separation was carried out by reverse-phasechromatography on a C18 column maintained at 35°C. Mobile phase A was composed of 100% acetonitrile, and B was made up of 25mM aqueous sodium acetate buffer (pH = 4.8). The flow rate of 1mL/min was used, with the following gradient program : 0-2min, (20-25% A; 2-32min, 25-60%A; 32-40min, 60-20%A. Detection was carried out at 284nm.
#Protocol 7 : SLIC (sequence- and ligation-independent cloning)
Procedures
1. Digest vector with restriction enzyme during 3h and purify the linearized vector with a commercial PCR purification kit. Elute DNA with elution buffer or 10mM TrisCl, pH 8.0-8.5. Do nnot elute the DNA with water or TE. Measure the concentration of the vector.
2. Amplify your gene of interest by PCR using primers with 15 mer (or inferior) homology extension to the linearized vector end. We usually use 15bp homology for single fragment cloning, and 20bp for multiple fragment cloning. Purify the linearized vector with a commercial PCR purification kit. Elute the DNA with water or TE. Measure the concentration of the insert(s).
3. Mix the linearized vector and insert at a molar ratio of 1.2 ina 1.5mL tube. An examble is shown as follows. (Vector to insert molar ratio of 1/1 for single fragment cloning, 1:2:2 for multiple fragments cloning. AN example of 3 fragments cloning is shown below with vector: insert 1: insert 2 molar ratio as shown is 1:2:2 as shown in Fig. 4A).
|
|
Stock concentration
|
Volume added
|
Final concentraion
|
| Linearized vector
|
100ng/µL
|
1µL
|
10ng/µL
|
| Insert 1
|
40ng/µL
|
1µL
|
4ng/µL
|
| Insert 2
|
40ng/µL
|
1µL
|
4ng/µL
|
| 10X BSA
|
|
1µL
|
1X
|
| 10X NEB Buffer 2
|
|
1µL
|
1X
|
| H2O
|
|
Up to 10µL
|
|
SLIC Oligo table
| DesA slic forward
|
cgctaaggatgatttctgGAATTCGCGGCCGCTTCTAGATGCGCTCGCACTTGCTT
|
| desA slic reverse
|
ttgcccttttttgccggaCTGCAGCGGCCGCTACTAGTATTATTAGGAGGCACGGTC
|
| desB slic forward
|
"a rentrer"
|
| desB slic reverse
|
ttgcccttttttgccggaCTGCAGCGGCCGCTACTAGTATTATTACACTGCAAATTC
|
| desC slic forward
|
"a rentrer"
|
| desC slic reverse
|
ttgcccttttttgccggaCTGCAGCGGCCGCTACTAGTATTATTAGGCTGAAACCGC
|
| desD slic forward
|
"a rentrer"
|
| des D slic reverse
|
ttgcccttttttgccggaCTGCAGCGGCCGCTACTAGTATTATTAACGCCCGGCTAA
|
| FliC E. coli slic forward
|
cgctaaggatgatttctgGAATTCGCGGCCGCTTCTAGATGGCACAAGTCATTAAT
|
| FliC E.coli slic reverse
|
ttgcccttttttgccggaCTGCAGCGGCCGCTACTAGTATTATTAACCCTGGAGCAG
|
| FliC desulfo slic forward
|
cgctaaggatgatttctgGAATTCGCGGCCGCTTCTAGATGTCACTGGTTATCAAT
|
| FliC desulfo slic reverse
|
ttgcccttttttgccggaCTGCAGCGGCCGCTACTAGTATTATTAGCCGCCGAGAAG
|
| CsgA E. Coli slic forward
|
"a rentrer"
|
| CsgA E. Coli slic reverse
|
"A rentrer"
|
