Team:UNITN-Trento/Protocols
From 2013.igem.org
PCRs
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1) Add the following components to a sterile microtube on ice:
Components | Volume | Final Concentration |
---|---|---|
10X Reaction buffer | 5µl | 1X |
10mM dNTP mix | 0.5µl | 0.1µm |
Primer mix (10µM each) | 1µl | 0.2µm |
Template DNA | 0.5⁓10µl | n/a |
RBC Taq DNA polymerase (5U/µl) | 0.25µl | 1.25units |
ddH2O | to 50µl | n/a |
2) Suggested Reaction Parameters for RBC Taq DNA Polymerase
Segment | Number of cycles | Temperature | Duration |
---|---|---|---|
1 | 1 | 94°C | 1⁓3 minutes |
2 | 25⁓35 |
94°C (denature) 5 degree lower than Tm of Primer 72°C (extend) |
30 seconds⁓1 30 seconds⁓1 minute 1minute/Kbp |
3 | 1 |
72°C 4°C |
7 minutes |
3) Analyze the amplification products by agarose gel electrophoresis and visualize by ethidium bromide staining.
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Component | 50 µl Reaction |
---|---|
Nuclease-free water | to 50 µl |
5X Phusion HF or GC Buffer | 10 µl |
10 mM dNTPs | 1 µl |
10 µM Forward Primer | 2.5 µl |
10 µM Reverse Primer | 2.5 µl |
Template DNA | Variable |
DMSO (optional) | (1.5 µl) |
Phusion DNA Polymerase | 0.5 µl |
For the template DNA, use 1 µl (50 ng/ µl) of E.coli genomic DNA.
Set the PCR with the following parameters:
Cycle step | Cycles | Temp [°C] | Time [s] |
---|---|---|---|
Initial denaturation | 1 | 98 | 30 |
Denaturation | 30 | 98 | 5-10 |
Annealing | 72 | 10-30 | |
Extention | 72 | 10-30*kb | |
Final extention | 1 | 72 | 5-10 [min] |
Hold | 1 | 4 | ∞ |
Reaction Mix | |
---|---|
5x One Taq Buffer | 10 µl |
Fwd Primer | 1 µl |
Rev Primer | 1 µl |
10 mM dNTP's | 1 µl |
One Taq | 0.25 µl |
Phusion | 0.3 µl |
Template DNA | 50-100 ng |
H20 | up to 50 µl |
Cycle Step | Cycles | Temp [°C] | Time [s] |
---|---|---|---|
Inital denaturation | 1 | 94 | 120 |
Denaturation | 30 | 94 | 30 |
Annealing | 60 * | 60 | |
Extension | 68 | 60 s/Kbase | |
Final Extension | 1 | 68 | 300 |
Hold | 1 | 4 | ∞ |
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Sample Capture:
- Add 250 µl of Capture buffer type 3 to the sample.
- Mix and control that the color is yellow or pale orange.
-
Sample Binding:
- Transfer the mix in the assembled GFX MicroSpin column and Collection tube.
- Spin for 30s at 16000*g (⁓13000rpm) and discard the Collection tube.
- Replace GFX MicroSpin column in the same Collection tube.
-
Wash and Dry:
- Add 500 µl of Wash buffer type 1.
- Spin for 30s at 16000*g (⁓13000rpm) and discard the Collection tube.
- Transfer the GFX MicroSpin column in a clean tube.
-
Eluition:
- Add 50 µl of distilled water.
- Incubate for 1 minute at room temperature.
- Spin for 1 minute at 13000rpm.
- Retain flowthrough.
- Quantify the sample at Nanodrop and label it with its concentration.
External protocol
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Cells
- Transformation Buffer: sterile 10 mM Tris-HCl, pH 7.0, 50 mM CaCl2
- Grow a 50 mL culture in LB at 37 deg C from 1 colony.
- When OD ~ 0.5, collect the cells in a sterile Falcon tube and chill on ice for 10min.
- Centrifuge at 5000 rpm for 10 min at 4 deg C. Discard supernatant.
- Resuspend cells in 15 mL of transformation buffer.
- Chill on ice for 15 min. Spin at 5000 rpm for 10 min at 4 deg C. Discard supernatant.
- Resuspend cells in 4 mL of transformation buffer.
The cells are now ready to be transformed. They can be stored in this state at 4 deg C for under a week.
Alternatively, the competent cells can be aliquoted (200µL), adding glycerol to a final conc of 15% (v/v), and the cells stored at –80 deg C.
Every time you make new competent cells you should check for possible contaminations. Plate an aliquot of the new cells in LB plates + antibiotic (i.e. ampicillin, chloramphenicol, kanamycin). Strains such as DH5a, NEB10b, Novablue, should not grow in the presence of antibiotics.
- Thaw home made CaCl2 competent cells on ice.
- Add 1µL of DNA to 200µL of competent cells (concentration of DNA stock should be between 50–150 ng/µL).
- Incubate on ice for 30 min.
- Heat shock at 42°C for exactly 2 min.
- Incubate on ice 1 min.
- Add 500-700µL of LB (or SOC) and shake at 37°C for 1 h.
- Plate the cells (use plates with the appropriate antibiotic according to your plasmid).
You can either plate a small amount (200µL) of the cells or more.
You should try a few conditions the first time and then choose the one that gives 30–300 separate colonies.
If few cells are expected: spin down the cells at 2500 rpm, discard supernatant and resuspend in 150–200µL of LB and plate all the cells.
Plates must be labeled as follow:
strain – [resistance] – part – “(plasmid)” – YOUR_NAME – date
For ligation you should increase the amount of DNA to be transformed (see cloning protocol).
- Incubate the plates O/N upside down at 37°C.
Competence medium (MC completed) | |
---|---|
H2O | 1.8 ml |
10x MC | 200 ul |
MgSO4 1M | 6.7 ul |
trp 1% (for trp - strains) | 10 ul |
MC 10x | |
---|---|
for 100 ml | |
K2HPO4 3H2O | 14.036 g |
KH2PO4 | 5.239 g |
Glucose | 20 g |
Tri-Na Citrate 300 mM | 10 ml |
Ferric NH4 Citrate | 1 ml |
Casein Hydrolysate | 1 g |
K glutamate | 2 g |
Mix everything in 40-50 ml H2O, then adjust to 100 ml, filter sterilize, freeze at -20 C |
Tri-Na Citrate 300mM | 8.823 g | in 100 ml H2O |
---|---|---|
Ferric NH4 citrate | 2.2 g | in 100 ml H2O |
--> wrap in aluminium foil!! |
- Pick up a nice big colony and drop it in 2 ml of completed MC (1x) (see below);
- Grow at 37 °C for 5 hours (or more if culture is not really turbid);
- Mix 400 ul of culture with DNA (usually 1 ug) in fresh tube (i.e. 15 ml tubes losely closed);
- Grow for additional 2 h at 37 °C;
- Plate all on selective antibiotic plates, and incubate at 37 °C O/N
- Transfer 100 ul of sterile distilled water in an eppendorf;
- Pick up a colony using a tip and resuspend it in the sterile water;
- Verify that the glass slide is cleaned and degreased or clean it with 70% alcohol;
- Transfer 20 ul of bacterial suspension on the slide;
- Swipe gently bacterial suspension with the aid of a sterile loop to occupy 1-2 cm at the center of the slide;
- Let dry the slide by evaporation;
- Cover the central part of the slide with methanol, remove the excess and let it evaporate;
- Sock the slide in the crystal violet solution for 1 min, wash then with sterile water;
- Sock the slide in the lugol solution for 1 min, wash then with sterile water;
- Pour Gram bleach solution on the product for 20-30 s, wash then with sterile water;
- Sock the slide in the safranin solution for 1 min, wash then with sterile water;
- Finally let dry the slide and observe it with the microscope.
Miscellaneous
- Label the empty eppendorfs that will contain the parts, including antibiotic resistance, part denomination and position (and on which kit).
- Spot the correct well and label it with a pen.
- Push a hole with the pin of a micropipette and resuspend the content with 10ul water.
- When the color is dark red, wait 1 minute.
- Move the re-suspended part into the correct empty eppendorf.
Prepare the digestion mix as follow:
DNA | 500 ng |
10X NEB Buffer | 2.5 ul |
10X BSA | 2.5 ul |
E1 | 1 ul |
E2 | 1 ul |
H2O | Up to 25 ul |
Incubate the reaction mix at 37 °C for 30 min. Disactivate then the enzymes incubating the mix at 80 °C for 20 min. The next step will be the ligation of the digestion products. The raction mix is prepared as follow:
Insert | 3 fold excess |
Vector | 40 ng |
10X T4 Ligase Buffer | 2 ul |
T4 Ligase | 1 ul |
H2O | Up to 20 ul |
Gently mix the reaction and incubate for 30 min at room temperature. Disactivate the enzymes at 80 °C for 20 min. Transorm 10 ul of the reaction in competent cells.
Prepare your reaction and incubate at RT for 2 hours. Transform half of the reaction into 200μL of “homemade” competent cells (DH5α, NEB10β, Novablue or other appropriate strains) following a standard transformation protocol. Plate all the cells.
Classic Cloning | Screening | ||
---|---|---|---|
PCR products | Plasmids | ||
Template | ~3-4µg | ~2-3µg | ~1.0µg |
Enzyme 1 | 2.5µl | 1.5µl | 1.0µl |
Enzyme 2 | |||
Buffer (stock 10X) | 10µl | 5µl | 2µl |
BSA (stock 10X) | 10µl | 5µl | 2µl |
Water | Up to 100µl | Up to 50µl | Up to 20µl |
Classic Cloning - for PCR products
Incubate at 37°C overnight. The day after add 1µl of DpnI and incubate at 37°C for 2 hours. Please note that PCR product must be purified before digestion.Classic Cloning - for plasmids
Incubate at 37°C overnight. The day after add 1µL of phosphatase (CIP or SAP) to the vector and incubate for 2 hours at 37°C.Biobricks Cloning
Incubate at 37°C for 30 minutes. Then disactivate the enzymes at 80°C for 20 minutes.Screening
Incubate for 1.5h at 37°C. Run all the digested product on an agarose gel to screen colonies.Double Digest finder
Details
PRIMERS SEQUENCES | |||
---|---|---|---|
Primer Forward | GCCGCTTCTAGAGA AGGAGG AACTACT ATGGCAAAACACCTTTTT | prefix(only Xba1) + RBS + spacer + ATG... | Tm = 66°C |
Primer Reverse | CTGCCGGTCTGAAG TAATAA TACTAGTAGCGGCCGCTGCAG | sequence + stop codon + suffix | Tm = 67.5°C |
PCR mix | |
---|---|
Solutes | Quantities or Concentration |
Template(genome) | 1ng/ µl |
dNTPs | 0.5µl |
Primer Forward | 1 µl |
Primer Reverse | 1 µl |
Buffer RBC | 1X |
Phusion polimerase | 0.3 µl |
RBC Taq polimerase | 0.25 µl |
Water | up to 50 µl |
The program set on the PCR is the following:
PCR Settings | |||
---|---|---|---|
Step | Temperature | Time | Go to |
1 | 94°C | 2 min | |
2 | 94°C | 1 min | |
3 | 62.5°C | 1 min | |
4 | 72°C | 1 min 9 s | Go to Step 2 for 30 times |
5 | 72°C | 7 min | |
6 | 4°C | pause |
PCR mix | |
---|---|
Template | 50ng (at least 0.50µl) |
HF Buffer | 10µl |
dNTPs | 1µl |
Primer Fw (suff) | 2.5µl |
Primer Rv (pref) | 2.5µl |
Phusion | 0.5µl |
Water | up to 50µl |
Given that pSB1C3 is 2070bp long and that the annealing temperature of the primers used is 58°C, the PCR program to be used is the following:
Step | Temperature | Time | Type | Go to |
---|---|---|---|---|
1 | 98°C | 30sec | ||
2 | 98°C | 10sec | Denaturation | |
3 | 58°C | 20sec | Annealing | |
4 | 72°C | 35sec | Extend | Go to step #2 for 30 times |
5 | 72°C | 10min | ||
6 | 4°C | &infinit; |
An overnight culture was diluited 1:100 and grown until O.D.600 reached 0.5. After that, the culture was induced with 5 mM arabinose and placed with a stirrer in a sealed vial (V = 15 ml) with a pierceable septum. The sample was kept for about 4 hours at 37 °C in thermoshaker. After that the sample was connected to the Micro Gas Chromatograph Agilent 3000A endowed with two colums: a Mol Sieve 5A Plot and a Plot U column (see the tables for colums and method specifications).
Column | Lenght | Diameter |
---|---|---|
Mol Sieve 5A Plot | 10 m | 0.32 mm |
Plot U | 8 m | 0.32 mm |
Method used | |
---|---|
t sample | 50 °C |
t injector | 55 °C |
t column Mol Sieve 5A Plot | 110 °C |
t column Plot U | 70 °C |
p column Mol Sieve 5A Plot | 39.16 psi |
p column Plot U | 21.76 psi |
t injection | 40 us |
t analysis | 95 s |
In order to estimate how much gas was taken for each measurement using the settings described above, a mass flow meter was connected to the micro GC. During a measurment, a flow of 3 (± 0.15) ml / min was registered. Due to the fact that a measurment lasts 10 s, the withdrawn volume was 0.5 ml.
An overnight culture was diluited 1:100 and grown until O.D.600 reached 0.5. After that, 3 ml of culture induced with 5 mM arabinose was placed with a stirrer in a sealed vial (V = 15 ml) with a pierceable septum. The sample was then connected to the Micro Gas Chromatograph Agilent 3000A endowed with two colums: a Mol Sieve 5A Plot and a Plot U column (see the tables for colums and method specifications).
Column | Lenght | Diameter |
---|---|---|
Mol Sieve 5A Plot | 10 m | 0.32 mm |
Plot U | 8 m | 0.32 mm |
Method used | |
---|---|
t sample | 50 °C |
t injector | 55 °C |
t column Mol Sieve 5A Plot | 110 °C |
t column Plot U | 70 °C |
p column Mol Sieve 5A Plot | 39.16 psi |
p column Plot U | 21.76 psi |
t injection | 40 us |
t analysis | 95 s |
In order to estimate how much gas was taken for each measurement using the settings described above, a mass flow meter was connected to the micro GC. During a measurment, a flow of 3 (± 0.15) ml / min was registered. Due to the fact that a measurment lasts 10 s, the withdrawn volume was 0.5 ml.
For some days, every morning the culture in the flasks was substituted with a new induced (or not) colture .
Furthermore, canonical jam jars (i.e.: with no connector) were adopted to contain the negative control fruit samples. All the apparatus was put under the chemical hood.
To detect if E. coli actually produced Methyl salicilate (MeSA), we tried both qualitative (SNIFF Test) and quantitative (GC-MS) tests.
All the measurement have to start by inocula in the correct antibiotics (CM) of MeSA producing cells and of normal Neb10β in LB without antibiotic as control. The inocula need to be growth O/N at 37°C in agitation. The following day, dilutions 1:100 were done in falcons with fresh LB and the same antibiotic; the cells were growth at 37°C in agitation until O.D.600≈0.6 was reached.
Then the cells were induced by adding Arabinose 5mM by a solution 1 M prepared by dissolving 0,150 g in 1 mL of dH2O. After two hours in some of the samples was added Salicylic Acid 2mM by a solution 1 M obtained by dissolving 0,138 g in 1 mL ethanol 70%. Then the culture were put for other 2 hours at 37°C in agitation waiting for the 4 hours of induction to pass.
The tests could also been in M9 medium because it smells less than LB. To do this, when cells in LB reached an O.D. of 400 they were centrifuged at 4100 rpm for 10 minutes to form a pellet. The supernatant was discarded and they were resuspended in fresh M9 medium with the correct antibiotic. This was done because E.coli cells growth in M9 in much more time than in LB. The cells were therefore induced with Arabinose and after two hours SA was added where needed.
At this point the samples were ready for different test.