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<p> <h2> Monitoring growth in a multi-well plate reader</h2> | <p> <h2> Monitoring growth in a multi-well plate reader</h2> | ||
Revision as of 07:50, 14 September 2018
Team Göttingen
iGEM 2018
Glyphosate on my plate?
Experiments
Monitoring growth in a multi-well plate reader
For growth experiments with the Synergy MX II multi-well plate reader (Biotek) prepare pre- cultures and grow them over night at 28°C. Next day dilute these cultures (for instance 1:100, 1:500 and 1:1,000) in 1 - 5 ml of the same medium that will be later on used for recording growth curves and incubate them at 37°C (or other temperatures) and 220 rpm. At an OD600 of about 0.2 – 0.5 use the cultures to inoculate a 96 well microtitre plate that has been supplemented with 100 µl medium per well. The outermost wells of the microtitre plate should contain 150 µl of distilled water to avoid that medium containing cells evaporate. Incubate the plate for a maximum of 48 h at the intermediate shaking mode. The OD600 can be detected every 10 to 15 min. It is recommended to do at least three technical replicates per strain and condition on the same plate. Sometimes the detection of the OD can be disturbed by condensing water under the lid and your growth curve will look really strange.
Genetic Modification of Bacteria
Preparation of competent E. coli cells
Method 1 (low amount of competent cells, RbCl)The Material LB liquid medium RF1 and RF2 buffer Liquid nitrogen
The Procedure 1. Inoculate a 4 ml culture either with a single colony or with a cryo culture of the desired E. coli strain and incubate the culture with agitation over night at 37°C. 2. Inoculate a 300 ml shake flask containing 100 ml LB medium with the overnight culture to an OD600 of 0.05 and grow the culture at 37°C until the OD600 is about 0.3. 3. Transfer the cells into two 50 ml Falcon tubes, incubate the cultures for 15 min on ice and harvest the cells by centrifugation for 15 min at 5,000 rpm and 4°C. Discard the supernatants. 4. Re-suspend the cells in 1/3 of the original volume (~16 ml/50 ml) of buffer RF1, incubate the cells again on ice and harvest the cells by centrifugation for 15 min at 5,000 rpm and 4°C. Discard the supernatants. 5. Re-suspend the cells in 4 ml of buffer RF2 and incubate the suspensions for 15 min on ice. Now it is time to label Eppendorf reaction tubes and go and get liquid nitrogen. 6. Put 0.4 ml of the cell suspension into the Eppendorf reaction tubes and freeze the cells by transferring them immediately to the liquid nitrogen. Store the competent cells at -80°C.
Method 2 (fast method, cells cannot be stored, CaCl2)
The Material LB liquid medium 50 mM CaCl2 solution
The Procedure 1. Inoculate a 4 ml culture either with a single colony or with a cryo culture of the desired E. coli strain and incubate the culture with agitation over night at 37°C. 2. Inoculate a 100 ml shake flask containing 10 ml LB medium with the overnight culture to an OD600 of 0.05 - 0.1 and grow the culture at 37°C until the OD600 is about 0.3.Schematic illustration of competent cell preparation. The desired E. coli strain is grown to log phase, pelleted and re-suspended in CaCl2 solution. Now the cells are competent and should be kept on ice all the time. To test the competence of the cells, one aliquot is used to test the transformation efficiency. This is done with a standard plasmid, e.g. pUC19 and a defined amount. Afterwards the efficiency can be calculated.
Method 3 (high amount of competent cells, time-consuming)
The Material
TB buffer (ice-cold, 99 T)
LB liquid medium (93 A)
SOB -Mg (93 J)
1 M MgCl2
1 M MgSO4
DMSO (100 %)
The Procedure
1. Inoculate a 20 ml culture either with a single colony or with a cryo culture of the desired
E. coli strain and incubate the culture with agitation for 20 h at 28°C.
2. Inoculate* 250 ml SOB medium supplemented with 10 mM MgCl2 and 10 mM MgSO4 in
a 2 l shake flask and grow the cells to an OD600 of 0.5 – 0.9 (20 – 24 h) at 18°C and 200 –
250 rpm.
3. Incubate the whole flask for 10 min on ice. Collect the cells by centrifugation for 10 min
at 4°C and 5,000 rpm. Re-suspend the cells in 80 ml of ice-cold TB and incubate them for
10 min on ice. Collect the cells by centrifugation for 5 min at 5,000 rpm.
4. Re-suspend the cells in 20 ml of ice-cold TB. Add DMSO to a final concentration of 7 %
(1.4 ml) by gently shaking the Falcon tube.
5. Transfer 0.2 ml aliquots into labeled Eppendorf reaction tubes and freeze the cells in
liquid nitrogen. Store the cells at -80°C.
*) The volume of the pre-culture strongly depends on the E. coli strain. Using DH5a it is
recommended to use 4 ml pre-culture and inoculate at 8 a.m. Next day around 10 a.m. this
strain should have reached an OD600 between 0.5 and 0.6. If you use the strain XL1-Blue, you will
need less cells and it is sufficient to inoculate the SOB medium around lunchtime.
Transformation of E. coli
The MaterialLB medium
LB agar plates supplemented with the appropriate antibiotics
The Procedure
1. Put your ligation samples on ice, defreeze 100 ml of your competent E. coli cells on top of
the ice and add the cells to your ligation samples. Mix it carefully!
2. Incubate the Eppendorf reaction tubes for 30 min on ice, transfer the tubes for 90 sec to
42°C (heat shock) and put them back on ice for 5 min.
3. Add 500 ml LB medium to the cells, transfer them to 15 ml Falcon tubes (or in sterile
1.5 ml Eppendorf reaction tubes) and incubate the cell for 1 h at 37°C with agitation.
4. Propagate 50 ml of the cells on LB medium agar plates supplemented with the
appropriate antibiotics. The remaining cells are collected by centrifugation for 1 min at
13,000 rpm and remove 400 ml of the supernatant. Re-suspend the pellet in the
remaining 50 ml of the supernatant and propagate the cells on the same LB medium agar
plates. It is highly recommended to do a negative control (only cells, no DNA).
5. Incubate the plates over night at 37°C. The plates should be stored after incubation over
night at 4°C to avoid the emergence of satellite colonies.
Preparation and transformation of competent B. subtilis cells
The Material
LB medium
MN medium
MNGE medium
Expression mix
Glucose (20 %)
1 M MgSO4
CAA (10 %)
The Procedure
Preparation of competent cells
1. Inoculate 4 ml LB liquid medium with a single colony of a B. subtilis strain and incubate
the culture over night at 28°C with agitation.
2. Use the overnight culture to inoculate 10 ml MNGE medium supplemented with 0.1 %
CAA in a 100 ml shake flask to an approximate OD600 of 0.1. Incubate the culture at 37°C
and 220 rpm until an OD600 of about 1.3. This may take up to 5 h, depending on the
strain.
3. Dilute the culture 1:1 with pre-warmed MNGE (w/o CAA) and incubate the culture for
another h at 37°C on a shaker.
You can continue with the transformation of B. subtilis directly after the nutritional
starvation step (see Transformation of B. subtilis, step 7) or continue for long term
storage.
4. Transfer 15 ml of the culture to 15 ml Falcon tubes and harvest the cells by
centrifugation for 5 min at 5,000 rpm. Transfer the supernatant into a sterile Falcon
tube.
5. Re-suspend the cells in 1.8 ml of the supernatant, add 1.2 ml 50 % glycerine, mix the cell
suspension and store the competent cell in 300 ml aliquots at -80°C.
6. Thaw an aliquot of the frozen, competent bacteria and mix 300 μl of them with 1.7 ml
1x MN medium that has been supplemented with 43 μl glucose (20 %) + 34 μl 1 M
MgSO4.
7. Add 0.1 - 1 μg DNA (2 mg plasmid DNA) to 400 µl of the competent cells and incubate the
reaction tube for 30 min at 37°C.
8. Add 100 μl expression mix and if required an inducer (IPTG, xylose,…).
9. Incubate the bacteria for 1 h at 37°C with agitation and propagate the cells on
SP medium agar plates supplemented with the appropriate antibiotics
Remarks: Do not forget the negative control!!!
Working with DNA
Preparation of chromosomal DNA from B. subtilis
here are different methods available for the isolation of chromosomal DNA. We will use the peqGOLD Bacterial DNA Kit from PEQLAB for the preparation of chromosomal DNA. The amount of DNA that will be obtained using this kit is much lower than that obtained with the standard phenol/chloroform extraction. However, the kit was designed for rapid purification of phenol- free total DNA, which is sufficient for PCR, cloning and even genome sequencing.
The Material
Lysis buffer
RNase A solution
EtOH (100 %, ice-cold)
peqGOLD Bacterial DNA Kit
The Procedure
1. Inoculation of 10 ml LB medium supplemented in a 100 ml shake flask with a single colony of B. subtilis. The overnight culture has to be incubated with agitation (220 rpm) at 37°C.
2. Collect the cells from 1.5 to 2 ml of the overnight culture in Eppendorf tubes by centrifugation for 2 min at 13,000 rpm. Discard the supernatant and re-suspend the cells in 200 ml lysis buffer.
3. Incubate the mixture for 30 - 60 min at 30°C in the lysis buffer to destroy the cell wall.
4. Spin down the cells for 5 min at 4,000 g and discard the supernatant. Re-suspend the pellet in 400 µl DNA Lysis Buffer T and add 20 µl Proteinase K and 15 µl RNase A. Vortex for 10 seconds.
5. Incubate the sample for 30 min at 70°C on a shaker. Without thermo-shaker, vortex 3 times for 10 seconds in the incubation time.
6. Add 200 µl of the DNA Binding Buffer and mix gently. Add the whole sample to the column (with all the precipitants). After centrifugation for 1 min at 8,000 – 10,000 rpm, discard the flow through. Put the remaining solution into the column and repeat the centrifugation step.
7. Wash the DNA on the column with 650 ml with the DNA Wash Buffer complemented with EtOH. Each time, centrifuge for 1 min at 8,000 – 10,000 rpm and discard the flow trough.
8. Place the empty DNA column into the collection tube and centrifuge for 2 minutes at 8,000 – 10,000 rpm. This step is essential! Do not reduce the time!
9. Place the column into a new 1.5 ml Eppendorf reaction tube. To elute the DNA, add 50 ml of buffer Elution Buffer (or sterile HPLC-H2O) that has been pre-warmed to 70°C and incubate the column for 3 min at room temperature. Collect the DNA by centrifugation for 1 min at 8,000 rpm.
10. To increase the amount of chromosomal DNA, you may add a second time your first elution to the column or add again 50 µl Elution Buffer or water and centrifuge again for 1 min at full speed.
Isolation of plasmid DNA from B. subtilis (K. Gunka) The cell wall of the Gram-positive bacterium B. subtilis cannot be disrupted as easy as that of a Gram-negative bacterium like E. coli . Therefore, lysozyme has to be added to the re-suspension buffer A1. Lysozyme is a glycoside hydrolase that catalyzes the hydrolysis of 1,4-b-linkages between N-acetylmuramic acid and N-acetyl-D-glucosamine residues in the peptidoglycan.
The Material
Liquid LB medium
1. Use a single colony from your B. subtilis plate to inoculate 4 ml LB liquid medium supplemented with the appropriate antibiotic and grow the culture over night at 37°C with agitation.
2. Collect the cells from 2 ml of the overnight cultures by centrifugation for 1 min at 13,000 rpm. Re-suspend the pellet in 250 µl of buffer A1 with lysozyme und incubate for 15 min at 37°C. Add 250 ml of buffer A2, mix gently 6 – 8 times and incubate the suspension for 5 min at room temperature.
3. Add 300 ml of buffer A3, mix gently 6 – 8 times and centrifuge the lysate for 10 min at 13,000 rpm.
4. Transfer the supernatant into a NucleoSpin® plasmid column, centrifuge for 1 min at 13,000 rpm and discard the flow-through.
5. Add 500 ml buffer AW pre-heated to 50°C to the column, centrifuge for 1 min at 13,000 rpm and discard the flow-through.
6. Add 600 ml of buffer A4, centrifuge for 1 min at 13,000 rpm and discard the flow- through.
7. To dry the silica membrane, centrifuge again for 2 min at 13,000 rpm.
8. Put the column in a sterile Eppendorf reaction tube and add 50 µl of HPLC water pre-heated to 70°C on top of the silica membrane of the column, incubate the column for 5 min at room temperature and elute the DNA by centrifugation for 1 min at 13,000 rpm.
9. Quantify the plasmid DNA with the Nanodrop spectrophotometer. The DNA can be stored at -20°C.
If the concentration of the plasmid DNA is too low for sequencing (less than 50 ng/µl) you can transform E. coli with the plasmid and isolate the plasmid again.
Isolation of plasmid DNA from E. coli
The Material
Liquid LB medium
NucleoSpin® plasmid kit, Macherey & Nagel
The Procedure
1. Use single colonies from your transformation plates to inoculate 4 ml (15 – 20 ml for
low-copy plasmids) LB liquid medium supplemented with the appropriate antibiotic and
grow the culture over night at 37°C with agitation.
2. Collect the cells from 1.5 ml (15 ml for low-copy plasmids) of the overnight cultures by
centrifugation (1 min, 13,000 rpm). Re-suspend the pellet in 250 ml of buffer A1, add
250 ml of buffer A2, mix gently 6 – 8 times and incubate the suspension for 5 min at
room temperature. For the isolation of low-copy plasmids add 500 ml of buffers A1 and
A2 to the cells.
3. Add 300 ml (0.6 ml for low-copy plasmids) of buffer A3, mix gently 6 – 8 times and
centrifuge the lysate for 5 – 10 min at 13,000 rpm.
4. Transfer the supernatant into NucleoSpin® plasmid column, centrifuge for 1 min at
13,000 rpm and discard the flow-through.
5. (Optional: for sequencing of low-copy plasmid DNA add 500 ml buffer AW to the column,
centrifuge for 1 min at 13000 rpm and discard the flow-through.)
6. Add 600 ml of buffer A4, centrifuge (1 min, 13,000 rpm) and discard the flow-through.
7. To dry the silica membrane, centrifuge again for 2 min at 13,000 rpm.
8. Add 50 ml of sterile and deionized water on top of the silica membrane of the column
incubate the column for 1 - 5 min at room temperature and elute the DNA by
centrifugation for 1 min at 13,000 rpm.
9. The plasmid DNA is highly pure and can be stored at –20°C.
Concentration and purity of DNA/RNA samples
Determination of DNA/RNA concentration
A reliable method for the quantification of DNA
and RNA is essential for our work in the lab. The
concentration of nucleic acids can be determined
by fluorescence and absorption spectroscopy.
The quantification of nucleic acids by
fluorescence spectroscopy relies on binding to
fluorescent dyes, e.g. ethidium bromide. This
method is very sensitive (10 – 100 ng of DNA can
be detected) but time-consuming. This is the
reason that DNA is mainly quantified by absorption spectroscopy. DNA can be quantified by
absorption spectroscopy because it absorbs ultra violet (UV) light with a maximum at the
wavelength of 260 nm. However, RNA absorbs UV light also at 260 nm and aromatic amino acids
at 280 nm what means that both can contaminate your measurements. Therefore, it is
important to determine the purity of your samples.
The purity of the DNA preparation
The quantification of DNA makes only sense if the sample is pure. The purity of the sample can
be evaluated by recording a spectrum of your DNA solution in the range between 220 and
320 nm. Proteins in the sample absorb light at 280 nm and cause a reduction of the A260 nm/A280
nm ratio. If the DNA sample is pure, this ratio is in the range of 1.8 – 2.0. A strong peak at 230
nm can indicate contamination with organic compounds or chaotropic salts.
Absorbtion spectrum of double stranded DNA|
The spectrum from 220 nm to 320 nm gives
information about purity of the DNA sample.
The Material
Nanodrop ND-1000 Spectrophotometer
DNA/RNA sample
Sterile water
The Procedure
1. Clean the measurement pedestal (it contains the receiving fibre) with deionized water
and pipette 1 ml of water on top of it.
2. Close the lid (sampling arm). Now the upper measurement pedestal (it contains the
second fibre optic cable) is brought into contact with the liquid sample causing the liquid
to bridge the gap between the two fibre optic ends. The gap is controlled to both 1 and
0.2 mm paths.
3. Initiate a spectral measurement using the operating software on the connected PC by
pressing the “blank” button to blank the Nanodrop. A pulsed xenon flash lamp will
provide the light source and the spectrophotometer analysis the light after passing
through the sample. After the measurement the data is logged in an archive file on the
PC.
4. When the blanking is done, open the sampling arm and wipe the sample from both the
upper and lower pedestals using a soft laboratory wipe. Wiping prevents sample
carryover in successive measurements for samples varying by more than 1,000-fold in
concentration.
5. Pipette 1 ml your DNA sample and press the “Measure” button to determine the amount
of DNA in your sample.
6. Remove the DNA solution from the measurement pedestal and clean the lid and the
pedestal with deionized water.
Agarose gel electrophoresis
Linear and double-stranded DNA molecules can move through a gel matrix with a velocity that is proportional to the logarithm of their molecular weight (MW). Therefore, the MW of unknown DNA species can be determined by comparing their electrophoretic mobility with that of DNA molecules having known MWs. DNA molecules with lengths ranging from 0.5 kbp to 25 kbp can be separated using agarose gels.
Voltage0: The velocity with that DNA molecules move through a gel matrix depends on the
applied voltage. It is important to know that the velocity of large DNA molecules increases more
rapidly than that of small DNA molecules. As a consequence, large molecules can be separated
from each other with a high accuracy at low voltages.
The electrophoresis buffer: Most gel systems are based on Tris-Acetate-EDTA (TAE) and
Tris-Borat-EDTA (TBE) buffers. The electrophoretic mobility of DNA molecules is quite similar in
both buffers. However, the buffering capacity of the TBE buffer is significantly higher. Therefore,
it is recommended to use TBE buffer for mini-gels that run at a high voltage.
The DNA conformation: Supercoiled, nicked and linear DNA molecules, having the same
molecular mass move with different velocities through the gel matrix. Because supercoiled DNA
has the smallest hydrodynamic radius, these DNA species show the highest electrophoretic
mobility.
1x TAE buffer or 1x TBE
5x DNA loading dye
Agarose
HDGreen® Plus Safe DNA Dye or Midori Green
The Procedure
1. Prepare a 100 ml mixture of 1 % agarose in 1x TAE. Carefully heat the mixture in a
microwave to dissolve the agarose. You can either store the agarose solution at 65°C or
cool it down to room temperature and heat it again for the next gel.
2. Now it is important to wear gloves.
Add 3 µl of the HDGreen® Plus Safe DNA Dye to 30 ml dissolved agarose and pour the
gel in a small custom-made gel chamber.
3. While the gel is cooling down, prepare your DNA samples by mixing 2 – 5 µl of your DNA
solution with 0.4 – 1 µl of loading dye, either in Eppendorf reaction tubes or in a multi-
well microtitre plate.
4. Remove the comb from the cold gel, add 1x TAE/TBE buffer into the chamber and load
the slots with your DNA samples. Do not forget the size standard (λ-marker or
commercial 1 kb DNA ladder).
5. Connect the gel chamber with the power supply and switch it on. Adjust the voltage to
100 – 130 V and press the start button.
6. If the stain bromphenol blue has passed ¾ of the gel, you should switch off the power
supply and check your gel under UV light. Safe picture and print result for lab book.
7. If possible, take a picture for the group seminar and your lab notebook.
8. You can also stain your gel after the run has finished in a 1 % aqeous HDGreen® Plus Safe
DNA Dye or Midori Green solution for 10 - 30 min at room temperature.
Ethidium bromide staining
To stain a agarose gel with Ethidium bromide you have to replace step two and stain the gel
after running with the following procedure:
1. Put on one glove and transfer the gel into the staining solution (0.5 µg/ml of Ethidium
bromide in water). After 10 min you can destain the gel in the water bath.
2. After 10 – 30 minutes of destaining you may analyze your agarose gel, either on a UV
table or with a gel documentation device (imager).
Error sources
The DNA molecules were separated with low accuracy. Wrong agarose concentration; low
voltage may cause diffusion of DNA molecules due to a long run.
Smearing bands. Too much DNA has been loaded to the slots; the applied voltage has been too
high. The gel looks smeared at all, you might touched the gel directly with your hands.
The gel was melting. Even old lab veterans sometimes use water instead of 1-fold TAE to
dissolve agarose. You should also regularly refresh the TAE buffer inside the running chamber.
Further information concerning the HDGreen® Plus Safe DNA Dye
Security precaution: Ethidium bromide is commonly used to stain nucleic acids in molecular
biology laboratories. However, this agent is highly mutagen and therefore considered as
hazardous. As alternative staining method we use HDGreen® Plus Safe DNA Dye. According to
the manufacturer (INTAS) this dye does not contain substances which at their given
concentration, are considered to be hazardous to health. Nevertheless, this dye stains DNA and
every DNA staining substance should be treated carefully and only with gloves.
Disposal considerations: The waste must be disposed of in accordance with federal, state and
local environmental control. Therefore, the gels are collected in a container next to the imager.
Purification of DNA fragments
PCR purification kit
The Material
DNA product(s) or linearized plasmid(s)
peqGOLD Cycle-Pure Kit
The Procedure
1. Add an equal volume of CP Buffer to your DNA solution. For fragments < 200 bp add
3 volumes of CP Buffer for better results.
2. Transfer the mixture to a spin column and centrifuge for 1 min at 13,000 rpm. Discard
the flow-through and add 750 µl CG Wash Buffer.
3. Centrifuge for 1 min at 13,000 rpm, discard the flow-through and repeat the steps 2 and
3 once.
4. Centrifuge again to dry the silica membrane 2 minutes at 13,000 rpm.
5. Put the column into a labeled Eppendorf reaction tube, add 30 - 50 µl of water (not less
than 30 µl) on top of the silica membrane, incubate for 5 min at room temperature and
elute the DNA by centrifugation for 1 min at 13,000 rpm. Please keep in mind that you
have to add less water if you want to elute the DNA from a restriction analysis! Always
check the purified DNA by agarose gel electrophoresis to make sure that you did not
lose the DNA. Determine the DNA concentration and the purity.
Concentration of DNA samples
You can concentrate your DNA sample if the amount is too low. Therefore add 1 M NaCl to a
final concentration of 0.1 M and add two volumes of 100 % EtOH. Vortex your samples and
spin down for 15 minutes at 13,000 rpm. The supernatant can be discarded. Add then 700 µl
70 %age EtOH and centrifuge again for 2 min at 13,000 rpm. Let the EtOH evaporate at room
temperature. Now you can dissolve your pellet in water.