Team:Goettingen/Notebook/reporterSystems June

General procedure to determine β-galactosidase activity.

1. Propagate a single colony over a whole SP agar plate and incubate the plate over the day at 37°C. You could also propagate a single colony on an SP agar plate in the evening and use the plate at the evening next day to inoculate a pre-culture.
2. Take a single colony of the B. subtilis strain of interest and inoculate 2&nadsh;5 mL C minimal medium supplemented with appropriate antibiotics and effectors (carbon and nitrogen sources). Incubate the pre-cultures over night at 28°C with agitation (220 rpm).
3. Inoculate 10 mL C minimal medium (plus effectors, carbon and nitrogen sources) supplemented in a 100 mL shake flask to an OD₆₀₀ of about 0.1 and grow the cultures to an OD₆₀₀ of 0.5–0.8 (3–5 h) at the desired temperature (usually at 37°C for B. subtilis).
4. Collect the cells from 1.5–2.0 mL of the cultures by centrifugation for 5 min at 13,000 rpm and 4°C. Discard the supernatants and store the cell pellets for further treatment at -20°C.
5. Re-suspend the cells in 400 mL Z buffer (with β-ME and 20 mL LD-Mix in 4 mL Z buffer). Incubate the suspension for 10 min at 37°C to lyse the cells. Keep a minimum of 20 mL Z buffer/LD-Mix for the Bradford assay.
6. Remove cell debris from the soluble fraction by centrifugation for 2 min at 13,000 rpm and 4°C. Transfer the supernatants into new Eppendorf reaction tubes.
7. Add 100 mL of the cell free crude extract to 700 mL Z buffer (with β-ME) and pre-incubate the mixture for 5 min at 28°C. 800 mL Z buffer (with β-ME) will serve as the reference.
8. Start the enzymatic reaction by the addition of 200 mL ONPG to the reaction tubes and note the time.
9. As soon as the reaction mixture turns yellow, stop the reaction by adding 500 mL Na₂CO₃ and note the time. Now it is time to measure the absorption of the sample at a wavelength of λ = 420 nm. The “reference sample” will serve as the reference!
10. The specific β-galactosidase activity in Miller Units/mg protein (MU/mg) can be calculated using the formula below:

                       <img src="">
                       <p>A420: absorption of o–Nitrophenol; Δt: time difference between start and stop of the enzymatic reaction in [min]; V: volume of crude extract used for the reaction (usually 0.1 mL, see step 3); A595: absorption at λ = 595 nm obtained by the Bradford assay.</p>
    

                   The method to detect the β–galactosidase activity can also be applied to detect the enzymatic activity of the β–xylosidase in cell freee crude extract of B. subtilis (Lindner et al., 1994). To detect β–xylosidase activity, ONPG has to be replaced by PNPX.
    

       <p>The following table shows the samples used for the lacZ–assay.</p>

       <p>Samples were inoculated with and without tryptophane.</p>

       <p>2x 2 mL of each sample was centrifuged at 13,000 rpm at 4°C. Pellets were stored at -20°C.</p>

       <p>The lacZ–assay was carried out as described previously. There was not change in coloration observeable, therefore the experiment has to be repeated. The Bradford assay was carried out to verify that the cells are lyzed using the LD mix. It came out that all samples contained proteins.</p>
       <p>Furthermore, B. subtilis strain 168 was transformed with pBQ200 (as an isogenic control) and pIGEM2.</p>

       <p>Cultures were prepared for RNA sequencing. OD600 measurement of the two ON cultures.</p>

       <p>Culture 2 was used to inoculate 6x CS-Glu –trp media. 150 µL 50 mM glyphosate solution was added to cultures 4–6 to obtain a concentration of 0.75 mM.</p>

       <p>1 mL cells were harvested at 4°C with centrifugation for 2 min at 13,000 rpm. The supernatant was descarded, and the pellets were placed into liquid nitrogen. Storage at -20°C.</p>
       <p>Furthermore, a PCR was performed to amplify PtrpP with primers iGEM2018_23 and iGEM2018_24. The template was chromosomal DNA from the wildtype 168. The results are shown in the figure below. The samples were purified and eluted in 35 µL H2O and measured with the Nanodrop device.</p>

           <img src="">
           <p>In all four lanes are samples of PtrpP.</p>

       <p>To measure the β-galactosidase activity, the strains 168_pIGEM3, SP1_pIGEM3, GP342, and GP650 were propagated on LB agar plates and grown over night at 37°C.</p>

       <p>Strains GP342 (200–300 MU/mg protein) and GP350 (10–20 MU/mg protein) serve as a positive control for the β-galactosidase assay. 4 mL LB medium were inoculated from the plates and incubated at 37°C over daytime. In the evening, the cells were transferred into 3 mL CS-Glu medium and incubated over night at 28°C.</p>
       <p>PtrpP was digested with the restriction enzymes BamHI and EcoRI as described before. The samples were purified and eluted in 30 µL H2O and measured with the Nanodrop device. Furthermore, the fragment was ligated into the vector pAC7 as described before.</p>

       <p>OD600 measurement of the over night cultures.</p>

       <p>The OD600 was measured.</p>

       <p>Competent E. coli DH5α cells were transformed, a negative control was also performed. The transformed cells were propagated on LB agar containing ampicilin and X-Gal.</p>
       <p>OD600 measurement for the β-galactosidase assay n=3.</p>

       <p>For the strains, the Miller units per mg protein were calculated with the formula given previously.</p>

       <p>The plasmids from 21.06.18 were isolated, eluted in 30 µL H2O, and the concentration was measured with the Nanodrop device. A sample was sent for sequencing with the primers lacZ-rev and ML107.</p>

       <p>B. subtilis strain SP1 was made competent as described previously. The cells were transformed with chromosomal DNA of GP650. The transformed cells were propagated on SP agar containing the appropriate antibiotics.</p>

       <p>Transformations from 26.06.18 were separated on SP agar containing the appropriate antibiotics. Sequencing of pAC7_PtrpP was succesful and the plasmid was named "pIGEM5".</p>

Isolation of chromosomal DNA from Bacillus subtilis

       <p>The protocol requires the "Bacterial DNA kit" from "peqGOLD".</p>

1. Inoculate 4 mL LB medium with the cells of interest and incubate them over night at 37°C. Harvest the cells with centrifugation.
2. Resuspend the pellet in 100 µL TE buffer and add 100 µL lysozyme. Incubate the reaction for 1 h at 30°C and 800 rpm.
3. Centrifuge the samples for 5 min at 6,500 rpm, discard the supernatant. Resuspend the pellet in 400 µL DNA lysis buffer T.
4. Add 20 µL proteinkinase K and 15 µL RNase A. Shake the samples vigorously and incubate them for 30 min at 70°C.
5. Add 200 µL DNA binding, mix the sample and load it on the column tube. Centrifugation at 11,000 rpm. Discard the flowthrough and place the column in a new collection tube.
6. Add 650 µL DNA wash buffer on the column and centrifuge for 1 min at 11,000 rpm. Discard the flowthrough.
7. Dry the column for 2  centrifugation at 11,000 rpm.
8. Place the column in a sterile Eppendorf cup, add 50 µL sterile H₂O, incubate the column for 1 min and centrifuge at 7,900 rpm. Repeat this step.
9. To avoid spores in the DNA, centrifuge the samples 10–30 min at 13,000 rpm at 4°C.
10. Store the supernatant at -20°C.

       <p>Strain SP1 was transformed with pIGEM5 and chromosomal DNA from strain GP342.</p>

       <p>Transformations from SP1 + DNA from GP650 worked well, so two clones were picked and separated. </p>