Team:Calgary/Notebook/PromoterScreen

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Transposon Library Notebook

Week 1 (May 1-4)

  This was the first week where we met with other team members and summarized the primary subprojects the team will be tackling this coming summer.

Week 2 (May 7-11)

  During this week literature search was performed.

Week 3 (May 14-18)

  During this week literature search was performed.

Week 4 (May 22-25)

  During this week, strains of Pseudomonas fluorescens PF-5 were obtained. Two cultures were started by adding 500 µL stock to 10 mL LB media containing 50 mg/L ACROS Naphthenic Acids. These cultures were grown at 30°C overnight, shaking at 110 rpm.

  Overnight cultures were then streaked on LB agar the following day with various types and concentrations of antibiotics in order to determine the susceptibility profile of the organism. This was necessary in order to determine what marker could be used on a transposon to allow for selection of organisms with sucessful transposon insertions. These plates were grown overnight to look for death or growth, and the following results were obtained;

Gentamycin Kanamycin Chloramphenicol Tetracycline
25 µg/ml = no growth 5 µg/ml = slight growth 5 µg/ml = growth 50 µg/ml = no growth
50 µg/ml = no growth 10 µg/ml = slight growth 10 µg/ml = growth 100 µg/ml = no growth
100 µg/ml = no growth 25 µg/ml = no growth 25 µg/ml = growth 200 µg/ml = no growth
50 µg/ml = no growth 50 µg/ml = growth



  Based on these results, it was determined that Kanamycin, Gentamycin, and Tetracycline could be used as the selectable marker on the transposon, while Chloramphenicol could not as the strain is naturally resistant. Glycerol stocks of the strains were also made at this time from a fresh overnight culture.

Week 5 (May 28-June 1)

  At the beginning of this week we spoke to Dr. Michael Hynes, who was able to give us E. coli SM10 and SM17-1 cells containing the plasmid pOT182. This plasmid contains an E. coli origin of replication, allowing it to act as a suicide vector when transferred to a different bacterial species. pOT182 contains a Tn5 transposon element containing a promotorless lacZ gene, genes for tetracycline resistance as well as a beta-lactamase, and also transposase and an E. coli origin of replication. These elements are bordered by insertion element sequences which are recognised by the transposase. When transferred to a different host through conjugation, the plasmid itself can no longer replicate. The transposase however can recognise and transfer the sequence between the insertion elements in a cut-and-paste fashion randomly into the genome. In this fashion, the tetracycline and beta-lactam resistant traits would only persist in cells in which the transposon has jumped into the genome, allowing these antibiotics to select for transposon positive cells. The lacZ protein will only be produced if the transposon jumps in frame downstream of a promotor, and in this case would allow for a lacZ based assay of the promotors response. The E. coli origin of replication present in the transposon allows for the self-cloning of the transposon in a plasmid format after genomic digestion and circularization and transformation into E. coli, allowing for the sequence of bordering gene fragments to be determined easily and therefore mapping the transposon in the genome.

  Cultures of E. coli SM10 and P. fluorescens PF-5 were grown up overnight in shakers at 37°C and 30°C respectively. SM10 was grown in LB + 10 µg/ml Tet, and PF-5 was grown in LB + 50 mg/L ACROS naphthenic acids. In the morning, the SM10 culture was subcultured (1/4) into LB without antibiotics and allowed to grow for an additional 4h. After this, 3 replicates of mating mixtures were made with 500 µl of each culture were mixed, and the cells were spun down and resuspended in 50 µl of LB. These samples were then plated in separate spots on LB agar. Additional spots were made in the same fashion with just PF-5 culture and just SM10 culture as controls, and the plate was incubated at 37°C overnight. In the morning, each spot was resuspended in 500µl sterile water + 25 µg/ml Tet, and dilutions of 1, 1/10, 1/100, and 1/1000 of each mating mixture was plated on Pseudomonas Isolation Agar (PIA) + 10µg/l Tet + 50 mg/L ACROS naphthenic acids. These cultures were allowed to grow at 30°C over the weekend.

  The purpose of the PIA is to selectively allow the growth of the PF-5 strain, while killing off the donor SM10 strain. The tetracycline is designed to select for the positive transposon mutants in the PF-5 strain, as the only way that tetracycline resistance would be acquired (barring spontaneous mutation events) would be if the transposable element had jumped into the genome of the cell. We decided to use 10 µg/ml as the concentration of the tetracycline in the plates because we believed that 50 µg/ml would be too high for even strains carrying resistance to survive. Seeing as 10 µg/ml was effective for E. coli, we chose to try this. After streaking the PF-5 culture on the plate to test for its resistance however, it was found that the strain without the transposon was able to grow slightly on the plates, meaning that the concentration of antibiotic is not high enough to properly select for transposon mutants v.s. untransformed cells. In order to try to remedy this, the mating spots were resuspended in a mixture containing a higher dose of antibiotics. The results of this experiment are pending.

Week 6 (June 4-8)

  When the plates from last week were examined, it was found that though the PIA was sucessful in inhibiting the growth of the E. coli donor strain, the original PF-5 strain was capable of growth on the media. Because of this, the plates were not selective towards cells containing the transposon insertion, and thus lawns of bacteria were seen on each of the plates.

  Because of this, new selective media plates were prepared. These contained LB agar + 50 mg/L ACROS NA's + 50 µg each chloramphenicol and tetracycline. The chloramphenicol was used in order to kill off the SM10 donor strain, while the tetracycline was used at a concentration previously shown to kill off the PF-5 cells that did not contain a transposon insertion. The conjugation procedure previously described was repeated, with 1 replicate mating spot being plated in 4 different dilutions on the new selective media. These plates were grown overnight at 30°C. It was found that both SM10 and unmodified PF-5 were not capable of growth on the new selective plates, and colonies were found growing on all 4 of the dilutions for the mating spot.

Figure caption

  Because the host and the untransformed cells were not capable of growth on the selective plates, it is believed that these colonies must represent sucessful transposition events, as this would be the only way that the tetracycline resistance would be transfered to the PF-5 cells (chloramphenicol would have no effect, as PF-5 cells are naturally resistant at this concentration, as previously shown.). Because the cell density was too high, the 1 and 1/10 dilution plates were discarded, while the 1/100 and 1/1000 plates were stored at 4°C until the next step of the procedure, in which screening for naphthenic acid response will be performed.

Week 7 (June 11-15)

  In order to test for a naphthenic acid response, a lacZ reporter system in the transposon will be utilized. Because the lacZ enzyme is capable of degrading X-gal, a dissacharide sugar containing lactose, into lactose, and an insoluble sugar (5,5'-dibromo-4,4'-dichloro-indigo), which appears blue. Therefore, in response to activation of a native gene promotor, in frame transposon insertions will produce lacZ at levels corresponding to the activation level of the gene, and these colonies will be able to utilize lactose as a carbon source as well as utilize Xgal as a substrate. Cells responding to naphthenic acids will therefore show blue pigmentation and be capable of growth on lactose. Those that do not respond should remain white, and perish when lactose is given as the only sugar source.

  The concentration of naphthenic acids used in the test plates will be 4x less than the minimal inhibitory concentration (MIC). Therefore, a MIC assay for naphthenic acids with PF-5 cells was carried out overnight at 30°C at 2%, 1%, 0.5%, 0.25%, and 0.125% concentrations in LB media. It was found that PF-5 grew well at all these concentrations; therefore 1% was arbitrarily picked for the test conditions for naphthenic acid response plates.

Plates were made as follows, with Xgal spread on top:

Wild-Type PF-5 Controls
M9 Minimal Media Alone, M9 Minimal Media + 0.4% Glucose, M9 Minimal Media + 0.4% Lactose, M9 Minimal Media + 1% NA's
Transposon Replica Plates
M9 Minimal Media + 0.4% Glucose + Chlor, M9 Minimal Media + 0.4% Glucose + Chlor + 1% NA's, M9 Minimal Media + 0.4% Lactose + Tet, M9 Minimal Media + 0.4% Lactose + Tet + 1% NA's



  Colonies from the 1/1000 transposon plate were replica stamped using velvet cloth onto the transposon test plates, and WT PF-5 was streaked onto the controls. The plates were allowed to grow over the weekend at 30 °C.

Week 8 (June 18-22)

  The plates from the previous week were observed on Monday. WT PF-5 grew on M9 + Glucose, but not on any of the other controls, indicating that the wild-type strain could not utilize lactose, indicating that this could possibly be used as a selection measure for responses from the transposon mutants.

  No growth was observed on any of the transposon test plates. This was believed to be likely from poor transfer during stamping, resulting from a poor contact with the plates in addition to a grease layer formed by the undissolved naphthenic acids. Because of this, a new method of creating plates had to be determined.

  We tried to dissolve NAs in DMF and both spread this mixture on top of agar plates as well as mix it into the liquid agar before pouring plates. Though this helped to solubilize the naphthenic acids, it was not as effective as increasing the pH of the media (pH 8 was found to be effective). We made M9 media at pH 8 before making the same set of test plates as before. It was found that the NAs stayed in solution when mixed, however came out of solution when the plates dried, leading to a grease layer on the plates as previously seen.

  In another attempt to raise the pH, stock solutions of NAs dissolved in NaOH at pH 12 were made, and these were autoclaved alongside the media. When NAs were added to the NaOH, the solutions became cloudy and uniform, indicating they were in solution. When the NA stocks were added to the media before plate pouring, the NAs remained in solution even after the plates dried, indicating that this method would be sucessful in making test plates. Using this method, the following plates were created:

Wild-Type PF-5 Controls
M9 Minimal Media Alone, M9 Minimal Media + 0.2% Glucose, M9 Minimal Media + 0.2% Lactose
Transposon Replica Plates
M9 Minimal Media + 0.2% Glucose + Chlor, M9 Minimal Media + 0.2% Glucose + Chlor + 0.05% NA's, M9 Minimal Media + 0.2% Glucose + Chlor + 1% NA's, M9 Minimal Media + 0.2% Lactose + Tet, 0.2% Lactose + Tet + 0.05% NA's, M9 Minimal Media + 0.2% Lactose + Tet + 1% NA's



  Xgal was spread on all the plates with NA's, however it was left out of the controls by mistake. Stamping was carried out as previously described from both the previously created 1/100 and 1/1000 dilution plates of transposon mutants (A new round of transposon mutagenesis was initiated, but the mating mixture was incubated at 30°C instead of 37°C, and no mutants were obtained on the selective plates). These plates were allowed to grow over the weekend at 30°C.

Week 9 (June 25-June 29)

Growth was observed from the selection plates incubated over the weekend at 30°C. Screening replica plates are made as before. The 1/1000 diluted transposon plate was used for the replica plating on all the screening conditions. The screening plates are incubated overnight at 30°C. The next day, no growth was observed on the negative control plates (M9 alone, M9 with 0.05% NAs), and no growth was observed on the positive control plates containing glucose. Similarly, no growth was observed on the M9+lactose (+Tet, with/without X-GAL, with/without 0.05% NAs). This suggests that either the a large number of matings is needed before a desirable transconjugant is seen, or that the media condition requires modification. The plate surface is not as greasy as before, which suggests that the replica plating transfer process works. However, the pH of the media may affect the growth of transconjugants. Plans are made to modify the pH of the media before replica plating.

Week 10 (July 2-July 6)

Replica plating screening plates are made so that NA stock solutions (1% at pH 12 diluted to 0.05% final concentration) were added to the M9 agar solution. The pH is adjusted to 7.4 before autoclaving. The pH prior to adjusting is approximately 9.0. This may explain the poor growth observed in the previous trial. A new series of mating were started (2 mating spots), and incubated overnight at 37°C. The mating spots are scraped and serial diluted up to 1/1000, plated on LB+Chlor50+Tet50, and incubated overnight at 30°C. This time, the results are consistent with the previous attempt, where no growth was observed on the negative control plates (M9 alone, M9 with 0.05% NAs), and ample growth was observed on the positive control plates containing glucose. However, still no growth was observed on the M9+lactose (+Tet, with/without X-GAL, with/without 0.05% NAs)plates. This seems to confirm with previous hypothesis that a large number of matings are needed to screen the genome for NA sensitive elements. Alternatively, perhaps the NA concentration used here is too high for proper selection of the transconjugants that are has a promoter element upstream of the transposon insertion. If the NA concentration used for the screen is too high, the promoter may be suppressed, and the lacZ is not expressed for cell survival. In fact, the lowest NA concentration used up to this point is 0.05% or 500 mg/L. The culturing conditions required to maintain Pseudomonas Pf-5's NA degrading abilities is LB+50mg/L. Therefore, to both allow cell survival and screen for the most robust and sensitive system, maybe the NA concentration should be lowered.

Week 11 (July 9-July 13)

The exact same experiment from the previous week has been repeated with two more mating mixtures (and their dilutions). However, we obtained the same results, with the positive and negative controls yielding predicted growth and no growth, respectively. But no growth was observed on the lactose plates. Furthermore, upon close examination of the selection plates after the conjugating/bipartite mating reaction (LB+Chlor+Tet), two colony morphologies can be seen: drier and larger colonies (resembling Pseudomonas), and smaller moist colonies (resembling E. coli). This suggests perhaps the LB+Chlor+Tet plates may be useful for selecting Pseudomonas transconjugants, but it does not prevent the donor E. coli to be efficiently killed. A final replica plating experiment is designed for next week, and Pseudomonas Isolation agar (PIA, just received)will be used for selection instead.

Week 12 (July 16-July 20)

Another mating reaction was set up, and plated on PIA+Tet50 to select for positive transconjugants. The colonies from the resulting mutants show only a single colony morphology consistent with Pseudomonas. From this, we know the selection is appropriate. The 1/1000 dilution of the mating reaction dilution is replica-plated on two sets of screening plates. The first set is prepared the same way as the previous week (NAs added and the media pH adjusted prior to autoclaving); the second set is the same except the NAs are added by spreading 100uL of a 50mg/L sterile stock NA solution in NaOH (pH12) prior to replica plating. The 1/1000 dilution plate of the mating reaction is replica plated on both plates (with the same controls as before). However, the same results are obtained as before, where no growth is observed on the M9+0.2% lactose+X-GAL or the M9+0.2% lactose+X-GAL+50mg/L NAs plates. At this point, since no NA-sensitive strains are isolated, new approaches needs to be taken in order to find a tranposon insertion mutant that has an NA-sensitive promoter upstream. Since all possible approaches have been taken using the replica plating strategy, another mass screening method is needed.

Week 13 (July 23-July 27)

Week 14 (July 30-August 3)

Week 15 (August 6-August 10)

Week 16 (August 13-August 17)

Week 17 (August 27-August 31)