Team:Edinburgh/Project/Notebook

From 2013.igem.org

(Difference between revisions)
(Chronological notebook)
(Chronological notebook)
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*'''3rd of July''':  
*'''3rd of July''':  
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(Harry, Hugo, Dainius and Kyle)  
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Since we propose using B. subtilis as a chassis for our waste water treatment bacteria, we first set about determining the concentration of different metal ions that the non genetically altered chassis can cope with. We initially observed cell density of cultures after 8 hours incubation with varying metal concentrations. Following this we recorded culture density every hour to obtain growth data for appropriate concentrations of metals, as indicated by the initial 8 hour cultures. These experiments continue... (Harry, Danius, Hugo)
*'''4th of July''':  
*'''4th of July''':  

Revision as of 10:05, 5 July 2013

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Chronological notebook

  • 27th of June:

B. subtilis (strain: 168) culture inoculated into 10 ml LB medium. Overnight incubation in 37 deg.C

Preparation of metal ion stock solutions: Ni - 0.1M; Zn - 0.1M; Fe - 0.5M; Cu - 0.5M; Co - 0.1M; Mn - 1M (Aleksandra, Harry and Jan)

  • 28th of June:

0.5 ml units of O/N culture diluted to 50ml (x100 dilution in LB medium). 3 ml of diluted culture aliquots poured into universal bottles (enables adequate aeration of the culture). Those were inoculated with 30 ul of differently concentrated metal ion solutions giving final concentrations of:

Ni - 1mM; 0.75 mM; 0.5 mM and 0.25mM; Zn - 1mM; 0.75 mM; 0.5 mM and 0.25mM; Fe - 5mM; 3.75mM; 2.5mM and 1.25mM; Cu - 5mM; 3.75mM; 2.5mM and 1.25mM; Co - 1mM; 0.75 mM; 0.5 mM and 0.25mM; Mn - 10mM; 7.5mM; 5mM; 2.5mM; 1.25mM and 0.625mM

0.4 ml of O/N culture diluted to 40ml (x100 dilution in 2xLB medium). 3 ml of diluted culture aliquots poured into universal bottles (enables adequate aeration of the culture). Those were inoculated with 1ml of differently concentrated ethanol solutions giving final concentrations of:

2%; 4%; 6%; 8%; 10%; 15%; 20% and 25%

The initial Absorbance readings at OD600 for diluted cultures were taken. Following 7h. incubation in 37 deg.C absorbance of each sample was measured and compared to samples inoculated only with H2O (Kyle, Harry, Aleksandra, Dainius and Jan).

  • 1st of July:

B. subtilis EtOH resistance assay was continued in a narrow concentration range (Jan).

E. coli (DH5alpha) cells were transformed using BioBricks required for EtOH production (Aleksandra).

O/N cultures of E. coli and B. subtilis were set up to continue with the experiments tomorrow (Harry).

  • 2nd of July:

Transformation was successful. Four colonies were selected and propagated into 5ml LB bottles supplemented with adequate antibiotic (Jan). After 8h incubation in 37 deg. C cells were pelleted and plasmids were extracted using Qiagen MiniPrep Kit (Aleksandra). Concentration and quality of DNA was measured using NanoDrop.

E. coli cells plated for competitors were harvested and propagated into 50 ml LB medium. Following 4h incubation they were used to make competent cells for future transformations (Aleksandra and Jan).

B. subtilis resistance to heavy metals experiment was continued in a narrow metal ion concentration range (Harry).

  • 3rd of July:

Since we propose using B. subtilis as a chassis for our waste water treatment bacteria, we first set about determining the concentration of different metal ions that the non genetically altered chassis can cope with. We initially observed cell density of cultures after 8 hours incubation with varying metal concentrations. Following this we recorded culture density every hour to obtain growth data for appropriate concentrations of metals, as indicated by the initial 8 hour cultures. These experiments continue... (Harry, Danius, Hugo)

  • 4th of July:

The competent E. coli cells were tested by transforming them with parts for ethanol production. The negative control was performed to confirm that cells have no indigenous antibiotic resistance and that prepared antibiotic plates have antibacterial properties (Aleksandra and Jan).

Time-lapse measurements of B. subtilis growth in specified metal concentrations (based on previous data) were performed (Harry, Hugo, Dainius and Kyle)

Team started preparing poster (Kyle) and presentation (Dainius and Hugo) for the Young Synthetic Biologist meeting held in London over the next weekend: 12-14/07/2013

  • 5th of July:

Outcome of the transformation was positive with the negative control showing no growth (as expected). Four colonies were collected and grown in 5ml LB supplemented with adequate antibiotic. Following 7h incubation the entire culture was pelleted and plasmid was purified using Qiagen MiniPrep Kit. NanoDrop was used to measure the DNA concentration (Harry and Jan)

Time-lapse measurements of B. subtilis growth in specified metal and ethanol concentrations (based on previous data)were performed (Harry, Hugo, Dainius and Jan).

Recipes (or protocols if you prefer so)

  • 2xLB medium:

Tryptone, 20g Yeast extract, 10g NaCl, 10g (when making more medium add 20g) Dissolve in 800 ml dH2O, adjust pH to 7.0 with NaOH/HCl, adjust volume to 1 litre and autoclave.

NOTE: Use this medium when diluting the culture with high volumes. If possible try to use same volume of 2xLB and the solution you want to add to it as B. subtilis does not grow really well in highly concentrated LB.

  • Preparation of competent E. coli cells:

TSS buffer is required for this process. 24 ml TSS:

-17 ml LB -5 ml 40% w/v PEG 3350 -1 ml 1 M MgCl2 filter sterylise the mix above and add: -1 ml DMSO

Procedure:

Propagate E. coli from plate into 50 ml of LB medium. Grow until OD600 of about 0.2 to 0.5 is obtained. Pellet 1 ml of culture for each eppendorf of competent cells. Remove supernatant and add 100 ul of ice-cold TSS buffer. Incubate with TSS for 30 min on ice and store in -80 deg.C

  • Transformation of competent E. coli cells:

1.Use 100ul aliquots of competent E. coli cells from the -80 deg. C freezer.

2.Place cells directly on ice. Try to limit the exposure to heat (i.e. do not touch the bottom of the eppendorf)

3.Add 2 ul of plasmid DNA to the cells and incubate on ice for 30 - 60 minutes.

4.Heat shock the cells in 42 deg. C for 90 seconds (exact timing)

5.After heat shock place the cells on ice for additional 90 seconds.

6.Add 900 ul of LB medium to the cells.

7.Grow in 37 deg. C shaking for 45 - 60 minutes.

8.Plate 100 ul of cells on a plate with appropriate antibiotic.