Team:UCL/Results/Deg
From 2014.igem.org
Degradation
In order to determine the compatibility of our BBa_K1336003 BsDyP Azo-degradation module, we set out to investigate the growth performance of E.coli DH5α containing our BioBrick in different media. We then set out to investigate the functionality of our Azo-degradation module in decolourising several model Azo-dye contaminated waste-waters.Figure 1 - BBa_K1336003 BsDyP Azo-degradation module preserves growth performance of E.coli DH5α in LB media. Graph showing that E.coli transformed with the BBa_K1336003 BsDyP Azo-degradation module shows comparable growth the plasmid-free control in LB media. OD measured at 680nm and Time is shown in hours after incubation. Error bars indicate SEM, n=2.
Figure 2 - BBa_K1336003 BsDyP Azo-degradation module is compatible with Acid Orange 7 (AO7) dye-contaminated waste waters. Graph showing that E.coli transformed with the BBa_K1336003 BsDyP Azo-degradation module is able to grow in LB media contaminated with AO7 dye. Please note that OD measurements are considerably higher in dye-contaminated waters due to the absorbance of the azo-dye. OD measured at 680nm and Time is shown in hours after incubation. Error bars indicate SEM, n=2.
Figure 3 - BBa_K1336003 BsDyP Azo-degradation module is compatible with Reactive Black 5 (RB5) dye-contaminated waste waters. Graph showing that E.coli transformed with the BBa_K1336003 BsDyP Azo-degradation module is able to grow in LB media contaminated with RB5 dye. Please note that OD measurements are considerably higher in dye-contaminated waters due to the absorbance of the azo-dye. OD measured at 680nm and Time is shown in hours after incubation. Error bars indicate SEM, n=2.
In order to determine the capabilities of our BBa_K1336003 and BBa_K1336007 BsDyP Azo-degradation module, DANIEL TO FILL OUT!
Figure 4 - BBa_K1336007 BsDyP Azo-degradation module is capable of degrading Acid Orange 7 (AO7) dye-contaminated waste waters. Graph showing that in comparison to the plasmid free control, E.coli transformed with the BBa_K1336007 BsDyP Azo-degradation module is able to decolourise AO7 dye contaminated LB media after being induced by 1mM IPTG. Inoculations were grown at 37 degrees and 180rpm for 24 hours and then left stationary for a further 24 hours at room temperature. OD680nm measurements were taken of the supernatant at the end of the 48 hour experiment. Error bars indicate SEM, n=2.
Figure 5 - BBa_K1336007 BsDyP Azo-degradation module is capable of degrading Reactive Black 5 (RB5) dye-contaminated waste waters. Graph showing that in comparison to the plasmid free control, E.coli transformed with the BBa_K1336007 BsDyP Azo-degradation module is able to decolourise RB5 dye-contaminated LB media after being induced by 1mM IPTG. Inoculations were grown at 37 degrees and 180rpm for 24 hours and then left stationary for a further 24 hours at room temperature. OD680nm measurements were taken of the supernatant at the end of the 48 hour experiment. Error bars indicate SEM, n=2.
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In order to widen our Azo-degrading and de-colourising toolbox, we also set out to investigate whether we could incorporate the Lignin Peroxidase (BBa_K500000) BioBrick submitted by Tianjin iGEM 2010 into our project and provide further characterisation. After getting this BioBrick synthesised
Figure 6 - BBa_K1336007 BsDyP Azo-degradation module is capable of degrading Reactive Black 5 (RB5) dye-contaminated waste waters. Graph showing that in comparison to the plasmid free control, E.coli transformed with the BBa_K1336007 BsDyP Azo-degradation module is able to decolourise RB5 dye-contaminated LB media after being induced by 1mM IPTG. Inoculations were grown at 37 degrees and 180rpm for 24 hours and then left stationary for a further 24 hours at room temperature. OD680nm measurements were taken of the supernatant at the end of the 48 hour experiment. Error bars indicate SEM, n=2.
Conclusions: DANIEL TO FILL OUT