Team:TU Delft/Project/alkane-degradation/results
From 2010.igem.org
(→Characterization of the ALdehyde DeHydrogenase system) |
(→Characterization of the ALdehyde DeHydrogenase system) |
||
Line 172: | Line 172: | ||
===[https://2010.igem.org/Team:TU_Delft/Project/alkane-degradation/results/ADH Characterization of the Alcohol DeHydrogenase (ADH) system]=== | ===[https://2010.igem.org/Team:TU_Delft/Project/alkane-degradation/results/ADH Characterization of the Alcohol DeHydrogenase (ADH) system]=== | ||
- | ===Characterization of the ALdehyde DeHydrogenase system=== | + | ===[https://2010.igem.org/Team:TU_Delft/Project/alkane-degradation/results/ALDH#Characterization_of_the_ALdehyde_DeHydrogenase_system Characterization of the ALdehyde DeHydrogenase system]=== |
Revision as of 18:55, 27 October 2010
Alkane Degradation Results & Conclusions
Characterization of the alkane hydroxylase system
Growth analysis
We attempted to culture our recombinant AH-carrying E.coli K12 strains ([http://partsregistry.org/Part:BBa_K398014 BBa_K398014]) on 1% v/v octanol or 1% v/v dodecane. Negligible growth was observed.
Resting-cell assays
The resting cell assays were performed on our recombinant AH-carrying E.coli K12 cells ([http://partsregistry.org/Part:BBa_K398014 BBa_K398014]). 100 micromoles of octane was added to 6 mL of growth-stalled cells (1.5 mg cell dry weight total) and incubated at 37 degrees with shaking o/n. The organic phase was extracted using EtOAc and analysed by gas chromatography.
The following are examples of typical chromatographs obtained:
The peaks shown in the chromatographs belong to the following compounds:
Retention time [min] | Compound |
~2.2 | Ethyl acetate (solvent) |
~5.2 | Octane (substrate) |
~11.8 | Undecane (internal standard, 0.1% v/v of solvent) |
The surface areas of the peaks correspond to the amount of molecules present in the sample. Due to the fact that many factors play a role in establishing an equilibrium between the aqueous and organic phase once the EtOAC is added, it's general procedure to add an internal standard to the EtOAc. In our experiment we decided to use a 0.1% vol/vol of undecane in EtOAc. The ratio between the surface areas of octane and undecane can now give an indication of the amount of octane still present in the sample and be very useful for comparisons between chromatographs.
The following table contains the average ratio of the hexadecane/undecane surface areas. Strains numbers 1 and 2 are two positive colonies taken from the same plate.
Strain | Ratio octane/undecane | Standard deviation [%] | Octane converted [umol] | Protein [mg] | Enzymatic activity [U/mg protein] |
Blank | 0.832 | 6.16 | 0.00 | 0.00 | 0.00 |
E.coli K12 negative control | 0.821 | 13.3 | 1.34 | 1.51 | 1.23E-3 |
E.coli K12 strain #1 (AH-system) | 0.652 | 14.4 | 21.6 | 1.70 | 1.77E-2 |
E.coli K12 strain #2 (AH-system) | 0.439 | 3.96 | 47.0 | 1.46 | 4.49E-2 |
From the ratios we may conclude that the samples obtained from the E.coli strain, carrying the AH system, contain relatively less octane than the control strain. Using a two-point calibration method, where we set the ratio of 0.898 equal to the total amount of octane added (16.2 uL, 99.7 umol), we can estimate the enzymatic activity of the AH-system. We know the reaction time (12 h.) and the mg of protein for each sample (using the conversion factor 0.41g/L/OD). See the table below for details.
Conclusions
We've succeeded in characterizing the activity of the alkane hydroxylase system using gas chromatography. By comparing peak ratios we were able to estimate the specific enzymatic activity of the system. The lack of an octanol peak in the GC-graphs above could be caused by the octanol being trapped by the cell, and thus not showing up in the organic (EtOAc) phase. Another likely explanation is that the octanol is readily converted by an aspecific alcohol dehydrogenase native to the E.coli K12 strain. In the future we would like to perform a resting-cell assay using P. putida and determine the enzymatic activity needed to support growth. A comparison of this natural-degrader value with the biological activity we've found of 0.045 U/mg would give more information on the growth feasibility of a strain carring the AH-system BioBrick on octane. Furthermore, a study could be done on the AH-system over time to find out more information on the kinetics of the system.
Characterization of the long-chain alkane monooxygenase; LadA
Enzyme activity assay based on NADH absorbance
Curves of the NADH absorbance for the blank, negative control and strains of interest displayed no significant differences, thus this method was abandoned. The reason for this could be explained by a lack of cofactors, a substrate diffusion limitation or even substrate inhibition.
Enzyme activity assay based on GC-analysis
Our enzyme activity protocol for LadA was loosely based an article by Maeng et al,1996. Homogenization of the alkane in the 50mM Tris buffer was achieved by adding Triton-X100, boiling and sonication. After 12 hours the residual alkane was extracted using EtOAc. The following are typical examples of the chromatographs obtained:
The peaks shown in the chromatographs belong to the following compounds:
<b>Retention time [min] | Compound |
~2.2 | Ethyl acetate (solvent) |
~11.8 | Undecane (internal standard, 0.1% v/v of solvent) |
~20.0 | Hexadecane (substrate) |
The analysis of the GC graphs was analogous to that of the AH system, described above. We made use of the internal standards present in each sample to determine the ratio of the surface areas of hexadecane vs. internal standard. These ratios can be related to the amounts of hexadecane added to eventually estimate the enzymatic activity. The following table displays the average ratios found and the enzyme activity estimates. Strains numbers 1 and 2 are two positive colonies taken from the same plate.
Strain | Average ratio hexadecane/undecane | Standard deviation [%] | Hexadecane converted [umol] | Protein [mg] | Enzymatic activity [U/mg protein] |
Blank | 0.900 | 3.19 | 0.00 | 0.00 | 0.00 |
E.coli K12 negative control ([http://partsregistry.org/Part:BBa_J13002 J13002]) | 0.807 | 3.48 | 1.76 | 4.46 | 5.49E-04 |
E.coli K12 strain #1 ([http://partsregistry.org/Part:BBa_K398017 K398017]) | 0.600 | 15.4 | 5.68 | 4.58 | 1.72E-03 |
E.coli K12 strain #2 ([http://partsregistry.org/Part:BBa_K398017 K398017]) | 0.532 | 4.25 | 6.95 | 3.18 | 3.03E-03 |
E.coli TOP10 strain ([http://partsregistry.org/Part:BBa_K398027 K398027]) | 0.492 | 2.98 | 7.71 | 3.22 | 3.33E-03 |
Conclusions
LadA was characterized succesfully using an enzyme kinetics assay coupled to gas chromatography. We see a significant increase in enzyme activity in the strains carrying the ladA protein generator BioBrick compared to the negative control strain. The highest enzyme activity value was found to be 3.33E-03 U/mg protein compared to 0.55E-03 of the negative control strain. Further studies into the enzymatic activity needed to sustain growth could be performed in future. This will give us information on the implementation of this BioBrick into our complete alkane degradation chassis.
Characterization of the Alcohol DeHydrogenase (ADH) system
Characterization of the ALdehyde DeHydrogenase system
USEFUL LITERATURE AND REFERENCES
- Kato T. et al. "Gene cloning and characterization of an aldehyde dehydrogenase from long-chain alkane-degrading Geobacillus thermoleovorans B23" Extremophiles (2010) 14:33-39.
- http://mbel.kaist.ac.kr/lab/research/protein_en1.html
- Hoffmann F. and Rinas U. "Stress Induced by Recombinant Protein Production in Escherichia coli" Advances in Biochemical Engineering/Biotechnology, 2004, Vol. 89/2004, pp. 73-92.