Team:TU Delft/Project/solubility/results

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Solubility Results & Conclusions

Our goal was to enhance the solubility of alkanes in water. Therefore we constructed a new part that expresses the emulsifier protein AlnA after induction by IPTG. By using our own emulsification assay we measured the increase in hydrophobic compounds in the water phase.

Results

For the production of large amounts of protein, 1 L shake flasks cultures were induced with IPTG after the OD measuremnts started to show the start of the exponential phase. The experiment was done 3 seperate times.

Experiment 1

This was the first time the experiment was done in a large volume (1 L) and carried out at 37 C. The OD measurements at the induction time point and harvest are shown in Table 1.

# Culture OD600 at induction OD600 at harvest
1 Control (J13002) 37 C 0.367 0.882
2 AlnA (K398206) 37 C 0.434 0.880

The total volume of sample at the end after completion of the isolation protocol was 3 mL. The protein concentration was determined by Bradford analysis and showed that the control contained 19 mg mL-1 and the AlnA sample contained 16 mg mL-1.

The emulsification capacity of the samples was determined using our emulsifier assay. 0.75 mg protein was used in the assay displayed in Figure 2. The 30% increase in absorption in the AlnA sample indicates a higher amount of Sudan II that is in solution, thus a higher emulsification by the proteins. A statistical T test shows that this is a significant increase (p = 3 x 10-3).

Figure 1: Emulsification of Sudan II by the isolated proteins from the control and AlnA culture. The measurements are corrected for background absorption caused by the sample itself and dissolved Sudan II without the addition of protein. The assay was done in triplo.

Experiment 2

The second experiment was carried out at 37 C and 30 C. This was done, because it was expected that IPTG causes a stronger induction at lower temperatures. The OD measurements at the induction time point and harvest are shown in Table 2.

# Culture OD600 at induction OD600 at harvest
1 Control (J13002) 30 C 0.073 0.451
2 Control (J13002) 37 C 0.088 0.810
3 AlnA (K398206) 30 C 0.060 0.393
4 AlnA (K398206) 37 C 0.067 0.624

The total volume of sample at the end after completion of the isolation protocol was 1 mL. The protein concentration was determined by Bradford analysis and showed that from the culture grown at 37 C the control contained 1.7 mg mL-1 and the AlnA sample contained 1.5 mg mL-1. The control samples from the culture grown at 30 C contained 2.41 mg mL-1 and the AlnA sample contained 2.29 mg mL-1.

The emulsification capacity of the samples was determined using our emulsifier assay. 0.75 mg protein was used in the assay displayed in Figure 2. The 13% increase in absorption in the AlnA samples indicate a higher amount of Sudan II that is in solution, thus a higher emulsification by the proteins.

Figure 2: Emulsification of Sudan II by the isolated proteins from the control and AlnA culture grown at 37 C and 30 C. The measurements are corrected for background absorption caused by the sample itself and dissolved Sudan II without the addition of protein.

Experiment 3

The experiments were repeated one last time to confirm the positive outcome. The experiment was again carried out at 37 C and 30 C. The OD measurements at the induction time point and harvest are shown in Table 3.

# Culture OD600 at induction OD600 at harvest
1 Control (J13002) 30 C 0.111 0.462
2 Control (J13002) 37 C 0.119 0.700
3 AlnA (K398206) 30 C 0.110 0.435
4 AlnA (K398206) 37 C 0.113 0.616

The total volume of sample at the end after completion of the isolation protocol was 1 mL. The protein concentration was determined by Bradford analysis and showed that from the culture grown at 37 C the control contained 11.33 mg mL-1 and the AlnA sample contained 8.15 mg mL-1. The control samples from the culture grown at 30 C contained 5.49 mg mL-1 and the AlnA sample contained 8.49 mg mL-1.

The emulsification capacity of the samples was determined using our emulsifier assay. 0.75 mg protein was used in the assay displayed in Figure 2. The 26% increase in absorption in the AlnA samples at 30 C and 30% increase by the samples grown at 37 C indicate a higher amount of Sudan II that is in solution, thus a higher emulsification by the proteins.

Figure 3: Emulsification of Sudan II by the isolated proteins from the control and AlnA culture grown at 37 C and 30 C. The measurements are corrected for background absorption caused by the sample itself and dissolved Sudan II without the addition of protein.

Conclusions

For enabling E. coli to degrade hydrocarbons we equipped the cells with the ability to produce, AlnA, a known emulsifying protein. The production the protein was induced by IPTG. However, we were not able see the protein on SDS-PAGE. This is probably due to a low protein synthesis of the cells when cultured in minimal medium.

Nevertheless do show an increased emulsifying capacity by the expression of BBa_K398206. With our emulsifier assay we determined that an increased amount of hydrophobic Sudan II is dissolved compared to the control strain with BBa_J13002. This indicates that strains with BBa_K398206 contain a higher amount of proteins capable of emulsifying Sudan II.

Although the use of cell extracts is not direct evidence, compared to isolated proteins, we can assume that the increased solubilization is caused by the production of AlnA. In future research we would recommend:

  • Tagging the protein to facilitate isolation. Some proteins native to E. coli also show emulsifying properties. A higher purity of AlnA will reduce the background and probably also make it possible to show the protein on gel.

Future prospects

In further research we would advise to add a tag to the protein, so it can be tracked and isolated with greater ease and purity.

CharacterizationResultsParts