Difference between revisions of "Team:ITB Indonesia/Results"

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<center><em> Figure 4. SEM result of plastic fragment incubated with BL21 cells transformed with BBa_K2378006 shows rougher surface with more cracks </em></center>
 
<center><em> Figure 4. SEM result of plastic fragment incubated with BL21 cells transformed with BBa_K2378006 shows rougher surface with more cracks </em></center>
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<p style="font-size: 18px"><strong>2. pSal Inducibility Assay</strong></p>
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<p>ITB_Indonesia iGEM team 2017 designed a PETase enzyme coding device consisting of NahR-pSal regulatory part which is commonly activated by salicylate induction. Beside salicylate, NahR-pSal regulatory system is also known to have a certain degree of responsiveness towards the presence of organic pollutants (OPs). This particular characteristic of NahR-pSal is utilized in iGEM 2017 Indonesia's project to detect the presence of plastic.</p>
  
 
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Revision as of 22:55, 1 November 2017


Results


Results

Experiments to test our project were segmented into three different sections:

PETase Activity Assay, pSal Inducibility Assay, Biofilm Formation Assay


1. PETase Activity Assay

The goal of this assay is to determine and measure the PET-degrading abilities of our parts. The first experiment is carried out using pNPB Assay. PETase activity was tested using pNPB (p-nitrophenyl butyrate) Assay which measures esterase activity. Trasformants of BBa_K2378005 were grown for 4, 16, 24 hours in LB and tested against pNPB to determine their esterase activities, which were measured spectrophotometrically. As controls, we grew BL21 cells without plasmid with the same variations of age.

The results clearly showed that PETase activities were observed in all different variations of bacterial age, as the absorbance differences with their individual controls were significant. We can thus conclude that this part works as intended.

Figure 1. PETase Activity Assay (pNPB Assay) of BBa_K2378005 Transformants

The difference of PETase activity among the 3 varying culture ages were not significant. One major observation point is that in culture grown for only 4 hours, the initial activities were lower. This might be due to the that the initial concentration of available PETase was lower as well.


Aside from that, we also tested PETase activity by directly applying our PET-degrading bacteria into PET bottle fragments. After 2 days of incubation, the fragments were visualized using Scanning Electron Microscope (SEM) techniques.

The results showed that the surface of PET fragments inoculated by PETase-containing cultures are rougher and have more cracks. This is most likely due to the activity of PETase.

Figure 2. SEM result of plastic fragment incubated with control BL21 cells bearing no plasmid

Figure 3. SEM result of plastic fragment incubated with BL21 cells transformed with BBa_K2378005 shows rougher surface with more cracks

Figure 4. SEM result of plastic fragment incubated with BL21 cells transformed with BBa_K2378006 shows rougher surface with more cracks

2. pSal Inducibility Assay

ITB_Indonesia iGEM team 2017 designed a PETase enzyme coding device consisting of NahR-pSal regulatory part which is commonly activated by salicylate induction. Beside salicylate, NahR-pSal regulatory system is also known to have a certain degree of responsiveness towards the presence of organic pollutants (OPs). This particular characteristic of NahR-pSal is utilized in iGEM 2017 Indonesia's project to detect the presence of plastic.