Part:BBa_C0178:Experience

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Characterisation of LasI by Shanghaitech iGEM 2017

Group: Shanghaitech 2017

1、LasI coding sequence is functional

Firstly, for convincing people that BBa_C0178 - LasI coding sequence is functional, which means that it can be translated into protein and produce Las molecule 3OC12, we detect Las molecule by HPLC and LC-MS.

Figure 1: LasI is functional

2、LasI coding sequence can be designed in more complex logical circuits (like signal delivery by converter)

Secondly, as for logic circuit design, many teams have done a lot, like AND、OR and NOR gate. As for our achievement, ‘Rpa-Las molecule converter’ can achieve a function – signal delivery. Figure 2 shows our idea as an example: we can build up different blocks including different converter devices (Rhl-Lux、Lux-Rpa、Rpa-Las、Las-Tra、Tra-Sin and so on). These blocks can form a more complex signal delivery system. This year we have successfully construct ‘Rpa-Las molecule converter’BBa_K2315046, so we can say that our concept can achieve.

Figure 2: Signal delivery

3、Las molecule 3OC12 can be detected by HPLC and LC-MS

There is rarely ways for detecting biological molecules like quorum sensing signals AHL. Therefore, this year we mainly use High Performance Liquid Chromatography (HPLC) to detect the Las molecule 3OC12-HSL. Figure 3 shows our result of two devices - Rpa-Las molecule converterBBa_K2315046 and Las molecule generator BBa_K2315033.

Figure 3-1: Rpa-Las molecule converter

Figure 3-2: Las molecule generator

Applications of BBa_C0178

Characterization of BBa_C0178-Arizona_State 2016

Authors: Ernesto Luna, Brady Dennison, Cassandra Barrett, Jimmy Xu, Jiaqi Wu, Dr. Karmella Haynes

Our team helped increase characterization of the part Bba_C0178(LasI). This part was tested against its ability to induce the part BBa_F2620 by the Canton Lab(MIT). This part outputs PoPS as a Receiver Device combined with LuxR. An induction test on BBa_F2620 had been done by Dr. Barry Canton (2008), but they tested GFP production over various AHL concentrations, while our test was an 8-hour GFP read over time for 2 AHL concentrations (10 and 50%). In addition, the Canton test utilized synthetic AHLs while our test utilized AHLs produced via an E.coli chassis. A visual induction test was also done, plating the Sender alongside a GFP positive control, negative receiver control, and F2620.

As shown below, Las was unable to induce F2620 in this visual induction, as colonies in the top right section did not produce GFP. This is not the expected result, since the Canton Lab showed that the Las AHL (3-oxo-C12-HSL) was capable of inducing F2620. This may have been due to an issue with AHL diffusion on the plate and will be examined more in the plate reader test.

The figure below compares LasI at 10% and 50% concentrations alongside the native AHL system LuxI at 10% and 50% concentrations. LasI is shown to induce F2620, but to a lesser degree than LuxI. This affirms that F2620 is capable of being induced by LasI synthesized within BL21(DE3) E. coli, supporting the notion that crosstalk is occurring. This result contrasts with the plate induction result, but because it is supported by the Canton results, it is likely that the plate induction for LasI was erroneous.

AHL Disposal Test

The final experiment conducted using this part aimed to determine proper safe disposal procedures for the 3-O-C12-HSL. This AHL molecule is capable of crosstalk with potentially pathogenic strains of bacteria, and proper disposal of these AHLs should be an important biosafety measure taken. S.A. Borchardt had already tested the susceptibility of AHLs to bleach and found that 3-oxo AHLs were easily broken down by bleach while other AHLs were not. Our experiment aimed to test the application of standard EH&S sanitation protocols on AHLs (10% bleach solution and autoclaving). The figure below indicates that AHLs produced by LasI were properly deactivated by a 10% bleach solution. This was the expected result, as LasI produces a 3-oxo AHL, which should have been destroyed by bleach.

A standard 15 minute Liquid autoclave cycle was also used to treat an extracted AHL solution. The figure below indicates that LasI was nearly completely destroyed via autoclaving. This was the expected result, as the high pressure and temperatures should deactivate any AHL molecules present.

Conclusion

The results demonstrate that Las was able to effectively induce F2620 after being extracted. The Las results were consistent, which showed significantly decreased induction when treated with bleach, indicating complete AHL inactivation. According to the autoclave results, a standard 15 min liquid procedure is able to degrade nearly all AHLs. The extreme pressure and temperature generated by the autoclave was more than enough to remove any threat posed by these AHL samples. In summary, our data suggests that, for LasI, both bleach and autoclaving are capable of deactivating 3-oxo-C12-HSL.

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