Team:TU-Delft/Killswitch

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For a detailed set up of the experiment see <href="https://2013.igem.org/Team:TU-Delft/Protocol_12#protocol_12" target="blank">here</a>.
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For a detailed set up of the experiment see <a href="https://2013.igem.org/Team:TU-Delft/Protocol_12#protocol_12" target="blank">here</a>.
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Revision as of 13:56, 1 October 2013

Kill switch

To the circuit a kill switch is added for two reasons: bio-safety and secretion. The bio-safety concern is that the E.coli is in essence a treat to the humans and thus it is killed after it has done what it is supposed to. The second reason is the efficient secretion: if the peptides are not secreted naturally it is very difficult to force them. The solution is cell lysis, then all the peptides will surely be secreted.

For lysis cassettes several options are already in the part registry, these are listed in the part registry. From these options the holin with endolysin kill switch, BBa_K112808, has the most experience and good experience. Furthermore, it is easy to combine with the other parts of the circuit.

In Figure 1 the kill switch is shown in the circuit. The kill switch gets activated after the timer, the final promoter is the pcI promoter. So, at the same time as the Ulp-1 is produced the kill switch is activated.

The kill switch design is based on the expression of holin and antiholin; Holin is a protein that forms pores in cell membranes. Anti-holin forms a dimer with holin, which is not active. Once pores are formed by holin, lysozyme can access the periplasmic space and degrade the cell wall, causing cell lysis.


Figure 1: Circuit of the kill switch, Part BBa_K112808



Experiments

Aim: To check for the time taken to lyse the cells by inducing the pT7 promoter with IPTG and triggering the lysis cassette. (BBa_K1022114 )

Figure 1: Part BBa_K1022114


Description

The BL21(DE3) cells transformed with pT7 lysis cassette (BBa_K1022114) is grown on a plate reader which is capable of shaking and heating to 37˚C to take readings of the cells in exponential phase at every 10 minutes. Different range of IPTG concentration is used to characterize the bio – brick BBa_K1022114. At time point, 160 minutes, IPTG is added according to the table below. BL21 is used as a control.

No cells + 1mM 0.1mM 0.2m 0.3mM 0.4mM 0.5mM 0.6mM 0.7mM 0.8mM 0.9mM 1mM Cell + No IPTG
LB(µL) 90 94 93 92 91 90 89 88 87 86 85 95
Cells(µL) - 5 5 5 5 5 5 5 5 5 5 5
10X IPTG(µL) 10 1 2 3 4 5 6 7 8 9 10 -

For a detailed set up of the experiment see here.

Results

The graph clearly shows the lysis of the cells after IPTG induction. 0.1mM and 1.0mM are representative for the other measurements taken.

Discussion

The Lysis cassette (BBa_K112808) is improved by adding a pT7 promoter in front of it in the part Bba_K1022114. We showed the lysis device is capable of lysing BL21 pLysS efficiently and quick.

The functionality of the lysis device is improved as the promoter provides more controllability to the existing part BBa_K112808.

From the experiment, it can be clearly noted that the cells are growing exponentially and when induced by IPTG, within minutes the lysis device starts to kill the cells. Whereas the control BL21 cells used in the experiment, are growing even after IPTG is added to them. This proves that the cells do not die due to the IPTG chemical, but due to the lysis device which is activated by the pT7 promoter.