Our metabolic kill switches build on previous iGEM projects which have used the expression of highly phototoxic fluorescent proteins to kill the cells by exposing the culture to light. KillerRed and KillerOrange are homologues of GFP which, when irradiated with green and blue light respectively, generate reactive oxygen species (ROS). KillerRed has been shown to effectively kill cells when exposed to green light (540–580 nm) and is much less effective under blue light (460–490 nm) (Bulina, 2006). KillerOrange effectively kills cells when exposed to 450-495nm (Sarkisyan 2015), the range that KillerRed does not. Firstly we aimed to improve KillerRed, an existing registry part, by codon optimising it for E. coli and improving its characterisation by exposing it to previously untested light intensity. We characterised KillerOrange in the same way. Once we had established the efficiency of KillerRed and KillerOrange, ministat chambers were inoculated with samples of each.
Fig. 9
Fig. 10
Fig.7,9 Average number of colonies after 0 h, 24 h, 120 h and 168 h. Values were averaged across three biological repeats. A max value of 300 colonies is set as any plate with more than 300 colonies was not counted and assigned the max value. All samples were induced to a final concentration of 0.2 nM IPTG. All samples were diluted 1000 times in a final volume of 4.5 ml LB. Error bars represent the standard error of the mean
Fig. 9,10Data from Fig.7,8 represented as percentage viable cells over time. 100% viable is given when the CFU count for the kill switch condition equaled the control. Error bars represent the standard error of the mean.
Enzymatic
Lysozyme is a common enzyme used in laboratories the Gallus gallus form is the basis of our enzymatic kill switch. It is bacteriolytic when transported into the periplasm of gram negative bacteria, hydrolysing the glycosidic bonds connecting N-acetylmuramic acid and N-acetylglucosamine. Under the control of a T7 promoter we induce lysis of the cell by adding IPTG.
Method
To show the activity of lysozyme, a molecular probes EnzCheck lysozyme assay kit from Thermo fisher scientific was used. The CDS contains an OmpA signal peptide targeting it to the perisplasm therfore lysozyme will only be detectable if the cells have lysed. The kit uses a substrate containing Micrococcus lysodeikticus cell walls labelled with fluorescein to such as degree that fluorescence is quenched. The presence of lysozyme causes a sharp increase in fluorescence (AU) by easing the quenching. The increase in fluorescence is proportional to lysozyme activity in the sample. The fluorescence assay was used to measure the activity of the freshly transformed kill switch and that of the cultures grown in the ministat. CFUs were also used as a measure of efficiency by comparing number of colonies to a control. 5 ml ovenights of E. coli BL21 (DE3) transformed with pSB1C3 lysozyme were used to inoculate 250 ml Erlenmeyer flasks containing 50 ml of LB laced with 35 µg/ml chloramphenicol. Once an OD of 0.23 was reached IPTG was added to a final concentration of 0.2 nM. Protein production was allowed to proceed for 2 hrs. The sample was serially diluted (10-2,10-3,10-4). 200 µl of each dilution factor was spread plated and incubated at 37 °C overnight. CFUs were then compared to a control treated in the same way.
The potential for horizontal gene transfer was tested using the lysozyme C (Gallus gallus) provided in the EnsCheck lysosyme assay kit from molecular probes. Cells were lysed, the enzyme inactivated and then transformation of the resulting lysate performed. For a detailed protocol see HGT protocol
Results
No difference in CFUs was observed between the control and the samples producing lysozyme. The results of the EnzCheck lysozyme assay were inconclusive
The HGT experiment showed that DNA present in lysate can be successfully transformed into a different E. coli strain with an average of 4 colonies per transformation (stdev=3.38). The BL21 (DE3) competent cells all gained the antibiotic resistance and RFP marker from the plasmid present in the lysed DH5a. 2 colonies from each plate were cultured over night and showed a fluorescence value concordant with that of the original culture. The starting cultures of DH5a had an average starting OD of 1.11 and fluorescence value of 258 before lysis. The BL21 (DE3) cultures transformed with the lysate had an average OD of 0.75 and average fluorescence of 306. None of the spread plated lysate produced any colonies, showing that all cells were killed in the lysis reaction.
Discussion
Metabolic Kill Switch: KillerRed and KillerOrange.
We have shown that KillerRed and KillerOrange can effectively kill cells under much lower light intensity than is used in the literature (reference). On investigation into the kind of light source that was needed to produce the 1 W/cm2 of previous experiments (Bulina et al, 2005), it became clear that 1 W/cm2 was impractically bright. We decided to use an LED array that produces 0.0012 W/cm2 normally used for growing plants and expose our samples to light for a greater length of time. We showed that this was still effective with an average survival rate in the + IPTG condition of 2.2% for KillerRed and 12.7 % for KillerOrange. A wider range of exposure times and light intensities would greatly improve the characterisation of these parts, unfortunately time limitations prevented us from testing this. There was no (statistical) difference between the + IPTG condition and – IPTG condition. CFU counts for + IPTG conditions were within the standard error of – IPTG. For KillerRed the induced kill switch appears to be more effective whereas the uninduced switch is more effective in killer orange. The leakiness of the T7 promoter has likely lead to near equal expression both conditions, possibly exacerbated by the length of time that the cultures were left to grow in order for the protein to fully mature. The literature showed that cells had been kept in a cold room at 4 °C for 24 hrs before exposing the samples to light (reference), the reason given for this was to allow the protein to fully mature. We tested the validity of this as cultures were incubated at 37 °C 220 rpm overnight not 4 °C and the phototoxicity of KillerRed and KillerOrange was still evident. The light box itself had a negative effect on E. coli growth. Each sample was first diluted to 10-3,10-4 and 10-5 before exposure to light. The control showed fewer colonies at each dilution factor as would be expected, with the CFU count at a 10-3 dilution still being a lawn of bacteria. However in the dark condition, the control sample grew to a lawn of E. coli regardless of the starting dilution factor.
The continuous culture of KillerRed showed a 15 fold increase in the percentage of viable cells after 168 hrs. The average fluorescence reading for 0 hr KillerRed samples was 506.3 (recorded at an average OD of of 0.745). After 168 hrs the average fluorescence reading was 436 (at an average OD of 0.96). It seems unlikely due to the readings being similar that a mutation has occurred in the kill switch itself. As fluorescence is proportional to the amount of ROS being produced, up regulation of native E. coli enzymes that mitigate the effects of ROS may be the cause of the increase in cell survival. Future transcriptome analysis could provide interesting data on the mechanism of this change, this was unfortunately beyond the scope of this project.
Enzymatic Kill Switch: Lysozyme