Team:Penn/LightActivatedLysis

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Light-Dependent Lysis of Mammalian Cells by Bacteria

We then wanted to prove that our pDawn-ClyA construct was able to lyse mammalian cells in a light-dependent manner. To assess this, we plated BL21 bacteria transformed with pDawn-ClyA or pDawn-mCherry on Columbia Agar plates supplemented with 5% sheep blood (BD). These plates are used to qualitatively detect hemolytic activity in bacteria by visually confirming lysis through a color change in the media as the blood cells are lysed. After plating the bacteria, cultures were grown in non-inducing conditions at 37°C until visible colonies were present (~12 hours). Plates were then grown at 25°C under either inducing or non-inducing conditions for 24 hours and imaged. These results are visible in Figure 1. The plates with pDawn-mCherry exposed to both dark and light conditions show no evidence of cell lysis. Similarly, the pDawn-His-ClyA plate exposed to dark conditions shows no cell lysis. However, in the pDawn-His-ClyA exposed to light conditions, there is significant cell lysis throughout the plate.

This cell lysis demonstrates that ClyA is being secreted from the bacteria in a light-dependent manner


pDawn-mCherry Dark

pDawn-mCherry Light


pDawn-His-ClyA Dark

pDawn-His-ClyA Light
Figure 4
Spatial Cell Lysis

Since our goal is a system for drug delivery, it is especially important to show spatial control of lysis. The advantage of our light-based system is the precision gained through using light to selectively target regions of the body to kill cells. We tested this concept on our blood agar plates by selectively exposing half of the plates to light conditions and the other half to dark conditions. Shown below in Figure 2, only the region exposed to light shows cell lysis. Similarly, when we plated a fun pattern in Figure 3, only the bottom half exposed to light shows cell lysis. There is also no leakage evident in these plates indicating the high degree of control which our system provides


Figure 2
Figure 2: Colony Spatial Control.

Figure 3
Figure 3: Penn iGEM spatial control
Verification of Expression of Cytolysin A (ClyA)

Having proven above in Figure 4 that ClyA was being secreted, our next step was to ensure that ClyA was being properly expressed and was the factor causing the cell lysis we observed on the blood agar plates. To test this, we conducted an affinity protein purifaction and the results of the protein gel are shown below in Figure 4. It is evident that there is a 34 kDA band in both the lysate and culture medium confirming that the protein was being expressed. Furthermore, this band is only evident in the pDawn-ClyA Light column. The fact that there is a band only on the light column as well as no evidence of a band in the pDawn-ClyA Dark column shows the strong on/off expression of the system as well as confirms the light-dependent expression of ClyA.

Thus, through the combination of our blood agar experiments and protein purification, we were able to show light-dependent expression and secretion of our cytolytic protein, ClyA



Figure 4
Figure 4: The production of clyA-his in BL21 in both bacteral lysate and culture medium
Dose-Response Characterization of ClyA Cytotoxicity


Figure 1
Figure 1: Surface display of mCherry using INPNC system. INPNC-mCherry and Intein-mCherry fusions were expressed in E. coli BL21 in the pET26b expression vector and Wood-Intein expression plasmid, respectively. When fused to INPNC, almost all mCherry was localized in the membrane fraction after sonication and centrifugation, while in the case of Intein-mCherry, all mCherry was localized in the cytoplasmic lysate.