Part:BBa_K4897013

Dark suicide system based on Cas9

What is it?

The blue light suicide system is a system that will start when our engineering bacteria lost in the external environment is not exposed to blue light. Since blue light is a type of visible light in the electromagnetic spectrum, its abundance in the natural environment is provided by common light sources such as sunlight, LED lights used in households, and fluorescent lights. The team thus investigated into how the myriad of blue light in the surroundings could be used to kill the used engineering E. coli for safety purposes.

By integrating this blue light suicide system into our engineering bacteria, precautions against potential leakage risks are established. Our engineering E. coli will not be able to survive in the external environment for more than a day, as when the night falls, it is forced to “commit suicide”. The detailed designs and procedures are illustrated in the figure below.

Usage and Biology

Fig. 1. The Scheme for the Explanation of the System

Aiming to develop this bule-light-activated suicide system, where our engineering E. coli will be killed during the absence of blue light, namely in the dark or at night, we equipped our engineering bacteria with a special part to produce EL222, a light-regulated DNA-binding protein. This protein can harness blue light to drive the reorientation of its Light-Oxygen-Voltage (LOV) sensory and Helix-Turn-Helix (HTH) effector domains, resulting in its self-dimerization and thus biding to the EL222 binding region located in between −35 (TTGACA) and −10 (TATAAT) region of the luxI promoter. T7 promoter combined with the Ribosome Binding Site (RBS) starts the transcription and translation processes of the DNA sequence coding for EL222 protein. The protein is stored in KEGG database as ELI_04755, which the gene sequence being expressed is: ATGTTGGATATGGGACAAGATCGGCCGATCGATGGAAGTGGGGCACCCGGGGCAGACGACACACGCGTTGAGGTGCAACCGCCGGCGCAGTGGGTCCTCGA CCTGATCGAGGCCAGCCCGATCGCATCGGTCGTGTCCGATCCGCGTCTCGCCGACAATCCGCTGATCGCCATCAACCAGGCCTTCACCGACCTGACCGGCTAT TCCGAAGAAGAATGCGTCGGCCGCAATTGCCGATTCCTGGCAGGTTCCGGCACCGAGCCGTGGCTGACCGACAAGATCCGCCAAGGCGTGCGCGAGCACAA GCCGGTGCTGGTCGAGATCCTGAACTACAAGAAGGACGGCACGCCGTTCCGCAATGCCGTGCTCGTTGCACCGATCTACGATGACGACGACGAGCTTCTCTAT TTCCTCGGCAGCCAGGTCGAAGTCGACGACGACCAGCCCAACATGGGCATGGCGCGCCGCGAACGCGCCGCGGAAATGCTCAAGACGCTGTCGCCGCGCC AGCTCGAGGTTACGACGCTGGTGGCATCGGGCTTGCGCAACAAGGAAGTGGCGGCCCGGCTCGGCCTGTCGGAGAAAACCGTCAAGATGCACCGCGGGCT GGTGATGGAAAAGCTCAACCTGAAGACCAGCGCCGATCTGGTGCGCATTGCCGTCGAAGCCGGAATCTGA (678 nt).

With the assistance of the T7 terminator, EL222 protein can thus be successfully synthesized using the parts provided above. As EL222 is able to homodimerize under blue light, during normal laboratory or under daytime conditions, it would induce conformational change in its LOV and HTH domains to form dimers which would later bind to the EL222 binding regions. This binding causes the release of the RNA polymerase (RNAP) sitting also in between the -35 to -10 luxI promoter region. Without RNAP, the CAS9 protein and its sgRNA cannot be expressed and used in gene editing. Consequently, the suicide system cannot complete and the ATP synthase as well as DNA polymerase of the E. coli cell continues to function, meaning that the bacteria will still survive in the external environment.

However, as nighttime approaches and blue light gradually disappears, the homodimerization of EL222 protein cannot be activated and thus is unable to compete with RNAP and bind to its binding region within the luxI promoter region. The RNAP will thus take its place and start the transcription process of CAS9 downstream, which is also assisted by the H1 promoter. Cas9 is a sizable protein weighing 160 kilodaltons, serving a crucial role in the immune defence of specific bacteria against DNA viruses and plasmids. Nowadays, it is heavily employed in genetic engineering. In our design of the suicide system, the Cas9 employed contains a unique sgRNA, a specific RNA sequence identifying the target DNA region for editing. Two types of CAS9 proteins and their corresponding sgRNA sequences are utilized in this part of the design. The CAS9 and sgRNA-A1 together collaborate to cut the ATP synthase within E. coli, rendering it nonfunctional. To pinpoint this particular sgRNA, we first identified the specific ATP synthase subunit that is crucial for the function of ATP synthase to produce ATP from ADP, labelled as P68699 on UniProt and named ATP synthase subunit C. Upon obtaining its full sequence, we utilized the sgRNA design tool at the website CRISPR direct to create the precise sgRNA sequence, GAATATGGATCTGCTGTACATTGG. Another sgRNA-A2 (sequence AAAGTCGCAATTGTATGCAC) designed by our team BS_United_China in 2022 to target the ATP synthase subunit C is also used, so that when it is combined with CAS9, two parts of the ATP synthase are destroyed, guaranteeing the death of the powerhouse of the bacteria. The other sgRNA-R in CAS9 is designed by similar methods, except for the fact that it is used to target DNA-directed RNA polymerase subunit beta which serves as the building block of RNA polymerase in E. coli. Without the enzyme catalysing the transcription of DNA into RNA, E. coli would not be able to produce the proteins needed for its survival and would thus die. The specific sgRNA-R sequence is CGAGAAAAAACGTATTCGTAAGG. The two types of CAS9 protein targeting the parts involved in essential bacterial metabolism serve as a strong double-layered protection to the environment, as the engineering E. coli will be deactivated as soon as CAS9 is activated.

In this way, once blue light is undetectable by EL222, the formation of EL222 dimers is terminated and the RNAP is allowed to bind back to the -35 to -10 region of the luxI promoter. This thereby activates the expression of CAS9 and its sgRNA sequence (sgRNA-A1, sgRNA-A2, and sgRNA-R). The gene editing process takes place after that, disrupting two of the most crucial parts of the bacterial cell’s metabolic pathways, energy and protein production, which eventually cause the death of bacteria.

Characterization

Fig. 2. The Characterization of Dark Suicide System

Sequence and Features