Part:BBa_K3017070

Combined CRISPRi and antisense RNA Toggle Switch - Model circuit

This construct is a proof of concept of a biological switch, novel to iGEM community, by our team. Our team has combined the CRISPRi system with RNA regulators to achieve a toggle switch. The switch utilizes the catalytically inactive form of Cas9 (dCas9) to achieve targeted and reversible repression of genes via specific single-guide RNAs (sgRNAs). Alternatively, the transcription of antisense RNA (asRNAs) reverses the effect of the dCas9 modulated repression on the desired genes. This method of regulation would allow for the ability to fine-tune and easily customize the execution of highly complex genetic circuits.

To bring our project to life, we have designed a circuit that drives the Escherichia coli (E.coli) strain DH5-alpha to alternately produce green fluorescent protein (GFP) and red fluorescent protein (RFP) depending on the inducer added to our system. The behavior of the construct, as a proof of concept design, relies much on the mathematical model based on data from characterizations of individual components, but the desired dynamics of the switch is illustrated below.

Circuit dynamics

State 0 -- initial state

dCas9, GFP, and RFP are constitutively produced

State 1 - Arabinose causes inhibition of RFP production

sgRNA_RFP (BBa_K3017002) is produced when arabinose is added. Then, the sgRNA forms a complex with the constitutively expressed dCas9 (which is always present in the system). This complex is guided by the sgRNA to specifically target the mrfp protein coding region, thereby suppressing the gene.

State 2 - IPTG reactivates RFP while suppressing GFP

Adding IPTG causes asRNA_RFP and sgRNA_GFP to be produced. As illustrated before, sgRNA will form a complex with dCas9. However, as sgRNA_GFP is produced in this state, the complex will suppress GFP instead of RFP. Meanwhile, the asRNA_RFP produced will target the dCas9/sgRNA_RFP complex currently bound to the RFP gene. asRNA causes the dCas9 complex to dissociate by tightly binding to the sgRNA.

Circuit components and functions

Constitutively expressed Fluorescent Proteins

As a proof of concept design, two commonly used fluorescent proteins are chosen as a reporter gene for the two output states. Green Fluorescent Protein (GFP) under the expression construct BBa_K608002-BBa_E0040-BBa_B0015 was designated as output state 1 while Red Fluorescent Protein (RFP) of construct BBa_K608002-BBa_E1010-BBa_B0015 was designated output state 2.
Notice that both fluorescent proteins are expressed under the same constitutive promoter and RBS, which allows the expression level of both fluorescent proteins to be similar. However, as mentioned in our human practice page, Professor xxx pointed out that same promoters may cause competition between themselves. Thus, an experiment was designed to characterize such <a href="https://2019.igem.org/Team:Hong_Kong_HKUST/Experiments"> promoter interference.</a>

Constitutively expressed dCas9

sgRNA and asRNA transcription by inducible promoter

The two sgRNAs are expressed under the regulation of inducible promoters pBAD (Arabinose inducible promoter) and LacL (IPTG inducible promoter). The sgRNA is transcribed and then bound to the dCas9 protein, providing precise guidance for dCas9.
The two asRNAs are expressed under the regulation of their respective inducible promoter. pBAD (Arabinose inducible promoter) and LacL (IPTG inducible promoter) promoter are selected for the following purpose. These repressor based inducible promoters are well-characterized strength and transcription start site (TSS), which allow us to plug the RNA sequence directly behind the TSS. Standard Promoter library of pBAD is also available with different strength of expression to allow for fine-tuning of expressed strength.

Sequence and Features