Part:BBa_K2818001

Cas13d-NLS-ADAR

Similar to part BBa_K2818002 (dPspCas13b-ADAR2_DD), Cas13d-ADAR2DD(E488Q) is a similar fusion protein of ADAR2 adenosine deamination and a Type IV CRISPR-associated RNA-guided ribonucleases (RNase) 13d that is mutated to be catalytically inactive but retains the ability of binding to RNA target with a separate guide RNA sequence. It can be used to selectively edit adenosine to inosine in RNA molecules in the presence of a guide RNA. NLS was fused to improve localization in the nucleus and hence enhance RNA editing.

Usage and Biology

The possible applications and the working mechanism of Cas13d is similar to that the Cas13b, which is a protein scaffold to target and guide the ADAR2 domain to the desired location to perform hydrolytic deamination of adenosine to inosine. However, one great advantage of the Cas13d system is its small size. With the average size of just 930 amino acids, it is the smallest Class 2 CRISPR effector ever being characterized in mammalian cells. Despite its small size, the nuclease-dead variant derived from Ruminococcus flavefaciens XPD3002 (also known as CasRx) has demonstrated alternative splicing modulation in vivo with high efficiency and specificity. Hence, it is an interesting construct that can be potentially useful and promises great results.

Methodology for Characterisation

We aimed to characterize both the A-to-I editing activities on transcripts of both the exogenous and endogenous genes, and compare it with the activities of the REPAIR system from literature. Two methods were used, namely a luciferase assay and direct targetting and sequencing of targeted endogenous mRNA.

Renilla luciferase Assay

In the luciferase reporter assay, the plasmid coding for a modified Renilla luciferase was constructed, where a guanosine is replaced by an adenosine at the codon of a key residue, resulting in a nonsense mutation. As such, after transfection, A-to I editing activities on the mRNA transcript by the dCas-ADAR2_DDconstructs will functionally restore the sequence and restores the luciferase protein back to the wildtype and allow for the quantification of editing activity by the Rluc luminescence. In our experiment, two parameters, namely spacer length and regions of coverage on the target were characterized in mediating A-to-I RNA editing.

Figure 1. Experimental design of luciferase assay

Endogenous mRNA Targetting

With the parameters obtained from the luciferase reporter assay, we further characterized the A-to-I editing activities of the dCas-ADAR2_DD constructs on endogenous mRNA. In such an experiment, plasmids coding for dPspCas13b-ADAR2_DD and dCas13d-ADAR2<tml>_DD</html> fusion proteins were transfected into HEK293FT cells, together with different guide RNAs targeting endogenous PPIB and KRAS mRNA transcripts. After 48 hours of transfection, the transcriptome of the cells was extracted and the target regions were amplified for Sanger sequencing. Fractions of the adenosine being called as guanosine and therefore being edited can then report for the on-target efficiency of A-to-I editing. Different guides were used to investigate the activities with different spacer lengths and guide mismatch locations.

Figure 2. Experimental design in endogenous mRNA targeting

Sequence and Features