DNA

Part:BBa_K5124023

Designed by: Louise Brown   Group: iGEM24_Exeter   (2024-08-19)


Cas13a RGS16 spacer

Usage and Biology

The Exeter iGEM 2024 team are designing a rapid detection system for Bovine Tuberculosis (bTB) using CRISPR-Cas detection systems. The literature suggests that bTB infection in cattle can be detected by nucleic acid biomarkers in both blood [1] and tissue samples [2]. Therefore, there was potential to develop tests looking for both DNA and RNA biomarkers in infected cattle.

In 2021 McLoughlin et al. published RNA-Seq data from cattle infected with bTB at several timepoints during the disease progression [1]. They identified 19 potential biomarkers that were present across the entire length of the infection time course. We would have liked to have tested all 19 sequences but after two rounds of the design-build-test-learn cycle (see our Wiki) we focused on:
CXCL8- chemokine ligand 8, involved in infection response and tissue injury.
FOSB- FBJ murine osteosarcoma viral oncogene homologue B, plays a role in regulating cell proliferation, differentiation and transformation.
NR4A1- nuclear receptor subfamily 4, group A, member 1, plays a role in inflammation and apoptosis.
PLAUR- plasminogen activator, urokinase receptor, a biomarker of inflammation.
RGS16- regulator of G-protein signalling 16, linked to many different disease states.

This basic part codes for a spacer sequence; a 24-nucleotide RNA sequence that is complementary to the target bovine mRNA. When transcribed with the repeat sequence from the CRISPR-Cas13a loci (Cas13a_crRNA), the 29-nucleotide repeat sequence folds into a single hairpin loop, which is recognised and bound by LwCas13a, leaving the 24-nucleotide spacer sequence free to bind to the target RNA (Figure 1). In addition, the T7 promoter adds three G nucleotides to the 5’ end of the transcript.

Figure 1: Single hairpin loop attached to 24 nucleotide spacer showing no incorrect folding

Design and Characterisation

We used the Bos taurus genome sequence from a Hereford cow (BioProject accession number PRJNA450837) as a starting point to design our spacer sequences.

The DNA sequences of the 19 targets were downloaded and using the associated annotations the introns were removed using the splicing function in SnapGene. The resulting mRNA sequences were inputted into a Python script that screened for potential spacer sequences. The Cas13a-CRISPR system requires that the protospacer flanking sequence (PFS), the adjacent nucleotide to the 3’ end of the target site, must be a non-guanine. Therefore, the Python script (see GitHub) looked for sequences 25-nucleotides long where the 25th nucleotide was non-G. The resulting 24-nucleotide spacer sequences that included either a CCCC or GGGG repeats were filtered out, as the presence of these would cause misfolding with the crRNA hairpin loop. In addition, sequences with more than one uracil base were filtered out, as uracil bases easily bind to other RNA nucleotides. The Cas13a crRNA sequence was appended to the 5’ end of each spacer sequence which were then analysed for secondary structure using the on-line software IPknot++ [3]. Final spacer sequences were chosen by the highest minimum free energy, denoting least intra-sequence binding within the spacer region, and minimum inter-sequence binding between the spacer and crRNA sequences.

Due to the minimum synthesis length of 125 base pairs for IDT gBlocks, this basic part was synthesised as part of a composite part containing: a 5’ crRNA sequence (BBa_K5124012), 5’ T7 promoter (BBa_K5124041) and Type IIs compatible prefix and suffixes. The gBlock was cloned into a high copy plasmid (origin of replication from pUC18 [4]) carrying an ampicillin selection marker.

Please see composite part BBa_K5124040 for further usage and results.

References

1. McLoughlin KE, Correia CN, Browne JA, Magee DA, Nalpas NC, Rue-Albrecht K, et al. RNA-Seq Transcriptome Analysis of Peripheral Blood From Cattle Infected With Mycobacterium bovis Across an Experimental Time Course. Frontiers in Veterinary Science. 2021; 8:662002.

2. Taylor GM, Worth DR, Palmer S, Jahans K, Hewinson RG. Rapid detection of Mycobacterium bovis DNA in cattle lymph nodes with visible lesions using PCR. BMC Vet Res. 2007 Jun 13; 3:12.

3. Sato K, Kato Y. Prediction of RNA secondary structure including pseudoknots for long sequences. Brief Bioinform. 2022 Jan 17; 23(1).

4. Vieira J, Messing J. The pUC plasmids, an M13mp7-derived system for insertion mutagenesis and sequencing with synthetic universal primers. Gene. 1982 Oct; 19(3):259-68.

Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    COMPATIBLE WITH RFC[21]
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    COMPATIBLE WITH RFC[1000]


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Parameters
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