Simplifying Genotyping of Mutants from Genome Editing with a Parallel qPCR-Based iGenotype Index.
Liezhen FuShouhong WangLusha LiuYuki ShibataMorihiro OkadaNga LuuYun-Bo ShiPublished in: Cells (2024)
Targeted genome editing is a powerful tool in reverse genetic studies of gene function in many aspects of biological and pathological processes. The CRISPR/Cas system or engineered endonucleases such as ZFNs and TALENs are the most widely used genome editing tools that are introduced into cells or fertilized eggs to generate double-strand DNA breaks within the targeted region, triggering cellular DNA repair through either homologous recombination or non-homologous end joining (NHEJ). DNA repair through the NHEJ mechanism is usually error-prone, leading to point mutations or indels (insertions and deletions) within the targeted region. Some of the mutations in embryos are germline transmissible, thus providing an effective way to generate model organisms with targeted gene mutations. However, point mutations and short indels are difficult to be effectively genotyped, often requiring time-consuming and costly DNA sequencing to obtain reliable results. Here, we developed a parallel qPCR assay in combination with an iGenotype index to allow simple and reliable genotyping. The genotype-associated iGenotype indexes converged to three simple genotype-specific constant values (1, 0, -1) regardless of allele-specific primers used in the parallel qPCR assays or gene mutations at wide ranges of PCR template concentrations, thus resulting in clear genotype-specific cutoffs, established through statistical analysis, for genotype identification. While we established such a genotyping assay in the Xenopus tropicalis model, the approach should be applicable to genotyping of any organism or cells and can be potentially used for large-scale, automated genotyping.
Keyphrases
- dna repair
- genome editing
- crispr cas
- high throughput
- genome wide
- dna damage
- induced apoptosis
- single cell
- cancer therapy
- dna damage response
- dna methylation
- cell cycle arrest
- cell free
- genetic diversity
- single molecule
- copy number
- endoplasmic reticulum stress
- oxidative stress
- deep learning
- gene expression
- drug delivery
- molecularly imprinted
- cell proliferation
- transcription factor