CRISPR/Cas9-mediated generation of a de novo C9ORF72 knock-in isogenic iPSC cell bank to model ALS and FTD

  1. Niamh L. O’Brien
  2. Erin Hedges
  3. Remya R. Nair
  4. Alexander J. Cammack
  5. Mireia Carcolé
  6. Deniz Vaizoglu
  7. Sara Tacconelli
  8. Katie Sutherland
  9. Chloe L. Fisher-Ward
  10. Ali Raza Awan
  11. Simon Topp
  12. Alfredo Iacoangeli
  13. Adrian M. Isaacs
  14. Thomas J. Cunningham
  15. Marc-David Ruepp
  16. Sarah Mizielinska
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Abstract

Background

The pathogenic G 4 C 2 repeat expansion in the C9ORF72 gene is the most common genetic cause of amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD). Studies focused on delineating the underlying perturbed mechanisms resulting from this genetic mutation are often confounded by the heterogeneity present in current disease models, such as patient-derived iPSC lines, with estimations of up to 50% of the variation in iPSC cell phenotypes resulting from inter-individual differences. Isogenic models, in which the pathogenic mutation is introduced into a defined genetic background, offer a powerful approach to isolating mutation-specific effects and enable high-resolution comparison across distinct ALS/FTD-associated mutations. Such models are essential for uncovering convergent disease mechanisms and improving reproducibility in ALS/FTD research.

Methods

A two-step scarless CRISPR/Cas9 genome editing strategy was used to generate isogenic human iPSC lines carrying a de novo knock-in of a disease-length G 4 C 2 repeat expansion in the C9ORF72 locus. The resulting lines underwent thorough quality control and were differentiated into lower motor neurons and assessed for the presence of key ALS/FTD pathologies, including changes to C9ORF72 mRNA and protein expression, RNA foci and dipeptide repeat proteins.

Results

Two C9ORF72 knock-in iPSC lines were generated with 631 and 600 G 4 C 2 repeats, alongside an isogenic genome editing control line. The C9ORF72 G 4 C 2 repeat expansion knock-in iPSC lines exhibit both loss-of-function and gain-of-function pathological features characteristic of ALS/FTD. Compared to the parental wild-type KOLF2.1J line and isogenic (wild-type) CRISPR control line, these exhibit a significant reduction in C9ORF72 mRNA and protein levels, the presence of RNA foci accumulation, and a marked increase in poly(GA) and poly(GP) dipeptide repeat protein levels in iPSCs and motor neurons.

Conclusions

This is one of the first reports of a successful knock-in of the pathogenic C9ORF72 G 4 C 2 repeat expansion into a human iPSC line, establishing a genetically defined and physiologically relevant model of ALS/FTD. These isogenic lines recapitulate both key loss- and gain-of-function disease pathologies, providing a crucial complement to existing patient-derived iPSC banks. By eliminating confounding genetic background variability, these cell lines will enable more precise interrogation of C9ORF72 -linked pathomechanisms and offer a robust platform for comparative studies across the ALS and FTD spectrum, mechanistic investigations, and future therapeutic targeting with enhanced translational relevance.

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