Generation of isogenic allelic series of LMNA-mutated hiPSC lines using the novel and highly-efficient targeting platform, STRAIGHT-IN

Abstract

Abstract Funding Acknowledgements Type of funding sources: Public grant(s) – National budget only. Main funding source(s): The Netherlands Organisation for Health Research and Development ZonMW Background Human induced pluripotent stem cells (hiPSCs) have demonstrated enormous potential for advancing in vitro disease modelling and genetically modified hiPSCs carrying disease-associated variants are particularly useful tools for this purpose. Until now, strategies for efficient and rapid integration of large DNA payloads (>10 kb) into specific genomic regions are still limited, thus precluding efficient and rapid targeting of hiPSC lines. Purpose and Methods To overcome this, the STRAIGHT-IN platform (Serine and Tyrosine Recombinase Assisted Integration of Genes for High-Throughput INvestigation) was developed that combined different classes of site-specific recombinases with CRISPR-Cas9 mediated homologous recombination and allowed stringent site-specific replacement of large genomic fragments in hiPSCs. Here, we use STRAIGHT-IN to simultaneously generate a library of genetically matched hiPSC lines carrying multiple heterozygous mutations in LMNA gene. Mutations in LMNA, encoding Lamin A/C protein, have been associated with 5-10% cases of dilated cardiomyopathy (DCM) with conduction defects. Results Through detailed online searches of the LMNA database and literature, we identified and selected 11 LMNA mutations to insert into a wild-type hiPSC line based on the following criteria: (i) mutations associated with cardiac abnormalities, in terms of structural (DCM/heart failure) and arrhythmic phenotypes; (ii) mutations with known familiar/pedigree-relationship; (iii) different types of mutations (missense and nonsense). We then applied the workflow of STRAIGHT-IN consisting of: (1) replacing the entire LMNA genomic locus (33 kb) on one allele with a Landing Pad (LP) cassette containing Serine Recombinase (Bxb1) recognition sites; (2) reintroducing LMNA gene into the LP cassette through integration of Bxb1-Donor plasmids carrying the LMNA variants of interest via Bxb1 expression; (3) expressing a tyrosine recombinase (Cre) to excise the majority of the auxiliary exogenous DNA sequences. Conclusions STRAIGHT-IN allows simultaneous generation of a panel of 11 isogenic hiPSC lines carrying selected LMNA mutations rapidly (5-6 weeks), efficiently and cost-effectively, thus facilitating the production of specific mutated hiPSC lines for disease modelling and personalized medicine applications.