Massive expansion of human induced pluripotent stem cells resulting in efficient biobanking and functional 3D tissue analysis of genetic cardiomyopathies

Abstract

Abstract Introduction Over the past decade, various protocols were established to ensure efficient differentiation of hiPSC into cardiomyocytes (CMs). A major limitation, however, remained the batch-to-batch variability of hiPSC-CM efficiency and cell number. Here, we suggest an approach in which concomitant GSK-3β inhibition and removal of cell-cell contact inhibition, resulted in a massive proliferative response of hiPSC-CMs1–3. This efficient method allows expansion and passaging of functional hiPSC-CMs, that routinely can be cryopreserved and subsequently used as a stable cell source for the downstream applications, such 3D in vitro models for the disease modelling of dilated cardiomyopathy (DCM). We focussed on the deletion of arginine 14 in the PLN gene (R14del), which is associated with severe heart failure in DCM patients, associated with arrhythmias, cardiac fibrosis and premature death. Methods Subsequent expansion of hiPSC-CM cultures is generally modest (<10 fold). Here, we describe a cost-effective strategy for massive expansion (up to 250-fold) of high-purity hiPSC-CMs relying on two aspects; 1) inhibition of cell-cell contact via low-density seeding and serial passaging in culture flask-format, 2)small molecular glycogen synthase kinase-3β inhibition with CHIR99021 (CHIR). Patient-specific hiPSC-CMs harbouring a PLNR14del mutation were generated and used for EHT formation and functional follow-up. Results We observed that proliferating hiPSC-CMs, especially within the first 2 passages, can routinely be cryopreserved and subsequently further expanded or utilized in downstream applications. Moreover, using this strategy, it is possible to produce ultimately >1 billion CMs within 3–5 weeks starting with one differentiation batch of day 11 hiPSC-CMs, without the need for cell sorting or selection. Expanded hiPSC-CMs retain their capacity to mature and allows fibrin-based engineered heart tissues (EHTs) formation. Previously expanded CMs from PLNR14del patient-specific hiPSC were used to generate EHT and displayed a reduced force phenotype (0.137±0.012 mN) vs healthy control (0.229±0.030 mN) and isogenic control (0.224±0.008 mN) in previously expanded CMs. Conclusion We provpresent a novel strategy for the massive expansion of functional hiPSC-CMs with concomitant GSK-3β inhibition and low cell density culture that ultimately generates up to a 250-fold increase in hiPSC-CM numbers. Expansion healthy control hiPSC-CMs does not limit the subsequent maturation process, and moreover cells remain fully functional such as required for downstream tissue engineering approaches. Therefore, CM expansion forms a well-controlled platform for upscaling hiPSC-CM production for functional 3-dimensionale PLN cardiac disease models, large drug screenings and multiple translational/regenerative applications. Funding Acknowledgement Type of funding sources: Foundation. Main funding source(s): PLN Foundation