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Pluripotent stem cells with low differentiation potential contain incompletely reprogrammed DNA replication

Theodore Paniza, Madhura Deshpande, Ning Wang, Ryan C. O’Neil, Michael V. Zuccaro, Morgan Elizabeth Smith, Advaitha Madireddy, Daylon James, Joseph R. Ecker, Zev Rosenwaks, Dieter Egli, Jeannine Gerhardt

2020The Journal of Cell Biology23 citationsDOIOpen Access PDF

Abstract

Reprogrammed pluripotent stem cells (PSCs) are valuable for research and potentially for cell replacement therapy. However, only a fraction of reprogrammed PSCs are developmentally competent. Genomic stability and accurate DNA synthesis are fundamental for cell development and critical for safety. We analyzed whether defects in DNA replication contribute to genomic instability and the diverse differentiation potentials of reprogrammed PSCs. Using a unique single-molecule approach, we visualized DNA replication in isogenic PSCs generated by different reprogramming approaches, either somatic cell nuclear transfer (NT-hESCs) or with defined factors (iPSCs). In PSCs with lower differentiation potential, DNA replication was incompletely reprogrammed, and genomic instability increased during replicative stress. Reprogramming of DNA replication did not correlate with DNA methylation. Instead, fewer replication origins and a higher frequency of DNA breaks in PSCs with incompletely reprogrammed DNA replication were found. Given the impact of error-free DNA synthesis on the genomic integrity and differentiation proficiency of PSCs, analyzing DNA replication may be a useful quality control tool.

Topics & Concepts

ReprogrammingDNA replicationBiologyInduced pluripotent stem cellDNA re-replicationGenome instabilityControl of chromosome duplicationCell biologyEukaryotic DNA replicationGeneticsDNACellDNA damageEmbryonic stem cellGenePluripotent Stem Cells ResearchCRISPR and Genetic EngineeringRenal and related cancers