Enhancing the neural differentiation capabilities of genetically asymmetric mouse F1 hybrid embryonic stem cell lines

Abstract

Allele-specific, monoallelic expression in diploid organisms represents an extreme case of allelic imbalance resulting from incompatibility between cis- and trans-elements. Due to haploinsufficiency, such monoallelic expression can lead to sporadic genetic diseases. In mice, allelic imbalances can be introduced into F1 offspring from inbred strains. Previously, we established F1 hybrid embryonic stem (ES) cell lines derived from four different mouse strains, each belonging to a different subspecies with substantial genetic polymorphisms. In this study, we investigated the neural differentiation capacity of the established ES cell lines. By introducing different culture conditions, which kept the ES cells undifferentiated under various pluripotencies, we succeeded in differentiating the majority of ES cell lines (eight out of eleven) with our default neural differentiation paradigm. Still, three lines exhibited insufficient differentiation despite combining culture conditions promoting undifferentiated as well as differentiated status. In addition, Ube3a imprinting was seen in two lines. Our findings contribute to the methodological understanding of mouse ES cell pluripotency and lead to the practical utility of F1 hybrid ES cells as a model for studying phenotypes resulting from gene locus interactions.