Platypus Induced Pluripotent Stem Cells: the Unique Pluripotency Signature of a Monotreme

The mechanisms by which pluripotency has evolved remain unclear. To gain insight into the evolution of mammalian pluripotency we have generated induced pluripotent stem cells (piPSCs) from the platypus. Deep sequencing of the piPSC transcriptome revealed that piPSCs robustly express the core eutherian pluripotency factors OCT4, SOX2 and NANOG. Given the more extensive role of SOX3 over SOX2 in avian pluripotency, our data indicate that between 315 million years and 166 million years ago primitive mammals replaced the role of SOX3 in the vertebrate pluripotency network with SOX2. DAX1/NR0B1 is not expressed in piPSCs and an analysis of the platypus DAX1 promoter revealed the absence of a proximal SOX2-binding DNA motif known to be critical for DAX1 expression in eutherian pluripotent stem cells, suggesting that the acquisition of SOX2 responsiveness by DAX1 has facilitated its recruitment into the pluripotency network of eutherians. We further show that the expression ratio of X chromosomes to autosomes (X1-5 X1-5:AA) is approximately equal to 1 indicating that there is no upregulation of X-linked genes and that there is no preference for silencing of maternal or paternal alleles (ie imprinting).