In Vivo Organ Regeneration via Stroma-Dependent Adult Lineage Reprogramming (mRNA). Mus musculus

Remarkable progress has been made in cell fate reprogramming by forced expression of a small number of transcription factors. Major challenges remain, however, in regenerative medicine regarding how to target multiple cell types and direct them to form a functional organ in vivo. Here, we demonstrate that, by changing their stromal microenvironment, adult differentiated cells of endodermal origin can be reprogrammed to generate a functional ectodermal organ. The process of organ regeneration is highly efficient and complete, and depends on epithelial-stromal interactions that lead to successful remodeling of the extracellular matrix and stromal cells that are essential for organ function. Furthermore, it is a multistep process consisting of changes in cell fate, where dedifferentiation occurs more rapidly than redifferentiation, and subsequent morphogenetic reprogramming. Remarkably, neither direct transdifferentiation nor a complete reversion to the pluripotency state is involved in the reprogramming process; instead it features dynamic activities of essential genes that regulate pluripotency and lineage development. Our data have important implications for stem cell biology, cancer biology, and regenerative medicine. Overall design: Three replicates of adult and reprogrammed mouse lung and mammary cells were profiled for mRNAs