SMAD1 Is Dispensable for CDX2 Induction but Required for the Repression of Ectopic Small-Intestinal Gene Expression in Human-Pluripotent-Stem-Cell-Derived Colonic Organoids

Abstract

The generation of gastrointestinal tissues from human pluripotent stem cells has provided unprecedented insight into the molecular mechanisms that drive the patterning of the primitive gut tube. Previous work has identified bone-morphogenetic-protein (BMP) signaling as an important mediator of mid/hindgut versus foregut and hindgut versus midgut cell fate choice. Inhibition of BMP signaling during gut tube morphogenesis inhibits the expression of the pan-intestinal transcription factor CDX2. Treatment of CDX2+ mid/hindgut cultures with BMP patterns them into hindgut, which gives rise to colonic organoids (HCOs). While the role for BMP signaling is clear, the molecular mechanisms through which BMP signaling patterns the mid/hindgut and colon remain unclear. BMPs bind to BMP receptors, activating a signaling cascade that results in the activation of SMADs, which function as transcription factors. We hypothesized that one of these factors, SMAD1, would be necessary for establishing the CDX2 domain and the colon domain. Unexpectedly, endoderm derived from SMAD1-deficient induced pluripotent stem cells was capable of inducing CDX2 in response to WNT and FGF signaling. In addition, CDX2+ gut tube cultures could activate posterior HOX genes in response to BMP. However, examination of HCOs following cytodifferentiation revealed that SMAD1-deficient HCOs ectopically expressed small-intestinal markers despite expressing posterior HOX genes. These results indicate that there is redundancy of SMADs during early hindgut patterning but that SMAD1 is required for the inhibition of small-intestinal gene expression in HCOs.