Enhanced enteric neurogenesis by Schwann cell precursors in mouse models of Hirschsprung disease

Abstract Hirschsprung disease (HSCR) is characterized by congenital absence of enteric neurons in distal portions of the gut. Although recent studies identified Schwann cell precursors (SCPs) as a novel cellular source of enteric neurons, it is unknown how SCPs contribute to the disease phenotype of HSCR. Using Schwann cell‐specific genetic labeling, we investigated SCP‐derived neurogenesis in two mouse models of HSCR; Sox10 haploinsufficient mice exhibiting distal colonic aganglionosis and Ednrb knockout mice showing small intestinal aganglionosis. We also examined Ret dependency in SCP‐derived neurogenesis using mice displaying intestinal aganglionosis in which Ret expression was conditionally removed in the Schwann cell lineage. SCP‐derived neurons were abundant in the transition zone lying between the ganglionated and aganglionic segments, although SCP‐derived neurogenesis was scarce in the aganglionic region. In the transition zone, SCPs mainly gave rise to nitrergic neurons that are rarely observed in the SCP‐derived neurons under the normal condition. Enhanced SCP‐derived neurogenesis was also detected in the transition zone of mice lacking RET expression in the Schwann cell lineage. Increased SCP‐derived neurogenesis in the transition zone suggests that reduction in the vagal neural crest‐derived enteric neurons promotes SCP‐derived neurogenesis. SCPs may adopt a neuronal subtype by responding to changes in the gut environment. Robust SCP‐derived neurogenesis can occur in a Ret‐independent manner, which suggests that SCPs are a cellular source to compensate for missing enteric neurons in HSCR.