Abstract
FoxA transcription factors pattern gut tissue across animal phylogeny. Beyond their early patterning function, little is known about whether they control the terminal differentiation and/or function of the fully mature enteric nervous system, the intrinsic nervous system of the gut. We show here that the expression and function of the sole C. elegans FoxA homolog, PHA-4, reaches beyond its previously described pioneer factor roles in patterning the foregut. Through the engineering of neuron-specific cis-regulatory alleles, Cre-mediated cell-specific knockouts and degron-mediated, temporally controlled PHA-4/FoxA removal in postmitotic neurons, we found that PHA-4/FoxA is required not only to initiate the terminal differentiation program of foregut-associated enteric neurons, but also to maintain their functional properties throughout the life of the animal. Moreover, we discovered novel sites of expression of PHA-4/FoxA in extrapharyngeal enteric neurons that innervate the hindgut (AVL and DVB), a GABAergic interneuron that controls foregut function during sleep (RIS), and a peptidergic neuron, PVT, which we implicate here in controlling defecation behavior. We show that while PHA-4/FoxA is not required for the developmental specification of AVL, DVB, RIS, and PVT, it is required to enable these neurons to control enteric functions. Taken together, pha-4 is the only transcription factor known to date that is expressed in and required for the proper function of all distinct types of enteric neurons in a nervous system.