The gastrointestinal tract is subjected to extensive mechanosensory stimulation during food ingestion. However, the identities of mechanosensory receptors in the enteric nervous system remain largely unknown. The pharynx of C. elegans is structurally and functionally analogous to the vertebrate foregut, but it contains only 20 neurons embedded among the muscles and epithelial cells of the organ. Here, we report that the DEG/ENaC family ion channel DEGT-1 is a proprioceptor of pharynx movement. DEGT-1 protein is expressed in four pharyngeal neurons (MI, M3, I4, and M5) and localized to their neuronal soma in direct contact with the collagenous pharyngeal basement membrane. degt-1 mutants display abnormally rapid feeding in the presence of food, causing global changes in lipid accumulation. degt-1 mutants also pump rapidly when pumping is induced by the presence of serotonin alone, suggesting that DEGT-1 is required for proprioception of pharyngeal pumping itself rather than for sensing ingested food. DEGT-1 is required in only two pharyngeal neurons (I4 and M5) to control pumping rate. I4 and M5 neurons show a DEGT-1-dependent calcium response. Taken together, these results suggest that DEGT-1 modulates pharyngeal pumping rate by relaying proprioceptive feedback generated by the shear force of the pharynx against its own basement membrane. Thus, mechanosensors in the enteric nervous system modulate organ function by detecting not only the forces from ingested contents but also the movements of the organ itself.