The most effective route for fishes to deal with toxic nitrogenous wastes is to excrete NH3/NH4+ into water directly. Over 80% of total ammonia in fish body is excreted into water via the gill epithelium. However, the mechanism for branchial ammonia transport of freshwater fish is not well understood. Using zebrafish larvae as a model, the present study investigated the mechanism of ammonia secretion by the skin of the larvae. Scanning ion-selective electrode technique (SIET) was applied to detect the NH4+ and H+ fluxes at specific cells of larval skin. NH4+ extrusion was relatively high in H+ pump-rich cells (HRCs), which were identified as the H+-secreting ionocyte in zebrafish. Minor NH4+ extrusion was also detected in keratinocytes and other types of ionocytes in larval skin. NH4+ secretion from the skin was tightly linked to acid secretion. Increases in the external pH and buffer concentration (5 mM MOPS, 3-morpholinopropane sulfonic acid) diminished H+ and NH4+ gradients at the larval surface. Moreover, coupled decreases in NH4+ and H+ extrusion were found in larvae treated with an H+-pump inhibitor (bafilomycin A1) or H+-pump gene (atp6v1a) knockdown. Knockdown of Rhcg1 (drrhcg1) also decreased NH4+ secretion at larval skin and HRCs. This study demonstrates ammonia secretion in epithelial cells of larval skin through an acid-trapping mechanism, and provides direct evidence for the involvement of the H+ pump and an Rh glycoprotein (Rhcg1) in ammonia secretion.