When fish are encountering an acidic stress, they have to consume extra energy to restore the disturbed internal ionic and acid-base homeostasis. Following the development of industry, environmental pollution and climate change cause acidification in global water and have been threatening the survival of fish. Therefore, studying acid-base regulation mechanisms in fish is extremely important to understand how fish cope with environmental acidification. While fish face a tension, the role of neuroendocrine system is a link between physiological responses and environmental changes. When under stress, estrogen-related receptors (ERRs), steroid hormone receptors, contribute to adapt environment in organisms. In a previous study, ERRs was found to affect V-type H+-ATPase (HA), the major proton secretion related transporter, to regulate proton secretion in zebrafish (Denio rerio). Most of freshwater fishes, such as medaka (Oryzias latipes) and tilapia (Oreochromis mossambicus), use Na+/H+ exchanger 3 (NHE3) as the major proton secretion transporter. Therefore, the present study used medaka as the model animal to investigate the role of ERRs in regulation of proton secretion. Under acidic stress, errγ2 mRNA expression of embryos and adult gills were upregulated. ERRα or ERRγ2 knockdown experiments revealed that ERRα may enhance the expression of NHE3 rather than affecting differentiation of ionocytes to directly regulate H+secretion. The results also suggested that ERRα and ERRγ2 may indirectly affect acid secretion function via other pathways to regulate the function of ionocytes to achieve body fluid acid-base homeostasis; however, the detailed mechanisms are needed to be clarified in future studies.