Physiological Functions of Aquaporin-3 in Mediating Water and Solutes

Aquaporins (AQP), are a family of membrane channel proteins that facilitate the transmembrane diffusion of water and some small non-charged solutes such as glycerol and urea by osmosis or solute gradient. AQP3, an aquaglyceroporin, is expressed in the kidney, skin, and testes, etc. Mice lacking AQP3 have symptoms of diabetes insipidus. In addition, the absence of AQP3 leads to dry skin in mice. AQP4 is permeable to water only. To understand the specific function of the water permeability and small solute transport mediated by AQP3, we generated AQP3 knock-out (AQP3 KO) mice and AQP4 knock-in mice (AQP4 KI) with AQP4 replacing AQP3 in situ. In the basal condition, knock-out of AQP3 in mice led to increased urine volume, decreased urine osmolality and tubule dilation. Interestingly, in AQP4 KI mice, these phenomena were reversed, showing improved urine concentration and tubular morphology. However, there was no significant difference in non-urea solute concentrations between both genotypes. Subsequently, we conducted acute urea loading tests and high-protein diet experiments to further increase the production and excretion of urea in mice. The experimental results showed that both urea loading and high-protein diet had little impact on urine osmolality and urinary urea concentration in AQP3 KO mice. But the urine osmolality and urinary urea concentration in AQP4 KI mice were altered by exogenous administration of urea. Our data indicates that the absence of AQP3 prevents urea accumulation in the kidney, disrupting urine concentration mechanism. The knock-in of AQP4 can restore AQP3 mediated water channel function and help to regulate the urine concentration ability. The water permeability, other than solute transport, of AQP3 plays important role in urine concentrating mechanism. AQP3 KO mice exhibited significant epidermal thickening, excessive keratinization, decreased skin hydration and elasticity. The replacement of AQP4 in situ did not improve these phenomena, indicating that solute transport mediated by AQP3 may play a role in maintaining normal skin function. Therefore, we constructed a mouse model of psoriasis induced by imiquimod (IMQ). It was found that AQP3 expression was reduced in the lesional skin of wildtype (WT) mice, while AQP3 KO mice and AQP4 KI mice exhibited dry skin, excessive epidermal proliferation, and increased inflammatory response. Local treatment with urea (10%) could alleviate these symptoms. These experimental results confirmed the important role of AQP3 in the pathogenesis of psoriasis and the potential role of urea in the treatment of psoriasis. Our study suggests the diverse physiological functions of AQP3 in different tissues. This research was supported by Beijing Natural Science Foundation (7232249). This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.