| Abstract: | We previously reported that disruption of the aquaporin-11 (AQP11) gene in mice resulted in cystogenesis in the kidney. In this study, we aimed to clarify the mechanism of cystogenesis in AQP11(−/−) mice. To enable the analyses of AQP11 at the protein level in vivo, AQP11 BAC transgenic mice (TgAQP11) that express 3×HA-tagged AQP11 protein were generated. This AQP11 localized to the endoplasmic reticulum (ER) of proximal tubule cells in TgAQP11 mice and rescued renal cystogenesis in AQP11(−/−) mice. Therefore, we hypothesized that the absence of AQP11 in the ER could result in impaired quality control and aberrant trafficking of polycystin-1 (PC-1) and polycystin-2 (PC-2). Compared with kidneys of wild-type mice, AQP11(−/−) kidneys exhibited increased protein expression levels of PC-1 and decreased protein expression levels of PC-2. Moreover, PC-1 isolated from AQP11(−/−) mice displayed an altered electrophoretic mobility caused by impaired N-glycosylation processing, and density gradient centrifugation of kidney homogenate and in vivo protein biotinylation revealed impaired membrane trafficking of PC-1 in these mice. Finally, we showed that the Pkd1(+/−) background increased the severity of cystogenesis in AQP11(−/−) mouse kidneys, indicating that PC-1 is involved in the mechanism of cystogenesis in AQP11(−/−) mice. Additionally, the primary cilia of proximal tubules were elongated in AQP11(−/−) mice. Taken together, these data show that impaired glycosylation processing and aberrant membrane trafficking of PC-1 in AQP11(−/−) mice could be a key mechanism of cystogenesis in AQP11(−/−) mice.Aquaporin-11 (AQP11) is a membrane-channel protein. Although AQP11 is reported to be permeable to the water molecule,1–3 the permeability of AQP11 to other solutes remains unclear. AQP11(−/−) mice die in the neonatal period because of renal failure and retarded growth.4,5 Moreover, AQP11(−/−) mice develop renal cysts, suggesting that AQP11 can play a role in cystogenesis.4,5 However, the mechanisms of cystogenesis in AQP11(−/−) mice have yet to be clarified. One of the reasons for the difficulties in investigating AQP11 has been the lack of a good antibody for detecting endogenous AQP11 in mouse tissues.Autosomal dominant polycystic kidney disease (PKD) is the most common inherited renal disorder, occurring in 1:400 to 1:1000 live births. It is characterized by gradual renal cyst development and expansion, ultimately resulting in massive kidney enlargement and ESRD. Among autosomal dominant PKD patients, 85%–90% of cases result from mutations in the PKD1 gene, whereas another 10%–15% of cases are accounted for by mutations in the PKD2 gene. PKD1 encodes polycystin-1 (PC-1), a 462-kD, 4303–amino acid integral membrane protein with 11 transmembrane domains, a long extracellular N terminus with multiple binding domains, and a short cytoplasmic C terminus that interacts with multiple proteins, including the protein product of PKD2, polycystin-2 (PC-2).6 PC-2 is a significantly smaller 110-kD protein with six transmembrane domains. PC-1 and PC-2 are located in the plasma membrane and cilia of renal epithelia.6–8To enable the analyses of AQP11 in mice at the protein level in vivo, we generated AQP11 BAC transgenic mice (TgAQP11) that express AQP11 tagged with 3×hemagglutinin (HA) sequence at its N terminus and showed that AQP11 localizes to the endoplasmic reticulum (ER) of proximal tubule cells in vivo. Moreover, to investigate the mechanisms of cystogenesis in AQP11(−/−) mouse kidneys, we focused on PC-1 and PC-2. Impaired glycosylation processing and membrane trafficking of PC-1 in AQP11(−/−) mouse kidneys were found, which could represent a key mechanism of cyst formation in AQP11(−/−) mice. |
