Primary polydipsia, but not accumulated ceramide, causes lethal renal damage in saposin D-deficient mice

Abstract

Saposin D-deficient (Sap-D−/−) mice develop polydipsia/polyuria and die prematurely due to renal failure with robust hydronephrosis. Such symptoms emerged when they were around 3 mo of age. To investigate the pathogenesis of their water mishandling, we attempted to limit water supply and followed sequential changes of physiological and biochemical parameters. We also analyzed renal histological changes at several time points. At 3 mo old just before water restriction challenge was started, their baseline arginine vasopressin level was comparable to the wild-type (WT) level. Twenty-four-hour water deprivation and desamino d-arginine vasopressin administration improved polydipsia and polyuria to certain degrees. However, creatinine concentrations in Sap-D−/− mice were significantly higher than those in WT mice, suggesting that some renal impairment already emerged in the affected mice at this age. Renal histological analyses revealed that renal tubules and collecting ducts were expanded after 3 mo old. After 6 mo old, vacuolar formation was observed, many inflammatory cells migrated around the ducts, and epithelial monolayer cells of tubular origin were replaced by plentiful cysts of various sizes. At 10∼12 mo old, severe cystic deformity appeared. On the other hand, 8-mo-long water restriction started at 4 mo old dramatically improved tubular damage and restored once-dampened amount of tubular aquaporin2 protein to the WT level. Furthermore, 10-mo-long water restriction ameliorated their renal function. Remarkably, by continuing water restriction thereafter, overall survival period became comparable with that of the WT. Together, polyuria, devastating renal tubular lesions, and renal failure were ameliorated by the mere 10-mo-long water restriction, which would trigger lethal dehydration if the disease were to be caused by any processes other than primary polydipsia. Our study demonstrates that long-term water restriction surely improved renal histopathological changes leading to prevention of premature death in Sap-D−/− mice.