Physiology and pathophysiology of the vasopressin-regulated renal water reabsorption

To prevent dehydration, terrestrial animals and humans have developed a sensitive and versatile system to maintain their water homeostasis. In states of hypernatremia or hypovolemia, the antidiuretic hormone vasopressin (AVP) is released from the pituitary and binds its type-2 receptor in renal principal cells. This triggers an intracellular cAMP signaling cascade, which phosphorylates aquaporin-2 (AQP2) and targets the channel to the apical plasma membrane. Driven by an osmotic gradient, pro-urinary water then passes the membrane through AQP2 and leaves the cell on the basolateral side via AQP3 and AQP4 water channels. When water homeostasis is restored, AVP levels decline, and AQP2 is internalized from the plasma membrane, leaving the plasma membrane watertight again. The action of AVP is counterbalanced by several hormones like prostaglandin E2, bradykinin, dopamine, endothelin-1, acetylcholine, epidermal growth factor, and purines. Moreover, AQP2 is strongly involved in the pathophysiology of disorders characterized by renal concentrating defects, as well as conditions associated with severe water retention. This review focuses on our recent increase in understanding of the molecular mechanisms underlying AVP-regulated renal water transport in both health and disease

Long-term rapamycin therapy in the Han:SPRD rat model of polycystic kidney disease (PKD)

Background. Short-term studies have demonstrated that rapamycin or everolimus treatment decreases cyst formation and improves renal function in animal models of polycystic kidney disease (PKD). Autosomal dominant polycystic kidney disease (ADPKD) patients would likely require life-long treatment with rapamycin

The role of phospholipase D in modulating the MTOR signaling pathway in polycystic kidney disease

The mammalian target of rapamycin (mTOR) signaling pathway is aberrantly activated in polycystic kidney disease (PKD). Emerging evidence suggests that phospholipase D (PLD) and its product phosphatidic acid (PA) regulate mTOR activity. In this study, we assessed in vitro the regulatory function of PLD and PA on the mTOR signaling pathway in PKD. We found that the basal level of PLD activity was elevated in PKD cells. Targeting PLD by small molecule inhibitors reduced cell proliferation and blocked mTOR signaling, whereas exogenous PA stimulated mTOR signaling and abolished the inhibitory effect of PLD on PKD cell proliferation. We also show that blocking PLD activity enhanced the sensitivity of PKD cells to rapamycin and that combining PLD inhibitors and rapamycin synergistically inhibited PKD cell proliferation. Furthermore, we demonstrate that targeting mTOR did not induce autophagy, whereas targeting PLD induced autophagosome formation. Taken together, our findings suggest that deregulated mTOR pathway activation is mediated partly by increased PLD signaling in PKD cells. Targeting PLD isoforms with pharmacological inhibitors may represent a new therapeutic strategy in PKD

Relationship of Copeptin, a Surrogate Marker for Arginine Vasopressin, With Change in Total Kidney Volume and GFR Decline in Autosomal Dominant Polycystic Kidney Disease:Results From the CRISP Cohort

<p>Background: Experimental studies indicate that arginine vasopressin (AVP) may have deleterious effects in the pathogenesis of autosomal dominant polycystic kidney disease (ADPKD). However, the significance of AVP in human ADPKD is unclear.</p><p>Study Design: Longitudinal observational study with 8.5 (IQR, 7.7-9.0) years' follow-up (CRISP [Consortium for Radiologic Imaging Studies of Polycystic Kidney Disease]).</p><p>Setting & Participants: 241 patients with ADPKD with creatinine clearance >70 mL/min.</p><p>Predictor: Plasma copeptin concentration, a surrogate marker for AVP.</p><p>Outcomes: Change in measured glomerular filtration rate (mGFR, assessed by iothalamate clearance) and total kidney volume (measured by magnetic resonance imaging).</p><p>Measurements: Baseline copeptin level, plasma and urinary osmolality, and measurements of total kidney volume and mGFR during follow-up.</p><p>Results: In these patients (median age, 34 [IQR, 25-40] years; 38% men; median mGFR, 94 [IQR, 79-145] mL/min/1.73 m(2); median total kidney volume, 859 [IQR, 577-1,299] mL), median copeptin level was 2.9 (IQR, 1.8-5.1) pmol/L. Copeptin was not associated with plasma osmolality (P = 0.3), the physiologic stimulus for AVP release, but was associated significantly with change in total kidney volume during follow-up (P <0.001). This association remained significant after adjusting for sex, age, cardiovascular risk factors, and diuretic use (P = 0.03). Copeptin level was associated borderline significantly with change in mGFR after adjusting for these variables (P = 0.09).</p><p>Limitations: No standardization of hydration status at time of copeptin measurement.</p><p>Conclusions: These data show that in ADPKD, copeptin level, as a marker for AVP, is not correlated with plasma osmolality. Most importantly, high copeptin levels are associated independently with disease progression in early ADPKD. This is in line with experimental studies that indicate a disease-promoting role for AVP. Am J Kidney Dis. 61(3):420-429. (C) 2013 by the National Kidney Foundation, Inc. Published by Elsevier Inc. All rights reserved.</p>