Progranulin Deficient Mice Develop Nephrogenic Diabetes Insipidus

Loss-of-function mutations of progranulin are associated with frontotemporal dementia in humans, and its deficiency in mice is a model for this disease but with normal life expectancy and mild cognitive decline on aging. The present study shows that aging progranulin deficient mice develop progressive polydipsia and polyuria under standard housing conditions starting at middle age (6-9 months). They showed high water licking behavior and doubling of the normal daily drinking volume, associated with increased daily urine output and a decrease of urine osmolality, all maintained during water restriction. Creatinine clearance, urine urea, urine albumin and glucose were normal. Hence, there were no signs of osmotic diuresis or overt renal disease, other than a concentrating defect. In line, the kidney morphology and histology revealed a 50% increase of the kidney weight, kidney enlargement, mild infiltrations of the medulla with pro-inflammatory cells, widening of tubules but no overt signs of a glomerular or tubular pathology. Plasma vasopressin levels were on average about 3-fold higher than normal levels, suggesting that the water loss resulted from unresponsiveness of the collecting tubules towards vasopressin, and indeed aquaporin-2 immunofluorescence in collecting tubules was diminished, whereas renal and hypothalamic vasopressin were increased, the latter in spite of substantial astrogliosis in the hypothalamus. The data suggest that progranulin deficiency causes nephrogenic diabetes insipidus in mice during aging. Possibly, polydipsia in affected patients - eventually interpreted as psychogenic polydipsia - may point to a similar concentrating defect.

Progranulin's functions in the periphery are still somewhat enigmatic. It promotes wound healing of the skin [20], reduces joint inflammation in arthritis [21], protects the kidney against ischemia-reperfusion injury [22] and promotes tumor growth [11], all supposed to result from silencing of an activated immune system [21]. Intracellular progranulin is localized to vesicular structures, which are endosomes or autophagolysosomes and it likely promotes the degradation of protein and lipid waste via the respective pathways [23,24]. Gene ontology enrichment analyses suggest that it contributes to the regulation of vesicular transport of proteins and metals [23]. In particular, its deficiency is associated with dysregulations of zinc transporter [5] including Slc30a9, which has been recently associated with a rare corticorenal disease in humans [25].
We have previously observed that aged progranulin deficient mice, despite their learning deficits, make few errors in place preference learning tasks, if water was the provided award [8], suggesting a higher appetitive drive. Indeed, under standard housing conditions, they drank more water, which became apparent at 12-15 months of age. Considering its multiple functions for neuronal and peripheral-immune homeostasis, polyuria might be due to primary polydipsia like in saposin D deficient mice [26], hence reflecting FTLD-like impulsive drinking and feeding. The polydipsia may also result from neurodegeneration in hypothalamus or pituitary gland, resulting in alterations of vasopressin production, supported by a previous study showing feeding-dependent fluctuations of progranulin release in the hypothalamus [27]. Progranulin deficiency also impairs the development of sexual dimorphisms [28], suggesting that hormoneproducing neurons are particularly vulnerable. Finally, the polydipsia may be caused by osmotic glucosuria or a manifestation of a nephrogenic diabetes insipidus, the latter due to unresponsiveness towards vasopressin all resulting in renal water losses. Progranulin indeed regulates insulin sensitivity [29,30], possibly by interfering with glucose transporters of the solute carrier family [31], is involved in vesicular transport [23] and glycogen synthase kinase functions [32], which are essential mechanisms for the insertion of water channels into membranes [33].
To dissect out the underlying cause, which may be clinically relevant for progranulin-deficient patients, we assessed drinking and feeding behavior, metabolic functions, plasma vasopressin and other neuropeptides, morphology of the kidney and hypothalamus and aquaporins in aged progranulin deficient and control mice, and in summary, the data reveal a renal water loss without glucosuria with high vasopressin suggesting a nephrogenic diabetes insipidus.

Animals
Progranulin knockout mice (Grn -/-) [34] were maintained as homozygous colony. The background is C57BL6J, so that sex and age matched C57BL6J mice (Charles River or Envigo, Germany) were used as controls. Mice were housed three to five per cage and maintained in the same room during life with constant room temperature (21 ± 1°C), standard diet and a regular light/dark schedule with light on from 7:00 A.M. to 7:00 P.M. Food and water was available ad libitum except for some experimental sessions in the IntelliCage and metabolic cage. Young mice were 9-12 weeks, aged mice 10-13 months and old mice 15-18 months. The experiments were approved by the local Ethics Committee for Animal Research (Darmstadt, Germany) and adhered to the guidelines of GV-SOLAS for animal welfare in science and the ARRIVE guidelines.

IntelliCage Licking behavior
The Intellicage (NewBehavior AG, Zurich, Switzerland) [8,35] consists of four operant corners, each with two water bottles, sensors, light-emitting-diodes (LEDs) and doors that control the access to the water bottles. The system fits into a large cage (20 x 55 x 38 cm, Tecniplast, 2000P). Four triangular red shelters (Tecniplast) are placed in the middle to serve as sleeping quarters and as stands to reach the food. The floor is covered with thick bedding. Mice are tagged with radio-frequency identification (RFID)-transponders, which are read with an RFID antenna integrated at corner entrance. Inside the corners, there are two holes with water bottles, which can be opened and closed by automated doors. Mice have to make nosepokes (NP) to open the doors for water access. The numbers and duration of corner visits, nosepokes, and licks are automatically recorded without the need for any handling of the mice during the recording times. Sixteen mice were housed in each cage.
The IntelliCage experiments followed established protocols [8,35,36]. Mice were adapted to the system for 3 days with free access to every corner, with all doors open, water and food ad libitum. The free adaptation was followed by 4-days "nosepoke adaptation", during which the doors upon nosepoking at the door. Water was available for 24h. Mice were then adapted for 7 days to the "drinking-session" protocol, in which drinking was allowed between 11 and 13 a.m. and 4 and 6 p.m. Outside of these times the doors remained closed. The day-pattern was used to increase the motivation to learn. The restricted drinking times were maintained in subsequent learning tasks. Subsequently, mice returned to their home cages with free access to food and water.

Phenomaster
The TSE Phenomaster offers an automated metabolic and behavioral monitoring in home cage environments. Drinking and feeding behavior were monitored with highprecision weight sensors for liquid and food dispensers, which are integrated into the lid of the cage. Mice were adapted to the drinking bottles for one week in their home cage and to the Phenomaster® cage for 3 consecutive days before starting the experiment, which consisted in 24h tap water and 24h sweetened water (20% sucrose). Drinking and feeding were recorded for 24 hours.

Excretion of creatinine, urea, glucose and albumin
Mice were placed in metabolic cages (Tecniplast) for urine collection with free access to water for 24h followed by water restriction for 2 x 12h with 1h free drinking in between. Urine was collected for 24 h in a cooling device. Body weight and drinking volume were determined daily. The 24h urine volume, urine specific weight, urine concentrations of creatinine, urea and glucose were analyzed by the veterinary laboratory LaboKlin, Bad Kissingen, Germany. Urinary albumin excretion was determined by the Bradford method and microalbumin test stripes (DIMA, Product ID M04S10-25). In addition, we used an ELISA for mouse albumin. Urinary creatinine levels were also assessed with the creatinine assay kit (Labor-Technik, Berlin, Germany) according to the manufacturer's instruction.

Serum and plasma analyses
Serum creatinine was determined with a colorimetric Microplate Assay (Oxford Biomedical Research, Biotrend, Germany), and serum urea was analyzed with an Urea Assay Kit (BioCat, Heidelberg, Germany) following the manufacturer's instruction. Serum Creactive protein, glucose and plasma zinc levels were analyzed by LaboKlin.

Analysis of vasopressin and other neuropeptides
Plasma levels of vasopressin were measured by a specific enzyme immunoassays (Arg8-vasopressin EIA kit) from Enzo (Cat.No ADI-900-017, Enzo Life science GmbH, Germany) according to the instructions of the supplier. In addition, we analyzed concentration of agouti related protein (AGRP, Cat.No LS-F16813, Life Span Bioscience, USA), visinin-like protein 1 (VILIP, Cat.No CSB-EL025933MO, CusaBio Biotech, USA) and ghrelin (Cat.No EZRGRT-91K, Merck Millipore, Germany) in plasma samples using specific ELISA kits, all according to instructions of the suppliers. Vasopressin in the kidney and hypothalamus was analyzed per immunehistochemistry.

Morphological studies and immunohistochemistry
Mice were terminally anaesthetized with isoflurane and cardially perfused with cold 1x phosphate buffered saline (PBS), pH 7.4 followed by 4% paraformaldehyde (PFA) in PBS for fixation. The kidneys were subsequently postfixed with 4% PFA in 1xPBS solution for 2h, dehydrated and embedded in paraffin. Renal sections (3.5 µm) were deparaffinized in xylene and graded ethanol and stained with haematoxylin & eosin (H&E) and periodic acid Schiff reagent (PAS). The sections were analyzed for signs of glomerulonephritis, sclerosis or tubulopathy as reported previously [37] by an investigator blinded to the genotypes. In addition, sections were processed for analysis of immune cell infiltration and aquaporin expression using immunohistology. Antigen retrieval in citrate buffer and antibody stainings followed standard procedures. Primary antibodies included rat anti-mouse F4/80 (Serotec), AQP1, AQP2 and AQP4 (Alamone labs, Jerusalem, Israel; diluted 1:100 in 1 % BSA in PBS-Triton) and vasopressin (Serotec). The numbers of neutrophils, macrophages and T cells were estimated per field (high-power field 400x, with a minimum of 10 fields counted per mouse, 3 mice per group; Soft Imaging System, Olympus, Hamburg, Germany).
For analysis of vasopressin positive neurons in the hypothalamus brains were excised, postfixed in 4 % PFA (2 h, RT), cryoprotected in 20 % sucrose (overnight, 4 °C), embedded in tissue molds in cryomedium and stored at -80 °C. Cryosections of 12 µm were permeabilized with 0.1% Triton-X-100 in 1x PBS (PBST) for 25 min, then blocked for 30 min with 5% BSA (Roth) in 1x PBS. Subsequently, sections were incubated overnight with the respective primary antibody at 4 °C, and subsequent secondary antibody labelled with Alexa-488 or Cy3 (2h, RT), followed by 30 min incubation with DAPI (1 µg/µl in 1 % BSA in PBST). Primary antibodies included vasopressin (1:500, 48h, Serotec) and GFAP (1:500, Millipore). Fluorescent sections were imbedded in Fluoromount (eBioscience). Images were captured with a Keyence (BZ-9000, Germany) microscope. For overviews, tiled images were automatically stitched. An observer who was not aware of the genotypes performed the image analyses with FIJI ImageJ for quantification of aquaporin and vasopressin immunofluorescence. The Particle Counter was employed after setting of the threshold (Isodata algorithm) and definition of size inclusion and circularity criteria. The analysis was done with sections of 4 mice per group. Results are presented as number or particles or percentage of area coverage with positive particles.

Statistics
Data are presented as mean ± SD unless stated otherwise and were analyzed with SPSS 23 and Graphpad Prism 6.0. Groups comprised 6-16 mice depending on the experiment, and numbers are presented in the figures and/or figure legends Data were submitted to univariate analysis of variance (ANOVA) or unpaired, 2-tailed Student's t-tests. In case of significant differences of ANOVAs, groups were compared with the respective control groups using t-tests with a correction of alpha according to Dunnett (one control group) or according to Šidák (specific control groups). Wildtype young mice were mostly used as the reference group. The alpha level was set to 0.05 for all comparisons, and adjusted P-values are reported. Organ weights of aged Grn -/and Grn +/+ mice. C) Number of lickings within 24h in the IntelliCage during free-drinking and restricteddrinking experiments. During 'free-drinking', access to the water bottles was allowed for 24h on nosepoking at the doors. During 'restricteddrinking', access to the water bottles was mostly denied except for 2x2h per day (11-12 am and 4-5 pm). D) Scatter plots showing the 24h drinking volume of aged Grn -/and Grn +/+ mice during free drinking and water restriction for 2x12h with one-hour free drinking in between. E) Scatter plots showing the weight of food and water consumed within 24h in sexmatched young and aged Grn -/and Grn +/+ mice in the Phenomaster cage. F) Phenomaster analysis of drinking and feeding behavior of old Grn -/and Grn +/+ mice during presentation of tap water or sweet water with 20% sucrose (mean ± SD). The data show the food weight and drinking volume consumed within 24h. For all subpanels each scatter represents one mouse, the line is the mean and the whisker show the standard deviation (SD). Asterisks indicate statistically significant differences between genotypes (unpaired, 2-tailed Student's t-test for each gender, organ, drinking or feeding. * P< 0.05, ** P<0.01, *** P<0.001, **** P<0.0001).

Body weight, feeding and drinking behavior
Under standard housing conditions, body weight was similar in male and female young Grn +/+ and Grn -/mice , which was lost again at old age (>18 months, not shown). Organ sizes and weights of the heart and spleen were similar in both genotypes irrespective of the age, but the kidneys of old Grn -/mice were enlarged with increased weights (2-way ANOVA for 'group X organ' F(3, 72) = 4.435; P = 0.0064; Fig. 1B), which was also obvious in tissue sections (Fig.  4). Significance was maintained when kidney weights were corrected for body weights, which also revealed higher relative weights of the livers (ANOVA F(3, 48) = 4.906; P = 0.0047; posthoc corrected P-values in the figure).   Daily lickings in IntelliCage experiments of young and aged Grn -/mice and respective controls showed that the number of licks was significantly increased in aged Grn -/mice during both 'free drinking' and 'restricted drinking' as compared to controls (ANOVA for 'group' F (3, 120) = 73.28; P < 0.0001; results of posthoc ttests presented in Fig. 1C). In contrast, young mice behaved normally. Metabolic Cage experiments showed that polydipsia of aged Grn -/mice was associated with polyuria ( Figure 1D), which was maintained during water restriction (2x12h with 1h free drinking in between).
We performed Phenomaster experiments (24h observation time) to quantify water and food consumption precisely. Drinking and feeding behavior was normal in young Grn -/mice, but increased in aged Grn -/mice as compared to the respective controls (ANOVA for 'age X genotype' for drinking F (1, 94) = 28.28; P < 0.0001, for feeding F (1, 86) = 16.45; P = 0.0001; posthoc in Fig. 1E). Polydipsia of Grn -/was obvious at old age irrespective of tap water or sweetened water was presented, amounting to daily drinking volumes of about 7 and 18 ml/d in Grn -/mice for tap and sweet water as compared to 3 and 10 ml/d in controls (Fig. 1E). Tap water polydipsia was accompanied with overfeeding, whereas feeding dropped to a minimum in both genotypes when sweetened water was presented (Fig. 1F).

Renal and metabolic functions
The increased drinking behavior was confirmed in an independent experiment in Metabolic Cages in a second set of aged Grn -/and Grn +/+ mice. Again, the 24h-drinking volume was almost doubled and was associated with an increase of the daily urine volume and a decrease of the urine osmolality and specific urine gravity, which was maintained during water restriction suggesting a renal water loss ( Fig. 2A, results of unpaired, 2-sided t-tests in the figure). Urine and plasma glucose concentrations were in the normal range (Fig. 2B), hence excluding osmotic polyuria. Plasma creatinine and creatinine clearance (Fig.  2C), urea excretion and urine albumin (Fig. 2D) were all in the normal range, suggesting an isolated concentration defect without major glomerular or tubular dysfunctions due to a renal diabetes insipidus, which is normally associated with an increase of vasopressin release. Indeed, plasma vasopressin levels in progranulin deficient mice were on average about 3-fold higher than normal levels (Fig. 2E), associated with increased vasopressin levels in the hypothalamus and in the kidney, as revealed by immunofluorescence analyses. Hence, the hypothalamic counter-regulatory loop appeared to be intact, allowing for exclusion of psychogenic polydipsia, which would suppress vasopressin production, and excluding a hypophyseal secretory defect, which would also result in low plasma vasopressin levels. But alterations of feedingregulating hormones, ghrelin and AgRP (Fig.2F, G), which were oppositely regulated, suggest that progranulin deficiency may cause hypothalamic hormonal dysbalances, which may account for the increase of appetite.

Kidney morphology and aquaporin water channels
The kidney function tests suggested that the renal water loss was caused by a defect of water reabsorption in tubules or collecting ducts. The histomorphology of the kidneys showed mildly widened tubules but no overt tubulopathy (Fig. 3A, B). The kidneys of aged Grn -/mice showed significantly higher numbers of F4/80+ macrophages within the interstitium and perivascular regions ( Fig. 3A; renal cortex P 0.039; renal medulla P = 0.0031), but H&E and PAS stainings (Fig. 3B) did not reveal signs of glomerulonephritis, tubulonephritis or tubulosclerosis. Overall, the kidney morphology agreed with the higher urine turnover [38], possibly owing to a vasopressin un-responsiveness, but without structural changes or diseases of the kidney that may result in renal water losses such as amyloidosis. Immune cell infiltration of the kidneys was not associated with higher plasma levels of the pro-inflammation markers, C-reactive protein (Fig. 3C) and euhydrated Grn -/mice had no derangement of serum electrolytes or serum osmolality (Table 1). Urine creatinine, potassium and magnesium were reduced likely owing to secretion of diluted urine (Table 1), and levels of the trace element, zinc were reduced is plasma (Fig. 3D) confirming our previous studies [5].
Congenital nephrogenic diabetes insipidus in humans is mostly caused by loss-of-function mutations of the renal vasopressin receptor, which is required for insertion of aquaporin water channels into the outer membrane of collecting duct cells [39], or more rarely the defect is caused by mutations of aquaporin 2 [40]. To address these potential mechanisms, we performed immunofluorescence studies of aquaporin 1, 2 and 4 (AQP1, AQP2, AQP4) in the kidneys (Fig. 4). AQP1 and AQP4 immunoreactivity were similar in both genotypes. However, AQP2 immunofluorescence clearly shows the enlargement of the Grn -/kidney and widening of the tubules associated with an apparent reduction of AQP2 immunofluorescence intensity, particularly in the inner medulla. High magnification shows that AQP2 is inserted in the apical membrane but somewhat weaker than in controls, suggesting that an AQP2 deficit in the collecting tubules may account for the water loss. The Gensat images in the right give an overview of the localization of the paraventricular nucleus (PVN) and the nucleus supraopticus (SON), which are the major sites for vasopressin producing neurons. The upper panels show AVP, GFAP and DAPI in the PVN as overview and zoom-in images, and the lower panels show the SON. AVP immunofluorescence was more intense in Grn -/and AVP positive neurons appear to be enlarged. GFAP staining reveals astrogliosis in Grn -/-. Scale bars 300 µm for overviews and 100 µm for zoom-in images. Table 1. Serum and urine electrolytes in progranulin knockout (Grn -/-) and wildtype (Grn +/+ ) female mice.

Vasopressin neurons in the hypothalamus
High vasopressin plasma levels in combination with polyuria suggested a counter-regulatory increase of vasopression production in the hypothalamus. In addition, the hypothalamus may be target of the neurodegenerative disease caused by progranulin deficiency. Therefore, we assessed putative signs of hypothalamic gliosis, and number and distribution of vasopression-positive neurons (Fig. 5). Vasopressin (AVP; arginine vasopressin) immunofluorescence was stronger in progranulin deficient brains in the paraventricular (PVN) and supraoptical nuclei (SON), and GFAP immunoreactivity of astrocytes revealed a strong gliosis within these regions in Grn -/mice, which is in line with the inherent neurodegenerative disease. In controls, AVP staining was finely distributed to fibers, particularly, in SON. In Grn -/ mice -, AVP-positive neurons appeared to be enlarged but rather reduced in numbers as revealed by DAPI counterstaining of the nuclei.

DISCUSSION
We show that aged progranulin deficient mice eat and particularly, drink considerable more than controls, about twice the normal volume. Considering that progranulin knockout is a model of frontotemporal dementia, which is predominated in humans by behavioral abnormalities including compulsive eating and drinking, one may hypothesize that the observed phenotype is a manifestation of the frontotemporal neurodegeneration, possibly contributed by dysfunctions of hypothalamic neurons that show comparably high expression of progranulin [41]. Indeed, progranulin's plasma levels fluctuate with the feeding conditions [27], and the observed inverse dysregulations of ghrelin and agouti related protein in the knockouts point to losses of progranulin-mediated anti-orexigenic effects [27] that may explain overfeeding. Hence, polydipsia and polyuria could be signs of psychogenic primary polydipsia or central diabetes insipidus due to vasopressin deficiency or mal-processing [42], but both was not the case. Instead, vasopressin levels were increased, and polyuria maintained during water restriction. Except for the water loss, renal functions of progranulin deficient mice were in the normal range agreeing with previous studies [6,34], and histomorphometric readouts of chronic renal diseases were negative. There was also no sign of osmotic diuresis due to excretion of glucose. Hence, the results point to a resistance of collecting tubules towards vasopressin resulting in a loss of aquaporin-2 expression and adaptive hypertrophy to handle the increased rates of glomerular filtration and tubular reabsorption that occur in models of central or nephrogenic diabetes insipidus [38,43].
Vasopressin enhances water reabsorption in the renal collecting duct by vasopressin V2 receptor-mediated activation of adenylylcyclase (AC) [44], cAMP-mediated phosphorylation of aquaporin-2 (AQP2), and increased insertion of AQP2 into the apical membrane [45]. Vasopressin also determines aquaporin-2 transcription via cAMP response elements [46]. In mouse models of nephrogenic diabetes insipidus, collecting ducts are resistant towards vasopressin owing to V2 mutations [47], exaggerated phosphodiesterase-mediated AC degradation [48], interference with AC activity [49], or AQP2 deficiency or malfunction [43,50,51]. In particular, ageassociated nephrogenic diabetes insipidus in some inbred mouse strains [52,53] and WAG/Rij rats [54] are caused by an age-progressive decline of AQP2 suggesting that progranulin deficiency may lead to similar but premature AQP2 losses and hence, early manifestations of kidney aging. Considering progranulin's multi-faceted functions a number of mechanisms may contribute to the DI phenotype.
The observed renal immune cell infiltration in Grn -/kidney may result from a general pro-inflammatory state in consequence of the loss of immune silencing provided by progranulin, which is expressed in immune cells of myeloid origin and suppressor T-cells and promotes the clearance of pathogens [34,55]. Permanent immune over-activation in the absence of progranulin may not only affect the kidney, but possibly also lung, liver and brain [34] and may contribute to the observed liver enlargement, possibly a sign of liver steatosis. Hence, although the immune infiltrates do not explain the water loss they may be representatives of the overall proinflammatory state.
Intracellular progranulin is localized to "membranebounded organelles" which are vesicles of altering destination, including endosomes, autophagosomes and lysosomes. Gene ontology analyses suggest that progranulin is involved in vesicle transport and vesicular transmembrane transport of ions and proteins [23]. Hence, its deficiency may impair vesicular uptake and release of ions and transport of water channels to and from the apical membrane of the collecting tubules. In line with this idea, gene regulation studies in postmortem brain of PGRNassociated FTLD-U patients show deregulations of aquaporin-1 and AQP4 among the top 100 deregulated genes (Geo data sets GDS3459, GSE13162 [56]), raising the intriguing possibility that patients with PGRNassociated frontotemporal lobar degeneration may eventually develop symptoms of polyuria. However so far, diabetes insipidus has not been described as clinical problem in these patients, possibly owing to the early onset and fatal course of the disease and/or interpretation of subtle manifestations as psychogenic polydipsia.
Secreted progranulin binds to and activates a number receptors including epidermal growth factor receptor [57], Ephrin A2 [13] and Notch receptors [12]. Ephrin and Notch signaling is mainly recognized for their pro-fibrotic effects in the kidney, hence not explaining the progranulin-provided benefit, but inactivation of Notch signaling in the renal collecting duct causes nephrogenic diabetes insipidus [58] similar to that seen in our progranulin-deficient mice. Similar phenotypes of nephrogenic DI were observed in aldose reductase deficient mice [51] and calcineurin deficient mice [59] all converging on losses of AQP2 expression, transport or phosphorylation, however without known interconnection with progranulin.
The increase of vasopressin plasma levels likely reflects an intact adaptation of the hypothalamichypophyseal axis in response to the renal water loss and argues against a substantial degeneration of hormone producing neurons at that age. However, AVP positive neurons appear to be enlarged and are surrounded by astrogliosis suggesting that the hypothalamus is affected by progranulin deficiency. In line, the observed changes of hormones regulating appetite and feeding show that progranulin is involved in hormone homeostasis. Hypothalamic dysfunctions have been observed in some other mouse models of neurodegenerative diseases [60,61], and primary polydipsia was found in saposin D deficient mice [26], the latter important because its precursor, prosaposin and progranulin converge on sortilin-mediated transport, interaction at the autophagolysosomal interface [16] and lysosomal functions [18,62]. In contrast to our mice, saposin D deficient mice had reduced vasopressin levels, and water restriction resulted in a normalization of kidney morphology and functions [26], suggesting different mechanisms of the polydipsia-polyuria phenotype.
In summary, we show that progranulin deficient mice develop a nephrogenic diabetes insipidus, which becomes manifest at about 6-9 month of age with a cumulative incidence of about 70-80%. Polyuria and polydipsia lead to a doubling of drinking volume and urine output but the dysfunction does not lead to extreme water losses, kidney damage or premature death. Nevertheless, the data show a relevant function of progranulin for the maintenance of water homeostasis and osmolality.