1 Department of Medicine, University of Cincinnati School of Medicine, Cincinnati MSB 5502; and 2 Veterans Affairs Medical Center at Cincinnati, Ohio
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ABSTRACT |
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Starvation causes impairment in the urinary concentrating
ability. The mechanism of this defect, however, remains unknown. We
tested the possibility that food deprivation might affect the expression and activity of aquaporins (AQP1, 2), thereby impairing renal water reabsorption in the kidney. Rats fasted for 24 h
exhibited severe polyuria (urine volume increased from 11 before
fasting to 29 ml/24 h after fasting, P < 0.0001) along
with failure to concentrate their urine (urine osmolality decreased
from 1,485 before fasting to 495 mosmol/kgH2O after
fasting, P < 0.0001). Refeeding for 24 h returned
the urinary concentrating ability back to normal. Northern
hybridization and immunoblot analysis demonstrated that fasting was
associated with a decrease in AQP2 protein (80%, P
0.002) and mRNA levels (
69%, P
0.003) in the outer
medulla. In the cortex, fasting decreased AQP2 protein abundance by
60% (P
0.004) but did not alter its mRNA expression. During the recovery phase, AQP2 expression returned to normal level in
both tissues. In the inner medulla, the expression of AQP2 was not
altered in fasting, but was increased significantly at both protein ( ± 92%) and mRNA ( ± 43%) levels during the recovery from fasting.
The proximal nephron water channel (AQP1) was not affected in response
to fasting or recovery from fasting. We conclude that 1)
fasting impairs the urinary concentrating ability in rats, and
2) the renal water-handling defect in fasting results
specifically from the downregulation of AQP2 in the cortical and outer
medullary collecting duct.
urinary concentrating mechanism; aquaporin 2; hypoglycemia
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INTRODUCTION |
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FASTING OR ABSTAINING from food has been practiced voluntarily (religious belief or dieting) or involuntarily (famine) throughout time. Food restriction induces adaptive mechanisms in the body that permit survival for prolonged periods of fasting. Indeed, human beings can endure several months of fasting (33). In humans, the first week of fasting is associated with a marked increase in water excretion, suggesting an impairment in the urinary concentrating mechanism (31). In the rat, it was reported that fasting induces a dual effect on renal function: a first phase characterized by a decline in both whole kidney glomerular filtration rate (GFR) and single nephron GFR (SNGFR), followed by an adaptive phase with normalization of both GFR and SNGFR (2). In the rabbit, it was shown that male rabbits deprived of food but having free access to water, developed a polyuric-polydipsic syndrome associated with decreased urine osmolality as early as 24 h of food deprivation (7). Despite these observations, the molecular basis of impaired urinary concentrating mechanism in response to food deprivation remains unknown.
Renal collecting duct water channels [aquaporins (AQPs)] are essential to normal urinary concentrating ability by enhancing water reabsorption along this nephron segment. The majority of water reabsorbed in the collecting duct occurs in the principal cells, via the AVP-regulated water channel AQP2 (3, 16, 34). In the outer and inner medulla, AQP2 is present in both glycosylated (~35 kDa) as well as nonglycosylated (~29 kDa) forms, whereas in the cortex only the nonglycosylated form (~29 kDa) is detected (22, 25). This water channel is predominantly expressed in the apical surface of connecting tubule and the entire collecting duct system (25). This study was undertaken to examine whether 24 h of food deprivation affects urinary concentrating ability in rats and to investigate the molecular basis of such a defect. Our results indicate that rats that fasted for 24 h demonstrated a defect in the kidney's ability to produce a concentrated urine and exhibited a polyuria along with hypodipsia. This correlated with the downregulation of AQP2 protein expression in the cortical and outer medullary collecting duct (OMCD).
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METHODS |
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Animal model.
Male Sprague-Dawley rats were placed in metabolic cages and allowed
free access to food and water. After 3-4 days of adjustment to
metabolic cages, rats were divided into two groups. One group (control)
had free access to food and water, whereas the second group was
deprived of food (fasting) for 24 h. Half of the fasting group was
killed 24 h after food deprivation, while the other half was
switched back to a normal diet for up to 48 h (recovery). At
death, the animals were weighed; the blood was obtained for serum
[Na+], [K+], [Cl],
[HCO
], and glucose analysis, where brackets indicate concentration. The kidneys were removed, and the superficial cortex, inner stripe of outer medulla, and inner medulla were dissected
and snap frozen in liquid nitrogen, and stored at
70°C for RNA
isolation and microsome preparation. The gastrointestinal tract was
excised from the end of the esophagus to the rectum from experimental
groups and weighed. The body weights were adjusted by considering the
difference in the weights of gastrointestinal contents in experimental groups.
Total RNA isolation.
Total cellular RNA was extracted from renal cortex, inner stripe of
outer medulla, and inner medulla by the method of Chomczynski and
Sacchi (4). In brief, 0.5-1 g of tissue was
homogenized at room temperature in 10 ml Tri-Reagent (Molecular
Research Center, Cincinnati, Ohio). Total RNA was extracted by
phenol-chloroform and precipitated by isopropanol (4).
Total RNA was quantitated by spectrophotometry and stored at 80°C.
Northern hybridization. Total RNA samples (30 µg/lane) were fractionated on a 1.2% agarose-formaldehyde gel and transferred to nylon membranes by using 10× SSPE as transfer buffer. Membranes was cross-linked by UV light and baked. Hybridization was performed overnight according to Church and Gilbert (5). The membranes were washed and exposed to PhosphorImager screens for 24-72 h. For AQP2 probe, a 296-base pair PCR fragment was generated by using the following primers: 5'-AGCGCGCAGAAGTCGGAGCA-3' (sense, bases 102-121) and 5'-CAGCCACATAGAAGGCAGCT-3' (antisense, bases 378-397) and used as a specific probe.
Preparation of membrane fractions from renal outer medulla, cortex, and inner medulla. A total membrane fraction containing plasma membrane and intracellular membrane vesicles was prepared as described (22, 23) with minor modifications. Briefly, the tissue samples were homogenized in ice-cold isolation solution (250 mM sucrose and 10 mM triethanolamine, pH 7.6) containing protease inhibitors (phenazine methylsulfonyl fluoride, 0.1 mg/ml; leupeptin 1 µg/ml), by using a polytron homogenizer. The homogenate was centrifuged at low speed (1,000 g) for 10 min at 4°C to remove nuclei and cell debris. The supernatant was spun at 150,000 g for 90 min at 4°C. The pellet containing plasma membrane and intracellular vesicles was suspended in isolation solution with protease inhibitors. The total protein concentration was measured, and the membrane fractions were solubilized at 65°C for 20 min in Laemmli sample buffer.
AQP2-specific antibody. A polyclonal antibody specific to AQP2 water channel was raised using commercial services (Genosys Biotechnology, Woodlands, TX). As it has been used successfully by other investigators (23, 25), the rat AQP2 peptide NH2-CEVRRRQSVELHSPQSLPRGSKA-COOH, which corresponds to amino acid residues 250-271 of the carboxy-terminal tail of the vasopressin-regulated AQP2 water channel, was used to develop the AQP2 antibody. A cysteine residue was added at the amino terminal end of the peptide to facilitate its conjugation with a carrier protein. Two rabbits were immunized with the conjugate complex. Both rabbits developed ELISA titers greater than 1:100,000. The antiserum was affinity purified by covalently immobilizing the immunizing peptide on commercially available columns (Sulfo-Link Immobilization kit 2, Pierce, Rockford, IL). With regard to AQP1 water channel, a 19-amino-acid synthetic peptide within the carboxy-terminal domain of rat AQP1 was selected for a specific AQP1 antibody production (Alpha Diagnostic Int., San Antonio, TX).
Electrophoresis and immunoblotting. These experiments were carried out as previously described (22, 23, 25). Briefly, the solubilized membrane proteins were size fractionated on 10% polyacrylamide minigels (Novex, San Diego, CA) under denaturing conditions. By using a Bio-Rad transfer apparatus (Bio-Rad Laboratories, Hercules, CA), the separated proteins were electrophoretically transferred to a nitrocellulose membrane. The membrane was blocked with 5% milk proteins and then probed with affinity purified anti-AQP2. The secondary antibody was a donkey anti-rabbit immunoglobulin conjugated to horseradish peroxidase (Pierce). The site of antigen-antibody complexation on the nitrocellulose membranes was visualized by using the chemiluminescence method (SuperSignal Substrate, Pierce) and captured on light-sensitive imaging film (Kodak). Bands corresponding to AQP1 and AQP2 proteins were quantitated by densitometric analysis using UN-SCAN-IT gel software (Silk Scientific, Orem, Utah) and were expressed as a percentage of pooled controls. The equity in protein loading in all blots was first verified by gel staining using the Coomassie brilliant blue R-250 (Bio-Rad) as shown in Fig. 2B.
Materials. 32P-dCTP was purchased from New England Nuclear (Boston, MA). Nitrocellulose filters and other chemicals were purchased from Sigma (St. Louis, MO). RadPrime DNA labeling kit was purchased from GIBCO-BRL. AQP1 antibody was purchased from Alpha Diagnostic Int.
Statistic analyses. Results are expressed as means ± SE. Statistical significance between experimental groups was determined by Student's t-test. P < 0.05 was considered significant.
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RESULTS |
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Blood composition.
No significant differences were observed between control, fasting, and
recovery groups with respect to serum electrolytes ([Na+], [K+], [Cl], and
[HCO
]) (Table 1).
Plasma osmolality was not different between the three groups (302 ± 2.6 vs. 306 ± 2.9 vs. 303 ± 3 mosmol/kgH2O
in control, fasting, or recovery group, respectively, n = 4 for each, P > 0.05). Furthermore, no significant
differences were observed in serum creatinine and blood urea nitrogen
(BUN) between control and fasting animals (Table 1). Fasting animals
became hypoglycemic, with blood glucose decreasing from 113 ± 3.92 mg/dl in control rats to 46 ± 7.47 mg/dl (n = 4 rats for each group, P < 0.009). Fasting was also associated with a decrease in total body weight [from 165 ± 2.1 before to 138 ± 1.2 g after fasting (n = 8, P < 0.0001)]. However, the net body weight loss (see
METHODS) was ~17.3 ± 1.1 g (P < 0.05). After 24 h of refeeding the net body weight gain was 18.5 g, and hypoglycemia was also recovered to a level of 121 ± 2.41 mg/dl, indicating that both hypoglycemia and weight loss were corrected
during 24 h of recovery from fasting.
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Water balance and urine osmolality in fasting.
Water intake, urine output, and urine osmolality were measured every
24 h. A significant polyuria was developed in fasting rats, with
urine output increasing from 11 ± 0.6 to 29 ± 4.2 ml/24 h
for control and fasting, respectively, (n = 17 for
each, P < 0.0001, Fig.
1B). The polyuria improved
during recovery from fasting (Fig. 1B). The polyuria was
associated with a significant decrease in urine osmolality [from
1,485 ± 55 to 495 ± 63 mosmol/kgH2O for control
and fasting, respectively, (P < 0.0001, n = 17 for each, Fig. 1C)]. The first
24 h of the recovery phase were associated with an increase in
urine osmolality above the normal levels [2,153 ± 114 (n = 8) vs. 1,485 ± 55 mosmol/kgH2O
(n = 17), P < 0.001, Fig.
1C]; urine osmolality returned to baseline level after
48 h of refeeding (Fig. 1C). Interestingly, water
intake decreased significantly during fasting [from 31 ± 1.6 to
21 ± 3 ml/24 h for control and fasting, respectively,
(n = 17 for each, P < 0.002 Fig.
1A)], indicating that the polyuria was not secondary to
polydipsia. The water intake first increased then returned to normal
level during the recovery from fasting (Fig. 1A). Water
intake, urine volume, and urine osmolality remained unchanged in the
time control group (data not shown). These studies demonstrate that
24 h of fasting impair the urinary concentrating mechanism and
results in polyuria (without polydipsia).
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Molecular Regulation of AQP2 and AQP1 Expression in Fasting
Immunoblot analysis of AQP2 expression.
In the next sets of experiments, the effect of fasting on AQP2 protein
expression was studied. Accordingly, microsomes were prepared from the
inner stripe of outer medulla (as well as superficial cortex and inner
medulla) of kidneys harvested from control, fasting, and recovery from
fasting groups. In the outer medulla, the AQP2 protein abundance was
decreased by 80% in fasting animals compared with control group (100 ± 5% and 21 ± 4% for control and
fasting, respectively, n = 82 for each,
P < 0.002 Fig.
2A2).
AQP2 returned to normal levels after 24 h of recovery [100 ± 5 vs. 85 ± 5% for control (n = 8) and
recovery from fasting (n = 7), respectively,
P > 0.05 Fig. 2A]. Comparable protein
loading in various lanes was verified by gel staining (Fig.
2B). The expression of AQP2 protein in the cortex was
decreased by 60% in fasted animals compared with control group
(100 ± 7 vs. 40 ± 7% for control and fasting,
respectively, n = 8 for each, P < 0.004 Fig. 2C). During the recovery from fasting, AQP2
returned to control level [100 ± 7 vs. 82 ± 8% for
control (n = 8) and recovery (n = 8),
respectively, P > 0.05 Fig. 2C]. In the
inner medulla, AQP2 abundance was not affected in response to fasting
(100 ± 16 vs. 91 ± 13% for control and fasting,
respectively, n = 7 for each, P > 0.05 Fig. 2D). During the recovery period, AQP2 was, however,
increased above the control level (100 ± 16 vs. 192 ± 36%
for control and recovery, respectively, n = 7 for each,
P < 0.05 Fig. 2D). The equity in protein loading
in the cortex and inner medulla was verified by gel staining (data not
shown).
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Northern hybridization of AQP2.
Total RNA was isolated from the cortex and outer and inner medulla of
kidneys harvested from control, fasting, and recovery from fasting
animals. AQP2 mRNA expression was examined by Northern hybridization.
In the cortex, the expression of AQP2 mRNA was not altered in fasting
(n = 7, P > 0.05, Fig.
3A) or during recovery from
fasting (n = 6, P > 0.05, Fig.
3A) compared with control (n = 6). In the
outer medulla, AQP2 expression significantly decreased in fasting rats,
with mRNA levels decreasing by ~69% [from 100 ± 8% in
control (n = 6) to 31 ± 6% in fasting group
(n = 7), P < 0.003 Fig.
3B]. The recovery phase was associated with an
overexpression of AQP2 mRNA above the normal levels (from 100 ± 8% in control to 196 ± 21% in recovery group, n = 6 for each, P < 0.004 Fig. 3B). In the
inner medulla, total RNA was isolated from pooled tissues of three to
four rats in each group (a total of seven rats was used in each group
of control, fasting, and recovery), and used for Northern
hybridization. AQP2 mRNA expression was not altered in response to
fasting (Fig. 3C) compared with control. However, during the
recovery from fasting, AQP2 mRNA levels were increased by 43% above
the control levels (Fig. 3C). Taken together, these results
indicate that fasting causes polyuria and urinary concentrating defect,
primarily via the downregulation of AQP2 protein abundance in the outer
medulla and cortex. During the recovery period, the decrease in urine
volume and the increase in urine osmolality involve the recovery of
AQP2 protein in the cortex and outer medulla, and an increase in its
expression levels in the inner medulla.
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Immunoblot analysis of AQP1 expression.
AQP1 is the major water-absorbing channel in the proximal nephron
and is expressed in both apical and basolateral membranes of proximal
tubule and the entire descending limb of Henle's loop. To examine
whether the expression of AQP1 protein is also altered in fasting,
immunoblot analysis of AQP1 protein was performed. The results are
summarized in Fig. 4, and show that AQP1
protein abundance was not altered in fasting or during the recovery
from fasting in the cortex (Fig. 4A), outer medulla (Fig.
4B), and inner medulla (Fig. 4C).
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Role of Hypoglycemia in Fasting-Induced Polyuria
Blood glucose level and body weight in glucose-treated and fasted rats. Fasting in rats was associated with hypoglycemia (see above). To examine the possible role of hypoglycemia in fasting-induced polyuria, rats were supplemented with 2.5% glucose added to their drinking water and subjected to the fasting protocol. The presence of glucose in the drinking water prevented hypoglycemia during fasting, with blood sugar levels of 123 ± 17 and 130 ± 8.5 mg/dl in fasting and control, respectively (n = 4 for each, P > 0.05). The body weight was decreased in fasted rats (from 218 ± 4 before fasting to 200 ± 5.6 gm after fasting, n = 7, P < 0.00001). However, the net body weight loss (after adjusting for the gastrointestinal contents; see METHODS) was only 7 ± 0.01 g (P < 0.05).
Water balance and urine osmolality in glucose-treated and fasted
rats.
Addition of 2.5% glucose alone to the drinking water was associated
with a significant increase in fluid intake in normal animals compared
with no glucose (from 27 ± 1.8 ml/24 h in control to 42 ± 8 ml/24 h in the presence of glucose, n = 22 for each, P < 0.05, Fig.
5A). Interestingly, fluid
intake further increased to 76 ± 9 ml/24 h in fasted rats on
glucose (P < 0.005, n = 14, Fig.
5A). Urine volume paralleled fluid intake, as it was
significantly increased in the presence of glucose alone compared with
no glucose control (from 12 ± 2 ml/24 h for control to 24 ± 7 ml/24 h for glucose alone, n = 22 for each, Fig.
5B, P < 0.001). Urine volume further
increased to 73 ± 9 ml/24 h in response to fasting
(n = 14) compared with glucose alone (n = 22, P < 0.001, Fig. 5B). The presence of
2.5% glucose in the drinking water caused a significant drop in urine
osmolality compared with control (from 1,387 ± 100 to 685 ± 73 mosmol/kgH2O for control and glucose alone,
respectively, n = 22 for each, P < 0.0001, Fig. 5C). Urine osmolality further decreased to
100 ± 46 mosmol/kgH2O in fasted animals
(n = 14) compared with glucose alone (n = 22) (P < 0.0001, Fig. 5C). During the
24 h recovery from fasting, fluid intake (Fig. 5A) and
urine output returned to baseline levels (Fig. 5B). Urine
osmolality was, however, increased above the normal levels and reached
1,354 ± 197 for recovery (n = 6) vs. 685 ± 73 mosmol/kgH2O for glucose alone group (n = 22, P < 0.04, Fig. 5C). Taken together,
these results indicate that addition of 2.5% glucose alone to the
drinking water was associated with a significant impairment of water
balance and urine osmolality. Furthermore, the results show that 2.5% glucose treatment corrected hypoglycemia but did not prevent polyuria in fasting, indicating that fasting-induced polyuria is not secondary to hypoglycemia.
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Molecular Regulation of AQP2 Expression in Glucose-Treated and Fasted Rats
Immunoblot analysis of AQP2.
Microsomes were prepared from the cortex and outer and inner medulla of
kidneys harvested from normal rats (control), 2.5% glucose-treated
animals (glucose), and 2.5% glucose-treated, fasted rats (glucose + fasting). In the cortex, the presence of glucose alone in the
drinking water was associated with a significant decrease in AQP2
protein abundance (25%) [from 100 ± 7 to 75 ± 4% in
control (n = 4) and glucose alone (n = 5), respectively, P < 0.04, Fig.
6A]. In glucose-treated,
fasted rats AQP2 protein further decreased by 40% [from 100 ± 7% in control (n = 4) to 60 ± 6% in
glucose + fasting group (n = 5), P < 0.03, Fig. 6A]. In the outer medulla, 2.5% glucose
alone did not alter the expression of AQP2 protein (n = 5) compared with control (n = 4) (P > 0.05, Fig. 6B). However, in glucose + fasting group,
AQP2 protein abundance was decreased by 63% [from 100 ± 3 to
37 ± 9% in control (n = 4) and glucose + fasting (n = 7), respectively, P < 0.03, Fig. 6B]. In the inner medulla, the expression of
AQP2 protein did not change in glucose-treated (n = 5, P > 0.05) or in glucose + fasting animals
(n = 5, P > 0.05) compared with
control (n = 4) (Fig. 6C). Comparable
protein loading in various lanes of these blots was verified with
parallel gels stained with Coomassie brilliant blue (data not shown).
These results indicate that glucose treatment alone decreased AQP2
protein in the cortex, which is likely responsible for altered water
balance and decreased urine osmolality in this condition (Fig. 5).
Furthermore, fasting downregulates AQP2 protein in the cortex and outer
medulla despite correction of hypoglycemia.
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Northern blot analysis of AQP2 mRNA.
In a manner similar to that in the above experiments, the effect of
fasting on AQP2 mRNA expression was studied in glucose-treated animals.
Accordingly, total RNA was isolated from cortex and outer and inner
medulla of kidneys harvested from control, 2.5% glucose-treated, or
glucose + fasting groups. In the cortex, AQP2 mRNA expression was
not altered in glucose-treated animals (n = 6, P > 0.05), or in glucose + fasting
(n = 6, P > 0.05) compared with
control (n = 6) (Fig.
7A). In the outer medulla,
2.5% glucose alone did not alter the expression of AQP2 mRNA
(n = 6, P > 0.05) compared with
control (n = 6) (Fig. 7B). However, in the
glucose-treated and fasted group, AQP2 mRNA was decreased by 60%
[from 100 ± 20 to 40 ± 7% for control (n = 6) and glucose + fasting (n = 7), respectively,
P < 0.04; Fig. 7B]. Taken together, these
results indicate that fasting-induced nephrogenic urinary concentrating defect is due to the downregulation of AQP2 expression in the outer
medulla and cortex and that this effect is independent of blood glucose
levels.
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DISCUSSION |
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The studies above demonstrate that food deprivation resulted in polyuria and urinary concentrating defect (Fig. 1). Polyuria was associated with a decrease in water intake, indicating that it was not secondary to polydipsia (Fig. 1). The alterations in urine output and urine osmolality in fasting were reversed within 24 h of refeeding (Fig. 1). Examination of AQP2 water channel expression revealed that the abundance of this protein was heavily suppressed in the outer medulla (Fig. 2A) and significantly decreased in the cortex (Fig. 2C). The downregulation of AQP2 protein in fasting correlated with a significant decrease in the expression of AQP2 mRNA in the outer medulla (Figs. 3B and 7B) but not in the cortex (Figs. 3A and 7A). Urine osmolality and polyuria were corrected during the recovery from fasting and correlated with an upregulation in the expression of AQP2 in the cortex and outer and inner medulla (Figs. 2 and 3). Furthermore, the effects of fasting or recovery from fasting were specific to AQP2, as the expression of AQP-1 was not altered in these conditions (Fig. 4).
The mechanism underlying the decrease in AQP2 protein abundance without alteration in the mRNA expression levels in the cortex is not clear. An inhibition of the translation process and/or activation of the AQP2 protein turnover are possible explanations. Alteration in the cellular distribution or trafficking of AQP2 protein is unlikely, as total cellular protein was used for the immunoblotting experiments (see METHODS). In the inner medulla, the expression of AQP2 protein/mRNA was not affected by food deprivation (Figs. 2D and 3C). However, an increase in AQP2 mRNA and protein was observed during the 24-h recovery from fasting (Figs. 2D and 3C). The increase in AQP2 expression during the recovery period without alteration in fasting may result from the fact that the effects of fasting and recovery on collecting duct AQP2 are mediated via distinct signaling pathways. It is also plausible that the cell heterogeneity along the collecting tubule [principal cells in the cortical collecting duct (CCD) and OMCD vs. inner medullary collecting duct (IMCD) cells] may play a role in the differential response of AQP2 in fasting vs. recovery from fasting.
The chemical analysis of blood composition indicated that serum electrolyte profile and osmolality were comparable in control and fasting animals (Table 1). One would expect an increase in serum osmolality and sodium in the face of polyuria and decreased water intake in fasting. The reason for the lack of alteration in plasma osmolality and blood composition despite a significant fluid loss after 24 h of fasting is not very clear at the present. One possibility is that fasting has caused a transcellular fluid shift from intracellular to extracellular compartment, hence attenuating extracellular volume depletion due to polyuria.
Food deprivation was associated with hypoglycemia. Correction of hypoglycemia, however, did not prevent the generation of polyuria (Fig. 5B) and dilute urine (Fig. 5C) in fasted animals. Furthermore, the polyuria and urinary concentrating defect in glucose-treated, fasted animals was also associated with a significant decrease in AQP2 expression in both cortical (Fig. 6A) and OMCD (Fig. 6B). These results indicate that the downregulation of AQP2 protein and the resulting urinary concentrating defect in fasting animals is not mediated by hypoglycemia. Interestingly, there was an increase in water intake in fasted animals supplemented with glucose, which was opposite to the fasted animals on no glucose (Figs. 1A and 5A). Whether polyuria and AQP2 downregulation in fasting resulted from increased water intake (sweet taste) is unlikely. In water-loaded rats, studies by Ecelbarger et al. (10) showed a significant decrease in AQP2 protein abundance in the inner medulla along with a 46% decrease in the osmotic water permeability of IMCD of water-loaded rats. However, our studies indicate that AQP2 protein abundance was not altered in the inner medulla of glucose-supplemented and fasted rats (Fig. 6C), indicating that polyuria and decreased AQP2 in these animals is a result of fasting rather than water loading. Finally, the presence of glucose alone was associated with a significant alteration in water balance, as both fluid intake (Fig. 5A) and urine volume (Fig. 5B) were increased along with decreased urine osmolality (Fig. 5C). The increase in urine output in the presence of glucose is likely due to decreased AQP2 protein expression in the CCD (as shown in Fig. 6A).
Recent studies have demonstrated that the expression of AQP2 protein in the collecting duct is significantly decreased in several forms of acquired nephrogenic diabetes insipidus (such as lithium treatment, hypercalcemia, K+ depletion, and ureteral obstruction) (9, 21, 22) as well as models of nephrotic syndrome (puromycin aminonucleoside, adriamycin, and low protein diet) (12, 13, 21). Whereas other isoforms of water channels (i.e., AQP3 and AQP4) are expressed in the collecting duct, the urinary concentrating defect in the above conditions results mainly from the alterations in the AQP2 expression, as this transporter is the only apical water channel in the collecting ducts (8, 9, 15, 16). However, an eventual dysregulation of the basolateral AQP3 and AQP4 in response to fasting or recovery from fasting is not excluded.
The mechanism by which fasting downregulates AQP2 and, as a result, impairs urinary concentrating ability is not clear. One possibility is hormonal dysregulation in response to hypoglycemia. However, correction of hypoglycemia did not block the urinary concentrating defect in fasting animals (Figs. 5 and 6). An eventual role of alteration in the levels of circulating antidiuretic hormone (ADH) is unlikely. The plasma osmolality was not significantly affected, and BUN and serum creatinine remained unchanged in fasting, suggesting the stability of the volume status. Moreover, fasted animals have a significant negative water balance as a result of polyuria without polydipsia. Therefore, if anything, serum ADH should increase in response to the possible dehydration, and that should actually increase the expression of AQP2 water channel (8, 32).
Fasting is associated with protein deprivation, which has been shown to alter the urinary concentrating ability in both human (reviewed in Ref. 20) and experimental animals (13, 24, 29). Defective urine concentration in a low-protein diet was reversed by urea supplementation (13, 29). Whether polyuria and decreased urine osmolality in fasted animals result from decreased protein intake with subsequent reduction in urea delivery to the medullary interstitium remains speculative. Such a possibility is unlikely, as the effect of a low-protein diet requires 2-3 wk to develop (24, 29), whereas fasting-induced urinary concentrating defect occurs within 24 h.
Several hormones, such as growth hormone, adrenal steroid, and prostaglandins, have been reported to be increased in fasting (2, 15, 19, 26). Prostaglandins are known to antagonize the effect of AVP on water transport in the collecting duct (11). Adrenal gland steroids also play an important role in the process of urinary concentrating ability in both human (35) and experimental animal (18, 30). Whether these hormones play any role in fasting-induced urinary concentrating defect remains to be determined. Another interesting observation in this model is the lack of any significant alteration in serum sodium in fasted animals despite significant polyuria and negative water balance (Table 1). It is possible that food deprivation is also associated with an increase in urinary Na+ loss. It has been reported that fasted male rabbits developed a polyuric-polydipsic syndrome associated with enhanced urinary Na+ loss (6, 28). However, rats and rabbits respond differently to fasting in that rabbits develop both polyuria and polydipsia (1, 14, 17, 27), whereas rats develop polyuria and hypodipsia (Fig. 1). It is worth mentioning that animals may have not reached a steady state after 24 h of fasting. Hence, more studies are required to fully describe the renal response to fasting with respect to urinary concentrating mechanism and renal sodium handling at both short and long term.
In conclusion, fasting impairs the urinary concentrating ability and, as a result, causes polyuria. This effect is mediated via suppression of AQP2 expression in the collecting duct. The inability to concentrate urine in fasting is rapidly reversible on refeeding and is associated with a return of AQP2 expression to normal levels. Lastly, fasting-induced urinary concentrating defect is independent of glucose homeostasis.
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ACKNOWLEDGEMENTS |
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These studies were supported by National Institute of Diabetes and Digestive and Kidney Disease Grants RO1-DK-46789, RO1-DK-52821, and RO1-DK-54430, and by the University of Cincinnati Academic Development Fund.
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FOOTNOTES |
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1 The densitometry values reported in the RESULTS section correspond to the level of the expression on the nonglycosylated form (29 kDa) of AQP2 or AQP1 water channels, which is expressed as a percentage of pooled controls.
2 The levels of AQP2 protein or mRNA expression shown in bars reflect the mean of blots from different experiments pooled together. The blots shown in the figures are representative blots only.
Address for reprint requests and other correspondence: H. Amlal/M. Soleimani, Univ. of Cincinnati Medical Center, 231 Bethesda Ave, MSB 5502, Cincinnati, OH 45267-0585 (E-mail: Manoocher.Soleimani{at}uc.edu or Hassane.Amlal{at}uc.edu).
The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Received 30 August 2000; accepted in final form 21 November 2000.
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