1Institute for Pediatric Urology, Department of Urology, Children's Hospital of New York, and 2Department of Pathology, Weill Medical College of Cornell University, New York, New York 10021
Submitted 15 December 2003 ; accepted in final form 16 August 2004
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ABSTRACT |
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Sprague-Dawley rats; interstitial fibrosis; apoptosis; transforming growth factor-; FSP; nitric oxide
It has been shown in a variety of chronic renal diseases that the presence of interstitial fibrosis is a major determinant of GFR (5, 6, 36). Thus, despite the presence of seemingly normal glomeruli, significant decreases in GFR have been found. Interstitial fibrosis may contribute to decreased GFR by a variety of mechanisms including tubular atrophy, tubular ischemia, and obliteration of postglomerular peritubular capillaries (12).
Many factors have been implicated in fibrosis in UUO. Two significant mediators are transforming growth factor- (TGF-
) and nitric oxide (NO) (2, 7). TGF-
is a profibrotic and proapoptotic mediator in UUO (29). Increases in TGF-
have been noted in both neonates (9) and adult kidneys (8) after relief of UUO. In contrast, NO, a multifunctional mediator synthesized from L-arginine by NO synthase (NOS) (33), has been shown to be antiapoptotic (29) and antifibrotic in UUO (21, 32), in addition to modifying renal hemodynamics (11, 13, 19, 37). Other studies suggest a reciprocal relationship between NO and TGF-
.
Because interstitial fibrosis is implicated in renal functional loss, it is possible that recovery of renal function after relief of UUO is at least partially dependent on changes in the interstitium. Therefore, in the present study, we examined the recoverability of both GFR and RBF over a period of 28 days following relief of 3 days of UUO. In addition to examining renal function, we also examined renal tissue for the presence of fibrosis and fibroblasts, tubular apoptosis, macrophage infiltration, and expression of both TGF- and NO. Our goal was to determine if changes in renal function and renal histopathology were convergent or divergent.
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MATERIALS AND METHODS |
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In vivo UUO and relief of UUO. Left UUO was performed as previously described (29). To ensure sufficient length of ureter for the ureteroneocystotomy, the left lower ureter was ligated using 30 silk at two places close to the ureterovesical junction.
Three-day UUO was reversed using microsurgical methods, described briefly here. Rats were anesthetized intraperitoneally and positioned supine under two heating lamps. A midline abdominal incision was made, and under 8x magnification, the dilated left ureter was identified and dissected free of surrounding tissues. An 18-gauge angiocatheter was introduced through the midanterior bladder wall and exited through the left lateral bladder wall. The ureter was transected 1 cm above the level of obstruction, and the open end was cannulated with the angiocatheter. With the use of a 100 nylon suture, a ureteral bladder anastomosis was effected in an interrupted fashion. The catheter was then removed and the bladder-puncture defect was repaired with a 70 prolene suture. The abdominal incision was closed in two layers including muscle and skin.
Renal function measurement. Renal function was measured as detailed below and described previously (22). RBF was calculated using PAH clearance; GFR was calculated using inulin clearance, both according to standard formulas. Urine and plasma concentrations of PAH and inulin were detected using standard chemical methods (15, 18). PAH was detected colorimetrically at 550 nm using p-dimethylaminocinnamaldehyde, and inulin at 595 nm using anthrone. For each rat, the values obtained for three clearance periods were averaged. Values were normalized to body weight (body weights shown in Table 3).
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To document that patency of the anastomosis had been maintained throughout the period following relief of UUO, an antegrade study was carried out at the conclusion of the measurement of renal function. A tube was inserted into the midureter and was ligated by 30 silk; 0.9% saline solution or ink was introduced into the ureter from a level of 18 inches using gravity, and patency of the anastomosis was confirmed by examining the entry into/efflux from the bladder. Only rats with patent anastomoses were used in these studies. After measurement of renal function, both kidneys were harvested for analysis.
RBF and GFR were measured in both and left and right kidneys of group 1 rats (group 1). In groups 3-5, RBF and GFR were measured at 7, 14, and 28 days postrelief of UUO, respectively. In group 2, RBF and GFR were measured at 1 day following UUO, because it was not possible to measure RBF and GFR at 3 days following UUO (too little urine flow). However, previous data demonstrate that RBF and GFR at 3 days of UUO are either comparable to or decreased from that measured 1 day after UUO (25); the present results obtained at 24 h of UUO document a significant decrease in renal function, consistent with previous findings (1, 25, 42). For tissue analysis in group 2, tissues were taken from rats subjected to UUO for 3 days. Analyses of renal function and tissue were made using n = 8 rats in groups 1, 4, and 5 and n = 7 rats in groups 2 and 3.
Urinary NO2/NO3. A 24-h urine sample was collected from rats in group 5 placed in metabolic cages at the following times: 1 day before UUO, and 3, 7, 14, 21, and 27 days after relief of UUO. The urine was collected in a reservoir containing 2-propanol and samples were frozen at 80°C until assay. Urinary NO2/NO (16, 28, 44) levels were measured by the Griess reaction after copperized cadmium treatment. The results were normalized to body weight, as the weight of the animals changed during the study (see Table 3).
Assessment of renal morphology and interstitial fibrosis. After renal function measurement, sections of previously obstructed and contralateral kidneys were fixed in 10% neutral buffered formalin and embedded in paraffin. Sections 5-µm thick were stained with hematoxylin and eosin and Masson's trichrome for light microscopic analysis. Slides were examined by a board-certified pathologist (S.V.S.). Histological studies were performed in a blinded fashion. Renal morphology including tubular dilatation and leukocyte infiltration was assessed. The general presence of interstitial fibrosis was assessed in slides stained with Masson's trichrome. In addition, interstitial fibrosis was assessed by measurements of interstitial volume, using a point-counting method as previously described (45).
Determination of tissue TGF-1.
Kidney tissues were stored at 80°C until assay. All samples were assayed using ELISA, following manufacturer's instructions (R&D Systems, Minneapolis, MN). In brief, to activate TGF-
1 in tissue, the samples were homogenized with 1 N HCl and neutralized with 1.2 N NaOH/0.5 M HEPES. Samples were analyzed using a microplate reader set to 450 nm with correction set at 550 nm. Standard curve and all samples were run in duplicate.
Immunohistochemical analysis. Immunohistochemical analyses for inducible and endothelial NOS (iNOS and eNOS) and macrophages were performed. Paraffin-embedded tissue sections were made as described above. Immunohistochemical analyses were performed as previously described (28, 30). In brief, the concentrations of primary antibodies were 1:100 for iNOS (monoclonal, Santa Cruz Biotechnology), 1:200 for eNOS (polyclonal, Santa Cruz Biotechnology), and 1:75 for macrophage (monoclonal, ED1 macrophage, Serotec). Biotinylated rabbit antimouse secondary antibody (Vector Laboratories, Burlingame, CA) was used for iNOS staining, and biotinylated goat antirabbit secondary antibody (Vector Laboratories) was used for eNOS staining. Horseradish peroxidase (HRP)-linked rabbit antimouse secondary antibody (Dako) was used for macrophage detection. Avidin-biotin peroxidase complex (Vector Laboratories) was used for iNOS and eNOS detection. Sections were developed with diaminobenzidine (DAB). Sections were then counterstained with hematoxylin. Positive macrophages were counted in 10 high-power fields (x400) by two independent investigators in a blinded fashion and an average was obtained.
We also analyzed tissue for the presence of fibroblasts using immunohistochemistry. The antibody used was DAKO #S100-A4. The S100-A4 antigen is also known as FSP-1 and has found to be expressed by fibroblasts, but not epithelial cells (35, 41). Antigen was retrieved by incubating cells with proteinase K for 20 min in an oven. Slides were then processed as is carried out routinely for immunoperoxidase. The primary antibody was used at a dilution of 1:100. Ten high-power fields were counted in each slide and averaged together. Staining for S100-A4 was found in spindle-shaped interstitial cells and also in cells that were round and were identified as inflammatory cells by the pathologist. Only spindle-shaped cells were included in the counts. Samples incubated without primary antibody exhibited no staining.
In situ detection of DNA strand breaks. To quantitate nuclei with fragmented DNA, the TUNEL assay was performed with in situ TUNEL kit (Intergen, Purchase, NY) as previously described (28, 30). Briefly, after deparaffinization and quenching endogenous hydrogen peroxide, to retrieve antigen, sections were treated with 1 mg/ml proteinase K for 15 min. The sections were rinsed with PBS and incubated with deoxynucleotidyl transferase (TdT) with digoxigenin-dNTP for 1 h. The reaction was stopped with terminating buffer. Slides were then washed with PBS, and peroxidase-conjugated antidigoxigenin antibody was applied for 30 min. After being washed with PBS, slides were developed with DAB and counterstained with 10% hematoxylin. Positive cells in renal tubules were quantitated in the same fashion as macrophages.
Western blotting analysis. Western blot analyses for iNOS and eNOS were performed in rats in all groups. After the measurement of renal function, kidney samples were harvested and stored in 80°C until use. Appropriate amount of kidney samples was homogenized in lysis buffer and centrifuged at 13,000 rpm for 30 min. The supernatant was separated, and the protein concentration was determined with the Bradford protein assay (Bio-Rad, Hercules, CA). For the Western blot analysis, equal amounts of protein were loaded. Western blot analysis was then performed as previously described (28, 30). In brief, the concentrations of primary antibodies were 1: 5,000 for iNOS (polyclonal, Transduction Laboratories, Lexington, KY) and 1:3,000 for eNOS (polyclonal, Santa Cruz Biotechnology). The concentration of HRP-conjugated secondary antibody was 1:5,000. The intensity of each band was quantified by National Institutes of Health image. iNOS and eNOS were detected at 130 and 133 kb, respectively. Relative intensity was expressed as percent control intensity (or an arbitrary unit).
Statistical analysis. All results are expressed as means ± SE and were analyzed for significance by one-way ANOVA and multiple comparison tests.
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RESULTS |
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RBF in group 1 was 1.02 ± 0.11 ml·min1·100 g1 in the right kidney, which was not significantly different from 1.01 ± 0.14 ml·min1·100 g1 in the left. RBF of the obstructed group 2 kidney decreased by greater than 90% (Table 2). By day 7 after relief of UUO, RBF in the POK had improved, and by day 14 was not significantly different from baseline. By 28 days of relief, RBF of the POK was significantly higher than untreated control (P < 0.05). In groups 4 and 5, RBF of the CLK was significantly higher than group l RBF. Furthermore, total RBF after 14 and 28 days of relief was significantly higher than group 1. At 7 and 14 days of relief, the percentage of RBF in the POK was significantly lower than control group; however, there was no significant difference between control group and group 5.
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In group 2 obstructed kidneys, almost no fibrosis was seen (interstitial volume = 0.64 ± 0.2%). In the POK, mild blue staining was seen in two of five animals in group 3 (4.80 ± 1.21%; Fig. 1A). Increased blue staining was seen in almost all group 4 kidneys (10.35 ± 1.02%, P < 0.05, compared with group 3) and group 5 kidneys (24.56 ± 3.53%, P < 0.05, compared with group 4; Fig. 1B). When the CLK was examined, there was minimal fibrosis in group 3 (0.60 ± 0.39%) and some slight fibrotic changes in groups 4 (1.19 ± 0.73%) and 5 (3.62 ± 0.71%). Kidneys in group 5 had significantly more fibrosis compared with groups 3 and 4 (P < 0.05), although this was much less than in the POK. These results demonstrate that interstitial fibrosis progresses after relief of UUO.
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Evaluation of iNOS and eNOS. Because urinary NO2/NO3 was increased in group 5, we were interested in examining renal expression of NOS by both immunostaining and Western blot. iNOS (Fig. 6A) was weakly expressed in renal tubular cells in group 1 kidney. Relatively higher staining was seen in cortex. In 3-day UUO (group 2), increased iNOS staining in tubular cells was seen in both medulla and cortex. Especially proximal and distal tubules in cortex were strongly stained with iNOS (Fig. 6B). In the POK (groups 3, 4, and 5), positive staining was seen in proximal tubules, convoluted distal tubules, and thick ascending limbs (Fig. 6C). Less staining was seen in other distal tubules and collecting ducts. Glomeruli had minimal staining. In the CLK, staining was also increased, similarly to that seen in the POK (not shown).
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iNOS was also examined by Western blot analysis. The 3-day UUO showed a small increase in iNOS compared with the control (Table 4 and Fig. 7A). Expression was increased in both CLK and POK in all relieved groups compared with groups 1 and 2 (Table 4 and Fig. 7B). There was no significant difference in these increases between CLK and POK in all groups.
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DISCUSSION |
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Both RBF and GFR of the POK returned to control levels by 14 days after relief of 3-day UUO. These results are similar to previous studies that demonstrated recovery of renal function after relief of 24-h UUO in rats (1). Relief of longer-term UUO, with variable recovery times, has not led to complete recovery of renal function in UUO (14, 27). Recovery of GFR or RBF at 1 mo after relief of UUO may not predict long-term recovery. Furthermore, recovery of total GFR may not indicate complete recovery from renal injury. After relief of 24-h UUO, 15% of superficial nephrons were not filtering at 14 days, and the remainder exhibited increased single nephron GFR (1). Hyperfiltration of single nephrons can lead to renal damage. Future studies will examine the long-term results of relief of 3 days of UUO to determine if the immediate recovery of renal function is sustained.
We examined several indicators of renal damage after the release of UUO. We found a gradual increase in the amount of trichrome staining, indicating interstitial fibrosis, which was strongest 28 days after relief of UUO. The tissue concentration of TGF-1 was increased in the POK after relief of 3 days of UUO. Tubular apoptosis was still evident 28 days after the relief of UUO. An increase in macrophages was also found postrelief of UUO. Furthermore, the increase in interstitial fibroblasts noted at 3 days of UUO was also sustained. Thus several different markers of renal damage were significantly increased or maintained at levels higher than control following relief of UUO. There was also evidence of progressive histopathological changes in the CLK, although these were not as severe as in the POK. In the CLK, tissue TGF-
was significantly increased after relief of UUO, and there was a slight but significant increase in interstitial volume at 28 days. It is not clear why TGF-
is increased in the CLK. However, we previously showed that renal tubules are a source of TGF-
in the kidney (45). Our unpublished data show increased tubular proliferation in the CLK, and these cells may account for the increased TGF-
. In contrast to the POK, tubular apoptosis, fibroblasts, and macrophage numbers were not different in the CLK compared with controls. Thus, despite similar increases in TGF-
, the contralateral kidney is less affected than the previously obstructed kidney. In this study, we examined only whole kidney levels of TGF-
. It is possible that there are differences in the regional expression of TGF-
between POK and CLK that would differentially affect the response of the kidneys. Even if there is similar expression of TGF-
in both kidneys, the POK, having been previously injured, may be more susceptible to the effects of TGF-
. Or, alternatively, other factors in addition to TGF-
may be responsible for the increased damage in the POK more than in the CLK.
Urinary NO metabolites increased after relief of UUO compared with baseline. Western blot and immunohistochemistry confirmed increased expression of both iNOS and eNOS in the POK and CLK, suggesting increased renal synthesis of NO. Previous studies have implicated NO in the changes in RBF in the obstructed kidney following UUO (13, 37). As NO is a known vasodilator (33), it may also contribute to the recovery of RBF after relief of UUO in the POK. Furthermore, we and others demonstrated that NO appears to be protective in UUO. Both interstitial fibrosis and apoptosis are increased in mice with a targeted deletion of iNOS (21, 30). Arginine feeding was shown to decrease fibrosis, and angiotensin-converting enzyme inhibitors that increase NO are also antifibrotic (23, 32). As we demonstrated increased urinary NO at 28 days postrelief, it is possible that the increased NO results from an attempt by the kidney to oppose the action of TGF-. This rise in NO would thus be beneficial to both renal function, as shown above, and to offset the deleterious effects of TGF-
. Alternatively, other mediators may be involved in the response of the kidney to continuing damage. Further experiments in which the NO system is modulated during the recovery period would be useful in delineating the role of NO.
Furthermore, the increased expressions of iNOS and eNOS in the CLK suggest that it may contribute to the functional changes in the CLK. In our study, both GFR and RBF in CLK were increased after relief of UUO. Similar findings were reported previously. In dogs, the CLK exhibited compensatory functional changes after relief of UUO (43). Similarly in rats, renal function in the CLK was increased either 7 days (14) or 3 mo (27) after relief of UUO. We demonstrated herein that the CLK maintained a significantly higher percentage of the RBF and GFR at 7 and 14 days postrelief. The findings of increased expression of NOS in the CLK suggest that NO may contribute to this.
In a neonatal rat model, Chevalier et al. (9) demonstrated progression of interstitial fibrosis after relief of UUO. Twenty-eight days after relief of UUO, interstitial collagen, -smooth muscle actin, and TGF-
1 were dramatically increased in the POK compared with sham-operated rats (10). Consistent with the present report, GFR after 28 days of relief was not significantly different from baseline GFR. At 1 yr following relief, interstitial collagen, macrophage infiltration, and
-smooth muscle actin immunostaining were significantly increased in both POK and CLK (10). GFR in the POK was at a level of only 20% of sham-operated rats. The neonatal rat is born with an immature kidney (39), and thus it might have been anticipated that an insult such as obstruction would lead to long-term damage, even if reversed. The data shown here demonstrate that even in an adult kidney, 3 days of UUO are sufficient to set off a chain of events that will lead to irreversible renal damage over time. Our results are similar to those reported by Morrissey et al. (31) who used a 3-day UUO followed by a 7-day relief model. In that study, interstitial volume and interstitial collagen IV deposition were increased in the relieved POK compared with control. In contrast to both of these studies, Koo et al. (24) reported a modest improvement in the POK at 10 days after relief of a 10-day UUO (0.26 ± 0.04 volume units) compared with an unrelieved 10-day UUO (0.32 ± 0.05). It is possible that with a longer time after relief, there would be a progression of fibrosis.
Interstitial fibrosis is a complex process that involves synthesis and degradation of extracellular matrix proteins, cellular infiltration, epithelial mesenchymal transformation, and tubular apoptosis and atrophy (12, 34, 40). The end result of interstitial fibrosis is decreased GFR, which may result from several factors. Tubular atrophy can result in atubular glomeruli; these glomeruli, which are detached from their corresponding proximal tubules, are unable to filter properly (26). The accumulation of extracellular matrix can isolate tubules from their oxygen supply and may also result in obliteration of peritubular capillaries, which can also result in decreased GFR (3, 4, 38). Given the importance of interstitial fibrosis, it is not unexpected that a large number of studies have examined interventions targeted to numerous cytokines designed to ameliorate interstitial fibrosis (12, 17). However, almost none have examined renal function in those animals. Because the ultimate goal of these interventions is preservation of renal function, it is surprising that there has been so little study of renal function in fibrotic models. In the study by Morrissey et al. (31) cited above, RBF was not significantly different from control after 7-day relief of 3-day UUO, whereas in the present study, we noted recovery by 14 days. GFR was still decreased compared with control. When bone morphogenetic protein-7 (BMP-7) was administered concomitant with relief of UUO, both GFR and interstitial volume changes were improved compared with relief alone.
Thus, in the present study, we examined both renal function and renal histopathology concomitantly in UUO, a model of rapidly progressing fibrosis. We chose to study surgical reversal of obstruction to mimic the clinical situation. The success of surgical reversal is monitored by following renal function. However, our results suggest that although RBF and GFR appear to recover in the short term, that the renal fibrosis set in motion by obstruction actually progresses. This suggests that in the long term, renal function may again decrease as the fibrosis progresses further. This also suggests that concomitant treatment with an antifibrotic agent may be an appropriate treatment when obstruction is reversed, as noted above using BMP-7. Preliminary studies in our laboratory using an antibody to TGF- showed an amelioration of the fibrotic process in postrelief UUO, validating the effectiveness of this strategy.
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GRANTS |
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FOOTNOTES |
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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.
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REFERENCES |
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