Uranyl Acetate-induced Acute Renal Failure Research Articles

Transient myofibroblast differentiation of interstitial fibroblastic cells relevant to tubular dilatation in uranyl acetate-induced acute renal failure in rats

To investigate the mechanisms of myofibroblast differentiation of interstitial fibroblastic cells (FCs) in rats with uranyl acetate-induced acute renal failure (ARF), we examined the relationship between the expression of alpha-smooth muscle actin (alpha-SMA), myofibroblast phenotype and tubular dilatation as well as cell shape and adhesion of FCs. Peritubular alpha-SMA-positive myofibroblasts appeared after induction of ARF and extended along the damaged, dilated proximal tubules and then almost disappeared after proximal tubular recovery. The perimeter of proximal tubules correlated with fractional areas stained for alpha-SMA (P<0.001). Most alpha-SMA-positive cells did not incorporate [3H]-thymidine, indicating a low proliferative activity. Transmission electron microscopy showed that FCs increasingly attached to the tubular basement membrane by elongated cytoplasm-containing microfilament bundles, which formed abundant adherens and gap junctions from day 4 to day 7. Scanning electron microscopy showed hypertrophic FCs covering large areas of tubules after induction of ARF. Administration of chlorpromazine, which can inhibit cytoskeletal movement, after induction of ARF partially inhibited myofibroblast differentiation of FCs immunohistochemically and morphologically and resulted in more dilated proximal tubules in concert with aggravation of renal dysfunction and inhibition of regenerative repair at day 4 than vehicle-administered rats. Our results indicate that mechanical tension, judged by tubular dilatation, may contribute to the induction of alpha-SMA phenotype with increased stress fiber formation and intercellular junctions in FCs to support damaged nephron structures by adjusting tensional homeostasis in rats with uranyl acetate-induced ARF.

Important role for fibronectin-EIIIA during renal tubular repair and cellular recovery in uranyl acetate-induced acute renal failure of rats.

The present study was designed to identify the source and kinetics of an alternatively spliced "embryonic" cellular fibronectin EIIIA (cFn-EIIIA) in relation to regenerating renal tubules in uranyl acetate (UA)-induced acute renal failure (ARF) in rats. Damage of the proximal tubules was found as early as day 2 after induction of ARF, peaked at day 5, and was almost substituted by epithelial relining by day 7. Immunohistochemistry showed de novo deposition of cFn-EIIIA in peritubular regions as early as day 2, then on the tubular basement membrane (TBM) after day 4. beta1 Integrin, the receptor for Fn, was mainly found at the basal side of tubules in the normal control and increased in the interstitium after induction of ARF, but the staining pattern gradually returned to the control after day 7. Immunoelectron microscopy revealed that cFn-EIIIA was produced initially by the peritubular endothelium and later by fibroblastic cells and was deposited to the TBM, on which regenerating tubules proliferated, probably with cFn-EIIIA production. beta1 Integrin was expressed in cFn-EIIIA-producing cells, especially in regenerating tubular cells, suggesting that cFn-EIIIA signal transduction affects regenerating tubules. Transforming growth factor (TGF)-beta1 was found in some damaged proximal tubules and interstitial cells after induction of ARF and later in the regenerating tubules. CFn-EIIIA and beta1 integrin mRNA levels were upregulated as early as day 2. TGF-beta1 mRNA level significantly increased after day 3, suggesting a modulatory role for TGF-beta1 on cFn-EIIIA production, but not by day 2. Our data suggest that cFn-EIIIA production by the endothelium during the very early response to tubular injury and by fibroblastic cells and regenerating tubules may play an important role in the cellular recovery of UA-induced ARF in rats.

Temporary changes in macrophages and MHC class-II molecule-expressing cells in the tubulointerstitium in response to uranyl acetate-induced acute renal failure in rats.

The present study was designed to asses the dynamic changes in macrophages (Møs) with or without expression of major histocompatibility complex (MHC) class-II molecule in response to uranyl acetate-induced acute renal failure (ARF) in rats. ED1+ monocytes/Møs infiltrated into the interstitium as early as day 2, peaked in number on day 5 after uranyl acetate-induced ARF. ED1+ cells did not correlate with necrotic tubules but accumulated abundantly in the vicinity of the Ki67+ regenerating proximal tubules around days 4-5. Afterward, regeneration of proximal tubules was accelerated. After day 5, some ED1+ cells entered the tubular lumen, and became ED1+ giant cells, which had features of phagocytic Møs by immunoelectron microscopy, peaking in number on day 7. Most ED1+ cells did not incorporate [(3)H]-thymidine, indicating lack of active proliferation. The number of OX6+ cells (directed to MHC class-II molecule) in the interstitium significantly increased on day 4 and peaked on day 5. Double staining revealed that ED1+OX6- cells entered the tubular lumen while ED1+OX6+ cells remained in the peritubular regions. Osteopontin (OPN) protein and mRNA were significantly upregulated. No specific relationship could be found between OPN+ regenerating proximal tubules and ED1+ cells, but most ED1+ giant cells were OPN+ and intermingled among OPN+ cell debris. Our findings suggest that ED1+ Møs are actively associated with regenerating proximal tubules and, thus, might promote proximal tubular regeneration. ED1+OX6- Møs may function as scavengers and phagocytose cellular debris in the tubular lumen, cleaning the wound site. OPN might be involved in this process. ED1+OX6+ Møs in the peritubular regions may act as outpost of the defense system to monitor incoming antigens. Our data indicate that Møs with or without expressing MHC class-II molecule contribute to the defense and repair of injured proximal tubules in this ARF.

Relation of Distal Nephron Changes to Proximal Tubular Damage in Uranyl Acetate-Induced Acute Renal Failure in Rats

Aims: To elucidate the pathophysiological roles of the changes of distal nephron in uranyl acetate (UA)-induced acute renal failure (ARF), we investigated the relation of changes of constituent molecules in distal nephron to proximal tubular damage and repair in UA-treated rats. Methods: ARF was induced in rats by intravenous injection of UA, and all rats received bromodeoxyuridine (BrdU) intraperitoneally 1 h before sacrifice. Results: Proximal tubular damage with necrosis appeared as early as day 2, mainly in the outer stripe of outer medulla and reached a peak level at day 5. Slight cellular damage was evident in the distal nephron as early as day 3, reaching a peak level around day 9. Immunoreactive BrdU- or vimentin-positive regenerating proximal tubules (PT) appeared at day 2 and regenerating PT relining was almost completed by day 7. Immunostaining for EGF, which was constitutively expressed in the thick ascending limb (TAL) and distal convoluted tubule (DCT), diminished significantly as early as day 2, when PT regeneration became evident, and remained below normal levels until day 21. In contrast, slight immunoreactivity for EGF was observed in regenerated PT accompanying brush-border formation mainly after day 9, suggesting newly expressed EGF might contribute to PT maturation. Lectin staining or immunostaining for representative constituent molecules of the thin descending limb, TAL, DCT and collecting duct demonstrated marked and transient reduction after day 5. Conclusions: EGF was not associated with regenerating PT, but may be involved in the maturation of PT. Transient reduction in expression of constituent molecules of the distal nephron following the reduction in EGF could reflect dedifferentiation or phenotypic simplification during regenerative repair of PT in UA-induced ARF in rats.

Mycophenolate Mofetil Inhibits Regenerative Repair in Uranyl Acetate-Induced Acute Renal Failure by Reduced Interstitial Cellular Response

We recently reported that transient appearance of interstitial myofibroblasts and infiltrating macrophages might play a role in cellular recovery in uranyl acetate (UA)-induced acute renal failure (ARF). Here we tested the effects of mycophenolate mofetil (MMF), which attenuates infiltration of lymphocytes, macrophages, and myofibroblasts, but does not suppress epithelial regeneration, on renal tissue repair. Rats treated with MMF (20 mg/kg/day) or vehicle were sacrificed at 2, 5, and 7 days after induction of ARF by injection of 5 mg/kg UA. Renal tissues were immunostained for bromodeoxyuridine (BrdU) and Ki67, alpha-smooth muscle actin (alpha-SMA), ED1, and CD43. The expression levels of alpha-SMA mRNA were examined by reverse transcription-polymerase chain reaction. Body weight loss or serum albumin levels were similar in MMF and vehicle rats during the experiment. In vehicle group, serum creatinine (Scr) significantly increased after day 5, but proximal tubular (PT) damage score increased as early as day 2 after UA injection. BrdU- or Ki67-positive regenerating tubular cells, ED1-positive macrophages and alpha-SMA-positive myofibroblasts significantly increased in the interstitium after day 5. In MMF-treated rats, Scr and PT damage score significantly increased at day 7 and the number of regenerating PT were significantly reduced compared with vehicle-treated rats at days 5 and 7. The numbers of macrophages and myofibroblasts and the expression of alpha-SMA mRNA were significantly lower in MMF than in vehicle rats at day 5, indicating that reduced interstitial cellular response is linked to the inhibition of regenerative repair. CD43-positive lymphocytes were significantly reduced in MMF group than in vehicle group at day 7, suggesting that lymphocyte infiltration does not seem to contribute to early regenerative response of proximal tubules. The transient appearance of myofibroblasts and macrophages in the interstitium may promote regenerative repair in UA-induced ARF in rats.

Possible Involvement of Myofibroblasts in Cellular Recovery of Uranyl Acetate-Induced Acute Renal Failure in Rats

Cellular recovery in acute renal failure is a form of wound healing. Fibroblast-like cells or myofibroblasts are involved in wound healing. We examined the serial changes in tubular damage and origin and kinetics of regenerating cells in uranyl acetate-induced acute renal failure, with a special emphasis on interstitial myofibroblasts. Acute renal failure was induced in rats by intravenous injection of uranyl acetate (5 mg/kg). All rats received bromodeoxyuridine intraperitoneally 1 hour before sacrifice. Serial changes in the distribution of tubular necrosis and bromodeoxyuridine-incorporated or vimentin-positive regenerating cells, and their spatial and temporal relation to alpha-smooth muscle actin-positive myofibroblasts as well as ED 1-positive monocytes/macrophages were examined. Necrotic tubules initially appeared around the corticomedullary junction after uranyl acetate injection, then spread both downstream and upstream of proximal tubules. Peritubular alpha-smooth muscle actin-positive myofibroblasts appeared and extended along the denuded tubular basement membrane, establishing network formation throughout the cortex and the outer stripe of outer medulla at days 4 to 5. Tubular regeneration originated in nonlethally injured cells in the distal end of S3 segments, which was confirmed by lectin and immunohistochemical staining using markers for tubular segment. Subsequently, upstream proliferation was noted along the tubular basement membrane firmly attached by myofibroblasts. During cellular recovery, no entry of myofibroblasts into the tubular lumen across the tubular basement membrane was noted and only a few myofibroblasts showed bromodeoxyuridine positivity. The fractional area of alpha-smooth muscle actin-positive interstitium reached a peak level at day 7 in the cortex and outer stripe of outer medulla, then gradually disappeared by day 15 and remained only around dilated tubules and in the expanded interstitium at day 21. ED 1-positive monocytes/macrophages were transiently infiltrated mainly into the region of injury. They did not show specific association with initially necrotic tubules, but some of them located in close proximity to regenerating tubules. Nonlethally injured cells at the distal end of proximal tubules are likely to be the main source of tubular regeneration, and the transient appearance of interstitial myofibroblasts attached to the tubular basement membrane immediately after tubular necrosis might play a role in promoting cellular recovery in possible association with monocytes/macrophages in uranyl acetate-induced acute renal failure.

Role of apoptosis in uranyl acetate-induced acute renal failure and acquired resistance to uranyl acetate

We have previously reported that animals recovering from uranyl acetate (UA)-induced acute renal failure (ARF) were resistant to subsequent insult. Recent evidence suggests that apoptosis participates in tubular damage. We investigated the role of apoptosis in UA-induced ARF and attenuation of ARF in acquired resistance to UA in rats. ARF was induced by an intravenous injection of UA (5 mg/kg) in rats. Rats of group 1 were injected with UA and followed for 28 days. Group 2 rats were injected with a second dose of UA (5 mg/kg) 14 days after the first injection and were followed for 14 days. All rats received an intraperitoneal injection of bromodeoxyuridine (BrdU) one hour before sacrifice. Using kidneys, histologic examination and immunohistochemical detection of proliferating cell nuclear antigen (PCNA), BrdU, Bcl-2, and Bax were performed. To detect apoptosis, electron microscopy, analysis of DNA fragmentation, and the TUNEL methods were adopted. UA increased the number of damaged renal tubules and serum creatinine, which peaked at 5 days in group 1, but both returned to baseline values by 14 days. Apoptosis was confirmed by electron microscopy and the "ladder" pattern of DNA fragments on gel electrophoresis. The number of apoptotic tubular cells evaluated by the TUNEL method showed two peaks at days 5 and 14 in group 1. The second peak of TUNEL-positive cells was preceded by an increased number of BrdU-positive nuclei, PCNA-positive nuclei, and total number of tubular epithelial cells. Renal damage after the second UA injection was markedly reduced. The peak number of apoptotic cells in group 2 was significantly less than that in group 1. Two peak levels of apoptotic cells occurred in UA-induced ARF. The first peak might play a role in UA-induced tubular damage, while the second one might represent the removal of excess regenerating cells during the recovery phase. Modulation of apoptotic cell death might be involved in the acquired resistance to rechallenge injury by UA.

Glycine attenuates apoptotic cell death in uranyl acetate-induced acute renal failure in rats

Background. Although uranyl acetate (UA) is known to induce apoptosis in renal tubular cells, the pathophysiological role of apoptotic cell death in UA-induced acute renal failure (ARF) is not clear. In this study, we examined whether glycine, which is known to provide protection against nephrotoxic acute renal failure, attenuated tubular damage in UA-induced ARF in rats, and, if so, whether the attenuation of tubular damage was associated with reduced apoptotic cell death. Methods. Sprague-Dawley rats were allocated to three groups; normal controls, UA-treated, and UA plus glycine-treated. Acute renal failure was induced by the intravenous injection of UA (5 mg/kg). UA plus glycine-treated rats were given glycine at 1 g/kg, i.v. over 3 min at the same time as the UA injection. Serum creatinine concentration (Scr) and tubular damage score were examined 5 days after UA administration. Apoptosis was evaluated by counting the number of terminal deoxynucleotidyl transferase-mediated dUTP-biotin nick end labeling (TUNEL)-positive cells in the outer stripe of the outer medulla. Results. Glycine significantly decreased the UA-induced increases in Scr (3.73 ± 0.31 vs 2.74 ± 0.11 mg/dl; P < 0.05) and the tubular damage score (3.83 ± 0.13 vs 2.58 ± 0.01; P < 0.01). UA significantly increased the number of TUNEL-positive cells in the outer stripe of the outer medulla (0.16 ± 0.04 vs 7.45 ± 0.46/high power field at ×400 magnification; P < 0.01 vs normal control value). Glycine infusion significantly lessened the number of TUNEL-positive cells (5.84 ± 0.31/ high power field at ×400 magnification; P < 0.01 vs UA-treated rats). A significant correlation was found between the number of TUNEL-positive cells and the tubular damage score (r = 0.93; P < 0.01). Conclusion. Glycine ameliorated the severity of UA-induced ARF and the degree of apoptotic cell death. This finding suggested that the protective effect of glycine in UA-induced ARF may be mediated, at least in part, through a reduction of apoptosis.

The roles of apoptosis in uranyl acetate-Induced acute renal failure

(1998). The roles of apoptosis in uranyl acetate-Induced acute renal failure. Renal Failure: Vol. 20, No. 5, pp. 697-701.

Association of HSP73 with the acquired resistance to uranyl acetate-induced acute renal failure

Studies were performed to investigate the relationship between heat shock protein (HSP) and the acquired resistance to uranyl acetate (UA)-induced acute renal failure (ARF). Rats were resistant to a rechallenge with 5 mg/kg of UA between 1 and 2 weeks after the first injection of the same amount of UA. During this period, the renal HSP73 was increased to 148 ± 12% of baseline, and tubular damage as well as an increase in serum creatinine after the second challenge of UA were significantly lower than existing after the first challenge. At 4 weeks after the first injection of UA, the amount of HSP73 returned to the normal level, and serum creatinine at the 5th day after the second challenge was increased to a level equivalent to that after the first injection. A lower dose of UA (2 mg/kg) had a little effect on the renal HSP73 content and induced limited resistance to 5 mg/kg of UA at 2 weeks after the first injection. Whole-body hyperthermia markedly increased the renal HSP72 content, but not that of HSP73, and did not induce resistance to UA. These data suggest that the increase in renal HSP73 might be associated with the acquired resistance to UA in rats, although there is no direct evidence that HSP73 produced by the regenerated cells plays a role in the acquired resistance.

Glomerular alterations in uranyl acetate-induced acute renal failure in rabbits

The study was performed to elucidate the progression and regression of superficial and inner glomerular alterations in uranyl acetate-induced renal failure in rabbits. Fifteen hours after the drug injection, creatinine clearance (CCr) decreased to 55% of controls with slightly elevated plasma creatinine concentration (initiation stage). After 5 days, urine flow and CCr decreased to approximately zero, with severe azotemia (maintenance stage). Scanning electron microscopic observations in these stages revealed a flattening and spreading of podocyte cell bodies associated with loss of epithelial foot processes, and reduction in the density of endothelial fenestrae. These changes were more advanced in the maintenance stage. Glomerular and fenestral diameters did not significantly change in the initiation stage but increased in the maintenance stage. There was no significant difference in these morphologic alterations, however, between the superficial and inner glomeruli. Glomerular alterations reverted to normal within 14 days, with good recovery of glomerular function. The findings show no significant difference in the progression or regression of the glomerular changes between the superficial and deep cortex. These morphologic changes may play a role in the reduction of CCr observed in this model.

Renal hemodynamics in uranyl acetate-induced acute renal failure of rabbits

The role of renal hemodynamic alterations in the curtailment of renal function was studied in rabbits with uranyl acetate-induced acute renal failure. The day following the i.v. injection of uranyl acetate (2 mg/kg of body wt), renal blood flow (RBF) and clearance of creatinine (Ccr) decreased to approximately 60 and 20% of controls, respectively. Intracortical fractional flow distribution, estimated by radioactive microsphere method, did not change. The extraction ratio of para-aminohippurate (EPAH) decreased and the renal extraction of sodium (CNa/Ccr) increased, with minimal structural change in the kidney. Urine output increased to two to three times that of the control. After three days oliguria appeared despite complete recovery of RBF. The zonal flow redistributed toward the deep cortex. CCr and EPAH reached their minimums, concomitantly with tubular necrosis and intratubular casts. After seven days animals could be divided into the oliguric and diuretic groups. CCr and EPAH were higher in the diuretic group, while there was no significant difference in RBF and the flow distribution between groups. Regeneration of damagee tubular cells was found in the diuretic group but not in the oliguric group. The findings suggest the minor roles of RBF and the intracortical flow distribution, and a fundamental role of back leakage of filtrate across damaged tubular epithelium in the maintenance of reduced CCR and urine output during the oliguric stage in rabbits with uranyl acetate-induced renal failure.