Calpastatin overexpression prevents progression of S-1,2-dichlorovinyl-l-cysteine (DCVC)-initiated acute renal injury and renal failure (ARF) in diabetes

Previously we have shown that 90% of streptozotocin (STZ)-induced type-1 diabetic (DB) mice survive from acute renal failure (ARF) and death induced by a normally LD(90) dose (75 mg/kg, i.p.) of the nephrotoxicant S-1,2-dichlorovinyl-l-cysteine (DCVC). This remarkable protection is due to a combination of slower progression of DCVC-initiated renal injury and increased compensatory nephrogenic tissue repair in the DB kidneys. BRDU immunohistochemistry revealed that the DB condition led to 4-fold higher number of proximal tubular cells (PTC) entering S-phase of cell cycle. In the present study, we tested the hypothesis that DB-induced augmentation of PTC into S-phase is accompanied by overexpression of the calpain-inhibitor calpastatin, which endogenously prevents the progression of DCVC-initiated renal injury mediated by the calpain escaping out of damaged PTCs. Immunohistochemical detection of renal calpain and its activity in the urine, over a time course after treatment with the LD(90) dose of DCVC, indicated progressive increase in leakage of calpain into the extracellular spaces of the injured PTCs of the non-diabetic (NDB) kidneys as compared to the DB kidneys. Calpastatin expression was minimally detected in the NDB kidneys, using immunohistochemistry, over the time course. On the other hand, consistently higher number of tubules in the DB kidney showed calpastatin expression over the time course. The lower leakage of calpain in the DB kidneys was commensurate with constitutively higher expression of calpastatin in the S-phase-laden PTCs of these mice. To test the protective role of newly divided/dividing PTCs, DB mice were given the anti-mitotic agent colchicine (CLC) (2 mg/kg and 1.5 mg/kg, i.p., on days 8 and 10 after STZ injection) prior to challenge with a LD(90) dose of DCVC, which led to 100% mortality by 48 h. Mortality was due to rapid progression of DCVC-initiated renal injury, suggesting that newly divided/dividing cells are instrumental in mitigating the progression of DCVC-initiated renal injury in DB. The anti-mitotic effect of CLC in DB kidney is associated with lower expression of calpastatin and higher leakage of calpain in the injured tubules. These findings suggest that constitutively higher cell division in the DB kidney is associated with overexpression of calpastatin, which reduces the progression of DCVC-initiated renal injury mediated by calpain on the one hand and accelerates nephrogenic tissue repair on the other, thereby restoring renal structure and function.     

Colchicine antimitosis causes progression of S-(1,2-dichlorovinyl)-L-cysteine-induced injury leading to acute renal failure and death in mice

Objective of the present study was to test the importance of tissue repair in the final outcome of S-(1,2-dichlorovinyl)-L-cysteine (DCVC)-induced nephrotoxicity using colchicine (CLC) intervention. Male Swiss Webster (SW) mice were administered a normally nonlethal dose of DCVC (30 mg/kg, i.p.) on day 0 and CLC (2 mg/kg, i.p.) at 42 and 66 h after administration of DCVC. The mice were observed for mortality and various renal injury and repair parameters were studied during a time course of 0-14 days. Administration of 30 mg DCVC/kg led to loss of renal architecture by day 1, which sustained until day 5, and regressed thereafter to reach normal architecture by day 10 resulting in 100% survival. Renal dysfunction as assessed by increases in plasma BUN and creatinine levels was concordant during this time course. Urinary volume increased significantly between days 10 and 14 with significant increases in urinary glucose concentrations on days 1-4. Calpain leakage increased from day 1 and remained so until day 5 before declining at later time points. In contrast, CLC intervention led to marked inhibition of S-phase DNA synthesis and 100% mortality by 120 h. H&E sections of kidneys revealed loss of renal architecture on day 1 which progressively worsened from day 2 to 4. Polyuria and glycosuria were evident during the first 2 and 3 days, respectively. Calpain immunohistochemistry revealed progressive leakage of calpain in the extracellular space during 2-4 days which lead to increased renal injury as evident from significant increases in calpain specific breakdown products (CSBPs) of alpha-fodrin during the same period of time. The group of mice receiving 2 mg CLC/kg alone showed a significant increase in urinary creatinine concentration on day 5. Neither the expression nor localization of aquaporin 1 was altered in any of the treatment groups. These results show that antimitotic intervention after DCVC-initiated renal injury leads to expansion and progression of that injury, which appears to be due to proteolytic destruction of neighboring cells mediated by calpain leaking out of necrosed renal tubular epithelial cells.     

Role of tissue repair in survival from s-(1,2-dichlorovinyl)-L-cysteine-induced acute renal tubular necrosis in the mouse.

S-(1,2-Dichlorovinyl)-L-cysteine (DCVC), a model nephrotoxicant in mice, causes acute tubular necrosis and death at high doses. Our earlier studies revealed that renal tissue repair was critical for survival in mice with DCVC nephrotoxicity. The objective of this study was to investigate if increasing renal tissue repair could protect mice from the lethal outcome of DCVC. Male Swiss Webster (SW) mice were administered a low dose of DCVC (15 mg/kg, ip) 72 h before injection of a normally lethal dose of DCVC (75 mg/kg, ip); this resulted in 100% protection against the lethal effect of DCVC. Because DCVC caused approximately two fold decrease in cytosolic and mitochondrial beta-lyase activity, the possibility that DCVC protection may be caused by decreased bioactivation was examined. Mercuric chloride (HgCl2, 6 mg/kg), a nephrotoxicant with no effect on beta-lyase activity, was administered 96 h before a lethal dose of DCVC. This also resulted in 100% protection from the lethal effect of DCVC. In both studies total glutathione was unchanged at any time after the lethal dose of DCVC was administered, obviating the role of glutathione in protection. In both cases the augmented and sustained tissue repair induced by priming dose and documented by 3H-thymidine pulse labeling and immunocytochemistry for proliferating cell nuclear antigen resulted in 100% survival in spite of the extensive renal injury. These findings suggest that stimulation of renal tubular repair by the priming dose, through augmented cell division, and the resistance of new cells to mechanisms of progression of injury, underlies auto- and heteroprotection against DCVC. The molecular mechanisms may have potential application in pharmacotherapeutic intervention for treatment of acute renal failure.     

Renal injury and repair following S-1, 2 dichlorovinyl-L-cysteine administration to mice

S-(1,2-dichlorovinyl)-L-cysteine (DCVC), a metabolite of a common environmental contaminant, trichloroethylene, is a selective proximal tubular nephrotoxicant. The objective of our study was to examine the dose-response relationship of renal injury and repair following DCVC administration. Male Swiss-Webster mice were injected with DCVC [15, 30, or 75 mg/kg ip in distilled water (10 ml/kg)] and the extent of nephrotoxicity and tissue repair was assessed over a 14-day period. The renal injury due to the low and medium doses of DCVC peaked at 36 and 72 h after dosing, respectively, and then regressed over time due to a timely and adequate tissue repair response. At the highest dose tissue repair was inhibited, thereby causing progression of renal injury, which led to acute renal failure and death of the mice. The possibility that compromised tissue repair was a result of the extensive nephrotoxic injury attendant to the high dose of DCVC was investigated via an equinephrotoxicity study in which separate groups of mice received 40 (LD40) and 75 (LD90) mg DCVC/kg, respectively. Bioactivation-based renal proximal tubular injury measured in these two groups over a time course was identical but there was a marked difference in mortality due to an early and robust tissue repair in the first group relative to the second group. These results support the concept that quantitative evaluation of renal tissue repair in parallel with injury is useful in the assessment of the likely toxic outcome associated with exposure to nephrotoxic drugs and toxicants.     

Streptozotocin-induced diabetic mice are resistant to lethal effects of thioacetamide hepatotoxicity

The effect of Type 1 diabetes on the toxicity of thioacetamide was investigated in a murine model. In streptozotocin-induced diabetic C57BL6 mice a LD90 dose of thioacetamide (1000 mg/kg, ip in saline) caused only 10% mortality. Alanine aminotransferase activity revealed approximately 2.7-fold less liver injury in the diabetic (DB) mice compared to the non-DB controls, at 36 h after thioacetamide (TA) administration, which was confirmed via histopathological analysis. HPLC analyses revealed lower plasma t(1/2) of TA in the DB mice. Covalent binding of [(14)C]TA to liver tissue was lower in the DB mice, suggesting lower bioactivation of TA. Compensatory hepatic S-phase stimulation as assessed by [(3)H]thymidine incorporation occurred much earlier and was substantially higher in the DB mice compared to the non-DB cohorts. Morphometric analysis of cells in various phases of cell division assessed via immunohistochemical staining for proliferating cell nuclear antigen revealed more cells in G(1), S, G(2), and M phases in the DB mice, indicating robust tissue repair in concordance with the findings of [(3)H]thymidine pulse labeling studies. The importance of tissue repair in the resistance of DB mice was further investigated by blocking cell division in the DB mice by colchicine (1 mg/kg, ip) at 40 h after TA administration, well after the bioactivation of TA. Antimitotic action of colchicine, confirmed by decreased S-phase stimulation, led to progression of liver injury and increased mortality in DB mice. These findings suggest that lower bioactivation of TA and early onset of liver tissue repair are the pivotal underpinnings for the resistance of DB mice.     

Mechanisms of inhibited liver tissue repair in toxicant challenged type 2 diabetic rats

Liver injury initiated by non-lethal doses of CCl(4) and thioacetamide (TA) progresses to hepatic failure and death of type 2 diabetic (DB) rats due to failed advance of liver cells from G(0)/G(1) to S-phase and inhibited tissue repair. Objective of the present study was to investigate cellular signaling mechanisms of failed cell division in DB rats upon hepatotoxicant challenge. In CCl(4)-treated non-diabetic (non-DB) rats, increased IL-6 levels, sustained activation of extracellular regulated kinases 1/2 (ERK1/2) MAPK, and sustained phosphorylation of retinoblastoma protein (p-pRB) via cyclin D1/cyclin-dependent kinase (cdk) 4 and cyclin D1/cdk6 complexes stimulated G(0)/G(1) to S-phase transition of liver cells. In contrast to the non-DB rats, CCl(4) administration led to lower plasma IL-6, decreased ERK1/2 activation, lower cyclin D1, and cdk 4/6 expression resulting in decreased p-pRB and inhibition of liver cell division in the DB rats. Furthermore, higher TGFbeta1 expression and p21 activation may also contribute to decreased p-pRB in DB rats compared to non-DB rats. Similarly, after TA administration to DB rats, down-regulation of cyclin D1 and p-pRB leads to markedly decreased advance of liver cells from G(0)/G(1) to S-phase and tissue repair compared to the non-DB rats. Hepatic ATP levels did not differ between the DB and non-DB rats obviating its role in failed tissue repair in the DB rats. In conclusion, decreased p-pRB may contribute to blocked advance of cells from G(0)/G(1) to S-phase and failed cell division in DB rats exposed to CCl(4) or TA, leading to progression of liver injury and hepatic failure.     

Disrupted G1 to S phase clearance via cyclin signaling impairs liver tissue repair in thioacetamide-treated type 1 diabetic rats

Previously we reported that a nonlethal dose of thioacetamide (TA, 300 mg/kg) causes 90% mortality in type 1 diabetic (DB) rats because of irreversible acute liver injury owing to inhibited hepatic tissue repair, primarily due to blockage of G(0) to S phase progression of cell division cycle. On the other hand, DB rats receiving 30 mg TA/kg exhibited equal initial liver injury and delayed tissue repair compared to nondiabetic (NDB) rats receiving 300 mg TA/kg, resulting in a delay in recovery from liver injury and survival. The objective of the present study was to test the hypothesis that impaired cyclin-regulated progression of G(1) to S phase of the cell cycle may explain inhibited liver tissue repair, hepatic failure, and death, contrasted with delayed liver tissue repair but survival observed in the DB rats receiving 300 in contrast to 30 mg TA/kg. In the TA-treated NDB rats sustained MAPKs and cyclin expression resulted in higher phosphorylation of retinoblastoma (pRb), explaining prompt tissue repair and survival. In contrast, DB rats receiving the same dose of TA (300 mg/kg) exhibited suppressed MAPKs and cyclin expression that led to inhibition of pRb, inhibited tissue repair, and death. On the other hand, DB rats receiving 30 mg TA/kg exhibited delayed up regulation of MAPK signaling that delayed the expression of CD1 and pRb, explaining delayed stimulation of tissue repair observed in this group. In conclusion, the hepatotoxicant TA has a dose-dependent adverse effect on cyclin-regulated pRb signaling: the lower dose causes a recoverable delay, whereas the higher dose inhibits it with corresponding effect on the ultimate outcomes on hepatic tissue repair; this dose-dependent adverse effect is substantially shifted to the left of the dose response curve in diabetes.     

Type 2 diabetic rats are sensitive to thioacetamide hepatotoxicity

Previously, we reported high hepatotoxic sensitivity of type 2 diabetic (DB) rats to three dissimilar hepatotoxicants. Additional work revealed that a normally nonlethal dose of CCl4 was lethal in DB rats due to inhibited compensatory tissue repair. The present study was conducted to investigate the importance of compensatory tissue repair in determining the final outcome of hepatotoxicity in diabetes, using another structurally and mechanistically dissimilar hepatotoxicant, thioacetamide (TA), to initiate liver injury. A normally nonlethal dose of TA (300 mg/kg, ip), caused 100% mortality in DB rats. Time course studies (0 to 96 h) showed that in the non-DB rats, liver injury initiated by TA as assessed by plasma alanine or aspartate aminotransferase and hepatic necrosis progressed up to 48 h and regressed to normal at 96 h resulting in 100% survival. In the DB rats, liver injury rapidly progressed resulting in progressively deteriorating liver due to rapidly expanding injury, hepatic failure, and 100% mortality between 24 and 48 h post-TA treatment. Covalent binding of 14C-TA-derived radiolabel to liver tissue did not differ from that observed in the non-DB rats, indicating similar bioactivation-based initiation of hepatotoxicity. S-phase DNA synthesis measured by [3H]-thymidine incorporation, and advancement of cells through the cell division cycle measured by PCNA immunohistochemistry, were substantially inhibited in the DB rats compared to the non-DB rats challenged with TA. Thus, inhibited cell division and compromised tissue repair in the DB rats resulted in progressive expansion of liver injury culminating in mortality. In conclusion, it appears that similar to type 1 diabetes, type 2 diabetes also increases sensitivity to dissimilar hepatotoxicants due to inhibited compensatory tissue repair, suggesting that sensitivity to hepatotoxicity in diabetes occurs in the absence as well as presence of insulin.     

Peroxidative damage and nephrotoxicity of dichlorovinylcysteine in mice

Male NMRI mice were treated i.p. with dichlorovinylcysteine (DCVC) in a dosage of 2.5-500 mg/kg-1 and renal cortical slices from naive mice were incubated with 0-125 micrograms/ml-1 DCVC. The effects of DCVC on blood urea nitrogen (BUN), reduced glutathione (GSH) content, malondialdehyde (MDA) production, p-aminohippuric acid (PAH)- and tetraethylammonium (TEA)-accumulation and glucose synthesis (gluconeogenesis) were measured. DCVC depleted GSH in a time- and dose-dependent manner. Depletion of renal cortical GSH by DCVC was more pronounced in the kidney cortex than in the liver. DCVC caused a dose-dependent increase of ethane exhalation and of MDA production in the renal cortex. When animals were kept in a closed system, decrease in oxygen concentration increased the peroxidative damage. No increase of MDA concentration was observed in the liver. Treatment of mice with DCVC induced a dose-dependent increase in BUN and decreased the accumulation of PAH and TEA in renal cortical slices. Pretreatment of mice with aminooxyacetic acid (AOAA) and (+) cyanidanol-3 (CY) caused a significant reduction in DCVC-induced lipid peroxidation and nephrotoxicity. In vitro incubation of renal cortical slices of naive mice with DCVC resulted in a concentration-dependent increase in MDA and a concentration-dependent decrease in the accumulations of PAH, TEA and of gluconeogenesis. In conclusion, the interaction of DCVC and/or its metabolites with membrane lipids may be responsible for lipid peroxidation and nephrotoxicity. The formation of lipid peroxidation products was greater under hypoxic conditions and appeared to be related to the DCVC-induced nephrotoxicity. This data suggests lipid peroxidation as a possible mechanism of DCVC-induced nephrotoxicity.     

Type 1 diabetic mice are protected from acetaminophen hepatotoxicity.

Streptozotocin (STZ)-induced diabetic (DB) mice challenged with single ordinarily lethal doses of acetaminophen (APAP), carbon tetrachloride (CCl4), or bromobenzene (BB) were resistant to all three hepatotoxicants. Mechanisms of protection against APAP hepatotoxicity were investigated. Plasma alanine aminotransferase, aspartate aminotransferase, and liver histopathology revealed significantly lower hepatic injury in DB mice after APAP administration. HPLC analysis of plasma and urine revealed lower plasma t1/2, increased volume of distribution (Vd), and increased plasma clearance (CLp) of APAP in the DB mice and no difference in APAP-glucuronide, a major metabolite in mice. Interestingly, covalent binding of 14C-labeled APAP to liver target proteins; arylation of APAP to 58, 56, and 44 kDa acetaminophen binding proteins (ABPs); and glutathione (GSH) depletion in the liver did not differ between nondiabetic (non-DB) and DB mice in spite of downregulated hepatic microsomal CYP2E1 and 1A2 proteins in the DB mice, known to be involved in bioactivation of APAP. Compensatory cell division measured via 3H-thymidine pulse labeling and immunohistochemical staining for proliferating cell nuclear antigen (PCNA) indicated earlier onset of S-phase in the DB mice after exposure to APAP. Antimitotic intervention of liver cell division by colchicine (CLC) after administration of APAP led to significantly higher mortality in the DB mice suggesting a pivotal role of liver cell division and tissue repair in the protection afforded by diabetes. In conclusion, the resistance of DB mice against hepatotoxic and lethal effects of APAP appears to be mediated by a combination of enhanced APAP clearance and robust compensatory tissue repair.     

Attenuation of renal ischemia-reperfusion injury by trimetazidine: evidence of an in vivo antioxidant effect

Renal ischemia-reperfusion injury constitutes the most common pathogenic factor for acute renal failure and is the main contributor to renal dysfunction in allograft recipients and revascularization surgeries. Many studies have demonstrated that reactive oxygen species play an important role in ischemic acute renal failure. The aim of the present study was to investigate the effects of the synthetic antiischemic agent trimetazidine in a rat model of renal ischemia-reperfusion injury. Renal ischemia-reperfusion was induced by clamping the unilateral renal artery for 45 min followed by 24 h of reperfusion. Trimetazidine (2.5 mg/kg i.p.) was administered 24 and 12 h prior to renal artery occlusion and the same dose was given intravenously 1 h before inducing ischemia. Tissue lipid peroxidation was measured as thiobarbituric acid reacting substances (TBARS) in kidney homogenates. Renal function was assessed by estimating serum creatinine, blood urea nitrogen (BUN), creatinine and urea clearance. Renal morphological alterations were assessed by histopathological examination of hematoxylin-eosin stained sections of the kidneys. Ischemia-reperfusion produced elevated levels of TBARS and deteriorated the renal function as assessed by increased serum creatinine, BUN and decreased creatinine and urea clearance compared with sham operated rats. The ischemic kidneys of rats showed severe hyaline casts, epithelial swelling, proteinaceous debris, tubular necrosis, medullary congestion and hemorrhage. Trimetazidine markedly reduced elevated levels of TBARS and significantly attenuated renal dysfunction and morphological changes in rats subjected to renal ischemia-reperfusion. These results clearly demonstrate the in vivo antioxidant effect and the therapeutic potential of trimetazidine, an anti-ischemic agent, in attenuating renal ischemia-reperfusion injury.     

Wistar大鼠肾脏急性缺血再灌注损伤动物模型的建立

目的 观察应用大鼠制备急性缺血-再灌注肾损伤模型的效果.方法 应用右肾切除并微型动脉夹夹闭大鼠左侧肾动脉制备急性缺血-再灌注肾损伤模型,其中大鼠分别于术后24 h和48 h后处死,观察肾功能及肾脏病理变化,另一部分大鼠观察其病情及存活情况至14d.结果 各次造模成功率均达85％以上;术后24 h及48 h实验组血清肌酐(SCr)和血尿素氮(BUN)水平明显升高,与对照组比较差异有统计学意义(P＜0.01);实验组肾脏外观出现典型“大白肾”表现,镜下出现典型急性肾小管坏死表现,并有较多炎性细胞浸润,肾小管组织学评分与对照组比较差异有统计学意义(P＜0.01);实验组在观察期间逐渐出现典型急性肾功能衰竭表现,至14d末,死亡率达91.7％,而对照组全部正常存活.结论 应用右肾切除并微型动脉夹夹闭大鼠左侧肾动脉可制备稳定急性缺血-再灌注肾损伤模型,而且成功率较高,方法简单.     

Reversal of iron-induced nephrotoxicity in rats by molsidomine, a nitric oxide donor.

Fe-NTA is a very potent nephrotoxic agent and causes oxidative renal injury as shown in various studies. Reactive oxygen species as well as nitric oxide (NO) play an important role in acute renal failure (ARF). Present study was designed to investigate the effect of NO donor, molsidomine (Mol) and inducible NO synthase inhibitor (iNOS), aminoguanidine (AG) in Fe-NTA-induced renal toxicity. Rats were pretreated with Mol (5, 7.5 and 10 mg/kg, p.o.), and AG (100 mg/kg, i.p.) before Fe-NTA challenge (8 mg iron/kg body weight, i.p.) to determine the urea and creatinine levels along with biochemical analysis of oxidative stress. Fe-NTA administration markedly increased the BUN and serum creatinine level which was coupled with a marked lipid peroxidation, reduced activity of glutathione and decreased total nitric oxide levels of rat kidneys coupled with significant morphological alterations. Fe-NTA also markedly increased the levels of tumor necrosis factor-alpha (TNF-alpha) in serum. Concomitant treatment with molsidomine significantly reduced the serum creatinine and BUN levels, decreased lipid peroxidation in a significant manner, restored the levels of reduced glutathione, increased total nitric oxide levels and restored the normal morphology. Molsidomine treatment also attenuated the serum levels of TNF-alpha. Prior administration of AG did not reverse the protective effects produced by molsidomine. Present findings strongly suggest that protection afforded by molsidomine may be due to its direct NO donor ability but not through nitric oxide synthase activity as pretreatment with aminoguanidine did not abolish the protective effects of molsidomine.     

Bone marrow and renal injury associated with haloalkene cysteine conjugates in calves

 Almost 40 years ago, it was reported that cattle-feed which had been extracted with hot trichloroethylene and then fed to calves produced renal injury and a fatal aplastic anaemia. The toxic factor was subsequently identified as S-(1,2-dichlorovinyl)-L-cysteine (DCVC). These original findings have been confirmed, a single intravenous dose of DCVC at 4 mg/kg, or 0.4 mg/kg intravenously per day administered for 10 days to calves produced aplastic anaemia, and renal injury after a single dose of 4 mg/kg. The toxicity to calves of a number of other haloalkene cysteine conjugates has been examined to ascertain whether, like DCVC, they produce bone marrow and renal injury. Intravenous administration of the N-acetyl cysteine conjugate of DCVC produced renal but not bone marrow injury at a molar equivalent dose to DCVC, indicating that the calf can deacetylate the mercapturic acid and further that sufficient chemical had reached the kidney to be a substrate for the enzyme cysteine conjugate β-lyase. However, intravenous administration of the α-methyl analogue of DCVC, which cannot undergo metabolism via the enzyme cysteine conjugate β-lyase, was without toxicity at doses about five-fold higher than DCVC. These latter findings provide strong evidence that metabolism of DCVC via the enzyme β-lyase is necessary for bone marrow and renal injury to occur. The cysteine conjugates of perchloro ethylene and hexachloro-1,3-butadiene(HCBD) when given intravenously to calves at molar equivalent doses to DCVC, or above, did not produce either bone marrow or renal injury. In contrast, intravenous administration of the cysteine conjugate of tetrafluoroethylene (TFEC) produced severe renal tubular injury in calves without affecting the bone marrow. In vitro studies with these haloalkene cysteine conjugates showed, like DCVC, that they were good substrates for calf renal cysteine conjugate β-lyase and toxic to renal cells as judged by their ability to reduce organic anion and cation transport by slices of calf renal cortex and inhibit the renal enzyme glutathione reductase. Calves were also dosed either orally or intravenously with HCBD to assess its toxicity. HCBD at higher molar equivalent doses than DCVC produced mid-zonal necrosis in the liver, renal tubular necrosis but no bone marrow injury in calves. The key findings emerging from these studies are (1) that none of the other cysteine conjugates, at molar equivalent doses to DCVC and above, produce bone marrow injury in calves, (2) TFEC produced only renal injury, suggesting that sufficient of the other conjugates had not reached the kidney for metabolism by β-lyase to produce cytotoxicity and (3) that HCBD itself is more toxic than its cysteine or mercapturic acid conjugate, suggesting that pharmacokinetics and disposition are important factors in determining the toxicity of these conjugates to calves. Further studies are needed to understand the basis for the selective toxicity of DCVC to the bone marrow of calves. Received: 16 October 1995/Accepted: 9 January 1996     

百草枯中毒早期大鼠肾组织中不规则趋化因子的表达

目的通过观察不规则趋化因子(Fractalkine,FKN,又称CX3CLl)在百草枯(Paraquat,PQ)中毒早期肾组织中的表达,探讨FKN在PQ致大鼠急性肾损伤中的作用。方法 SD大鼠80只,按随机数字法分为染毒组(40只)和对照组(40只)。染毒组腹腔注入PQ(22 mg/kg),对照组给予等量生理盐水。每组分别在染毒后0.5、1、3、5 d处死大鼠。测定血清肌酐及尿素氮,HE染色观察肾组织病理改变,免疫组化法检测FKN的表达。结果 PQ染毒后大鼠出现肾功能损害,血肌酐及尿素氮同步升高,且随染毒时间延长,肾功能损害逐渐加重,与同时间对照组相比,差异有统计学意义(P<0.05)。镜下观察,染毒组大鼠肾组织病理改变为肾小球体积增大,肾小管上皮细胞肿胀及管腔变窄;此后随观察时间延长,可见水肿渗出、坏死,间质炎性细胞浸润增加,肾小管内蛋白管型。免疫组化发现:染毒组在染毒后0.5、1、3、5 d,FKN表达呈逐渐增高趋势(P<0.05),且明显高于对照组,差异具有统计学意义(P<0.01)。结论 FKN在PQ早期大鼠肾组织中可表达,并与急性肾损伤的发病过程紧密相关。     

MRP-1 expression levels determine strain-specific susceptibility to sodium arsenic-induced renal injury between C57BL/6 and BALB/c mice

To clarify the pathophysiological mechanism underlying acute renal injury caused by acute exposure to arsenic, we subcutaneously injected both BALB/c and C57BL/6 mice with sodium arsenite (NaAs; 13.5 mg/kg). BALB/c mice exhibited exaggerated elevation of serum blood urea nitrogen (BUN) and creatinine (CRE) levels, compared with C57BL/6 mice. Moreover, half of BALB/c mice died by 24 h, whereas all C57BL/6 mice survived. Histopathological examination on kidney revealed severe hemorrhages, acute tubular necrosis, neutrophil infiltration, cast formation, and disappearance of PAS-positive brush borders in BALB/c mice, later than 10 h. These pathological changes were remarkably attenuated in C57BL/6 mice, accompanied with lower intrarenal arsenic concentrations, compared with BALB/c mice. Among heavy metal inducible proteins including multidrug resistance-associated protein (MRP)-1, multidrug resistance gene (MDR)-1, metallothionein (MT)-1, and arsenite inducible, cysteine- and histidine-rich RNA-associated protein (AIRAP), intrarenal MDR-1, MT-1, and AIRAP gene expression was enhanced to a similar extent in both strains, whereas NaAs challenge augmented intrarenal MRP-1 mRNA and protein expression levels in C57BL/6 but not BALB/c mice. Moreover, the administration of a specific inhibitor of MRP-1, MK-571, significantly exaggerated acute renal injury in C57BL/6 mice. Thus, MRP-1 is crucially involved in arsenic efflux and eventually prevention of acute renal injury upon acute exposure to NaAs.     

Interactive toxicity of inorganic mercury and trichloroethylene in rat and human proximal tubules: effects on apoptosis, necrosis, and glutathione status

Simultaneous or prior exposure to one chemical may alter the concurrent or subsequent response to another chemical, often in unexpected ways. This is particularly true when the two chemicals share common mechanisms of action. The present study uses the paradigm of prior exposure to study the interactive toxicity between inorganic mercury (Hg(2+)) and trichloroethylene (TRI) or its metabolite S-(1,2-dichlorovinyl)-l-cysteine (DCVC) in rat and human proximal tubule. Pretreatment of rats with a subtoxic dose of Hg(2+) increased expression of glutathione S-transferase-alpha1 (GSTalpha1) but decreased expression of GSTalpha2, increased activities of several GSH-dependent enzymes, and increased GSH conjugation of TRI. Primary cultures of rat proximal tubular (rPT) cells exhibited both necrosis and apoptosis after incubation with Hg(2+). Pretreatment of human proximal tubular (hPT) cells with Hg(2+) caused little or no changes in GST expression or activities of GSH-dependent enzymes, decreased apoptosis induced by TRI or DCVC, but increased necrosis induced by DCVC. In contrast, pretreatment of hPT cells with TRI or DCVC protected from Hg(2+) by decreasing necrosis and increasing apoptosis. Thus, whereas pretreatment of hPT cells with Hg(2+) exacerbated cellular injury due to TRI or DCVC by shifting the response from apoptosis to necrosis, pretreatment of hPT cells with either TRI or DCVC protected from Hg(2+)-induced cytotoxicity by shifting the response from necrosis to apoptosis. These results demonstrate that by altering processes related to GSH status, susceptibilities of rPT and hPT cells to acute injury from Hg(2+), TRI, or DCVC are markedly altered by prior exposures.     

Metabolism and toxicity of trichloroethylene and S-(1,2-dichlorovinyl)-L-cysteine in freshly isolated human proximal tubular cells.

Trichloroethylene (Tri) caused modest cytotoxicity in freshly isolated human proximal tubular (hPT) cells, as assessed by significant decreases in lactate dehydrogenase (LDH) activity after 1 h of exposure to 500 microM Tri. Oxidative metabolism of Tri by cytochrome P-450 to form chloral hydrate (CH) was only detectable in kidney microsomes from one patient out of four tested and was not detected in hPT cells. In contrast, GSH conjugation of Tri was detected in cells from every patient tested. The kinetics of Tri metabolism to its GSH conjugate S-(1,2-dichlorovinyl)glutathione (DCVG) followed biphasic kinetics, with apparent Km and Vmax values of 0.51 and 24.9 mM and 0.10 and 1.0 nmol/min per mg protein, respectively. S-(1,2-dichlorovinyl)-L-cysteine (DCVC), the cysteine conjugate metabolite of Tri that is considered the penultimate nephrotoxic species, caused both time- and concentration-dependent increases in LDH release in freshly isolated hPT cells. Preincubation of hPT cells with 0.1 mM aminooxyacetic acid did not protect hPT cells from DCVC-induced cellular injury, suggesting that another enzyme besides the cysteine conjugate beta-lyase may be important in DCVC bioactivation. This study is the first to measure the cytotoxicity and metabolism of Tri and DCVC in freshly isolated cells from the human kidney. These data indicate that the pathway involved in the cytotoxicity and metabolism of Tri in hPT cells is the GSH conjugation pathway and that the cytochrome P-450-dependent pathway has little direct role in renal Tri metabolism in humans.     

Protective effect of edaravone against renal ischemia/reperfusion injury and compared with ischemic postconditioning in rats

The aim of this study is to clarify whether edaravone postconditioning had protective effect against renal ischemia/reperfusion injury and to compare the protective effect between ischemic postconditioning and edaravone postconditioning. Rats were subjected to 45 min ischemia followed by 24 h reperfusion. The rats were randomly assigned to seven groups: a sham-operated control group, an ischemia/reperfusion group, an ischemic postconditioning group, a normal saline vehicle postconditioning group and an edaravone postconditioning (1, 3, and 6 mg x kg(-1)) group. Renal function was assessed by serum creatinine and BUN concentration, while histological damage of renal tissue was assessed with HE staining. MDA content and SOD activity of renal tissue were determined. TUNEL staining was performed to analyze the apoptosis of the tubular epithelial cells, the protein level of Bcl-2 and Bax in renal tissue was examined by Western blotting. Compared to the ischemia/reperfusion group, edaravone postconditioning significantly decreased serum creatinine and BUN concentration, and ameliorated histological damage of renal tissue. MDA was less after 24 h reperfusion in the edaravone postconditioning group than that in the ischemia/reperfusion group, consistent with an increase in SOD activity. In addition, edaravone postconditioning decreased TUNEL-positive cells and Bax expression, and increased Bcl-2 expression. Results detected in the edaravone postconditioning group showed no significant difference from the ischemic postconditioning group. Edaravone administered during the last 3 min of ischemia, prior to reperfusion induces a pharmacological postconditioning in vivo against renal ischemia/reperfusion injury in rats. This protection is similar to that observed with ischemic postconditioning.     

埃他卡林对脂多糖、油酸、二甘醇等所致肾脏损伤的影响

目的观察埃他卡林对脂多糖、油酸和二甘醇等不同因素所致肾脏损伤的影响。方法采用大鼠股静脉注射2%醋酸铅致敏后注射脂多糖1μg（1ml/kg）,4h造成内毒素休克肾损伤模型,大鼠左肾动脉注射油酸0.15ml/kg,24h造成油酸所致肾损伤模型,分别在造模前3d及1h,以埃他卡林1,3,9mg/（kg.d）灌胃给药;小鼠腹腔注射二甘醇10g/kg后,立即以埃他卡林1,3,9mg/（kg.d）灌胃给药6d,第7天造模成功。3种模型建立后,观察血清肌酐、尿素氮水平和肾脏形态学变化,评价肾脏功能。结果（1）内毒素性休克大鼠血清肌酐和尿素氮水平显著升高,组织病理显示有肾小球微血栓、肾小管上皮肿胀和管腔内蛋白管型形成。埃他卡林9mg/kg组能明显降低血清尿素氮和肌酐水平,改善上述病理变化。（2）左肾动脉注射油酸大鼠血清肌酐和尿素氮水平显著升高,组织病理显示肾小球内皮细胞坏死,球囊腔减小,肾小管间质充血且管腔内有蛋白管型形成。埃他卡林对油酸所致大鼠肾脏损伤无显著性改善作用。（3）二甘醇肾损伤小鼠血清肌酐水平显著性升高,埃他卡林9mg/kg组血清肌酐水平恢复至正常。结论埃他卡林不适合于脂多糖、油酸所致肾脏损伤的防治,埃他卡林可否用于二甘醇所致肾损伤的治疗值得进一步研究。