Your search keyword '"Hyperoxaluria metabolism"' showing total 11 results

1. N-acetylcysteine regulates oxalate induced injury of renal tubular epithelial cells through CDKN2B/TGF-β/SMAD axis.

Author

Cao W, Zhang J, Yu S, Gan X, and An R

Subjects

Animals, Male, Rats, Acetylcysteine pharmacology, Calcium Oxalate metabolism, Epithelial Cells metabolism, Rats, Sprague-Dawley, Superoxide Dismutase metabolism, Transforming Growth Factor beta1 metabolism, Hyperoxaluria chemically induced, Hyperoxaluria metabolism, Oxalates metabolism

Abstract

This study was aimed to investigate the preventive effects of N-acetyl-L-cysteine (NAC) against renal tubular cell injury induced by oxalate and stone formation and further explore the related mechanism. Transcriptome sequencing combined with bioinformatics analysis were performed to identify differentially expressed gene (DEG) and related pathways. HK-2 cells were pretreated with or without antioxidant NAC/with or silencing DEG before exposed to sodium oxalate. Then, the cell viability, oxidative biomarkers of superoxidase dismutase (SOD) and malondialdehyde (MDA), apoptosis and cell cycle were measured through CCK8, ELISA and flow cytometry assay, respectively. Male SD rats were separated into control group, hyperoxaluria (HOx) group, NAC intervention group, and TGF-β/SMAD pathway inhibitor group. After treatment, the structure changes and oxidative stress and CaOx crystals deposition were evaluated in renal tissues by H&E staining, immunohistochemical and Pizzolato method. The expression of TGF-β/SMAD pathway related proteins (TGF-β1, SMAD3 and SMAD7) were determined by Western blot in vivo and in vitro. CDKN2B is a DEG screened by transcriptome sequencing combined with bioinformatics analysis, and verified by qRT-PCR. Sodium oxalate induced declined HK-2 cell viability, in parallel with inhibited cellular oxidative stress and apoptosis. The changes induced by oxalate in HK-2 cells were significantly reversed by NAC treatment or the silencing of CDKN2B. The cell structure damage and CaOx crystals deposition were observed in kidney tissues of HOx group. Meanwhile, the expression levels of SOD and 8-OHdG were detected in kidney tissues of HOx group. The changes induced by oxalate in kidney tissues were significantly reversed by NAC treatment. Besides, expression of SMAD7 was significantly down-regulated, while TGF-β1 and SMAD3 were accumulated induced by oxalate in vitro and in vivo. The expression levels of TGF-β/SMAD pathway related proteins induced by oxalate were reversed by NAC. In conclusion, we found that NAC could play an anti-calculus role by mediating CDKN2B/TGF-β/SMAD axis., (© 2024. The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.)

Published

2024

2. Nox1-derived oxidative stress as a common pathogenic link between obesity and hyperoxaluria-related kidney injury.

Author

Sáenz-Medina J, Muñoz M, Sanchez A, Rodriguez C, Jorge E, Corbacho C, Izquierdo D, Santos M, Donoso E, Virumbrales E, Sanchez A, Ramil E, Coronado MJ, Prieto D, and Carballido J

Subjects

Animals, Disease Models, Animal, Male, Rats, Rats, Wistar, Hyperoxaluria complications, Hyperoxaluria metabolism, Kidney Diseases etiology, NADPH Oxidase 1 metabolism, Obesity complications, Obesity metabolism, Oxidative Stress physiology

Abstract

Specific relationships among reactive oxygen species, activation pathways, and inflammatory mechanisms involved in kidney injury were assessed in a combined model of obesity and hyperoxaluria. Male Wistar rats were divided into four groups: Control, HFD (high fat diet), OX (0.75% ethylene glycol), and HFD + OX (combined model) Changes in basal O 2 - levels were evaluated by chemiluminescence in renal interlobar arteries and renal cortex. Furthermore, the effect of different inhibitors on NADPH-stimulated O 2 - generation was assessed in renal cortex. Oxidative stress sources, and local inflammatory mediators, were also determined, in parallel, by RT-PCR, and correlated with measures of renal function, urinary biochemistry, and renal structure. Rats from the HFD group developed overweight without lipid profile alteration. Tubular deposits of crystals were seen in OX and severely enhanced in HFD + OX groups along with a significantly higher impairment of renal function. Basal oxidative stress was increased in renal cortex of OX rats and in renal arteries of HFD rats, while animals from the combined HFD + OX group exhibited the highest levels of oxidative stress in renal cortex, derived from xanthine oxidase and COX-2. NADPH oxidase-dependent O 2 - generation was elevated in renal cortex of the OX group and markedly enhanced in the HFD + OX rats, and associated to an up-regulation of Nox1 and a down-regulation of Nox4 expression. High levels of oxidative stress in the kidney, of OX and HFD + OX groups were also associated to an inflammatory response mediated by an elevation of TNFα, COX-2, NFκB1 MCP-1, and OPN. Oxidative stress is a key pathogenic factor in renal disease associated to hyperoxaluria and a common link underlying the exacerbated inflammatory response and kidney injury found under conditions of both obesity and hyperoxaluria. Nox1 pathway must be considered as a potential therapeutic target.

Published

2020

3. Calcium oxalate crystal deposition in the kidney: identification, causes and consequences.

Author

Geraghty R, Wood K, and Sayer JA

Subjects

Humans, Hyperoxaluria complications, Hyperoxaluria diagnosis, Hyperoxaluria etiology, Calcium Oxalate metabolism, Hyperoxaluria metabolism, Kidney metabolism

Abstract

Calcium oxalate (CaOx) crystal deposition within the tubules is often a perplexing finding on renal biopsy of both native and transplanted kidneys. Understanding the underlying causes may help diagnosis and future management. The most frequent cause of CaOx crystal deposition within the kidney is hyperoxaluria. When this is seen in native kidney biopsy, primary hyperoxaluria must be considered and investigated further with biochemical and genetic tests. Secondary hyperoxaluria, for example due to enteric hyperoxaluria following bariatric surgery, ingested ethylene glycol or vitamin C overdose may also cause CaOx deposition in native kidneys. CaOx deposition is a frequent finding in renal transplant biopsy, often as a consequence of acute tubular necrosis and is associated with poorer long-term graft outcomes. CaOx crystal deposition in the renal transplant may also be secondary to any of the causes associated with this phenotype in the native kidney. The pathophysiology underlying CaOx deposition is complex but this histological phenotype may indicate serious underlying pathology and should always warrant further investigation.

Published

2020

4. Different effects of γ-linolenic acid (GLA) supplementation on plasma and red blood cell phospholipid fatty acid composition and calcium oxalate kidney stone risk factors in healthy subjects from two race groups with different risk profiles pose questions about the GLA-arachidonic acid-oxaluria metabolic pathway: pilot study.

Author

Rodgers AL, Jappie-Mahomed D, and van Jaarsveld PJ

Subjects

Adult, Arachidonic Acid biosynthesis, Arachidonic Acid blood, Biomarkers blood, Biomarkers urine, Dietary Supplements, Erythrocytes metabolism, Fatty Acids blood, Fatty Acids metabolism, Healthy Volunteers, Humans, Hyperoxaluria blood, Hyperoxaluria ethnology, Hyperoxaluria urine, Linoleic Acids blood, Linoleic Acids metabolism, Male, Nephrolithiasis blood, Nephrolithiasis ethnology, Nephrolithiasis urine, Phospholipids metabolism, Pilot Projects, Risk Factors, Young Adult, gamma-Linolenic Acid blood, gamma-Linolenic Acid metabolism, gamma-Linolenic Acid pharmacology, Hyperoxaluria metabolism, Metabolic Networks and Pathways drug effects, Nephrolithiasis metabolism, Phospholipids blood, gamma-Linolenic Acid therapeutic use

Abstract

Fatty acid (FA) composition of phospholipids in plasma and red blood cells (RBC) can influence calciuria, oxaluria and renal stone formation. In this regard, the ratio of arachidonic acid (AA) and its precursor linoleic acid (LA) appears to be important. Administration of γ-linolenic acid (GLA) has been shown to increase the concentration of dihomo-gamma linoleic acid (DGLA) relative to AA indicating that it may attenuate biosynthesis of the latter. Such effects have not been investigated in race groups having difference stone occurrence rates. Black (B) and white (W) healthy males ingested capsules containing linoleic acid (LA) and GLA, for 30 days. Plasma and RBC total phospholipid (TPL) FA profiles, serum and 24 h urine biomarkers of hypercalciuria and urinary stone risk factors were determined on days 0 and 30. Data were tested for statistical significance using GraphPadInstat version 3.02. Concentration and percentage content of DGLA in plasma TPL increased in W but not in B. Arachidonic acid (AA) did not change in either group. There was no change in calcium excretion in either group but oxalate and citrate excretion increased in W. We suggest that elongation of GLA to DGLA may occur more rapidly than desaturation of DGLA to AA in W and that depressed activity of the enzyme elongase may occur in B. Calciuric and citraturic effects may be dependent on the quantity of LA or on the mass ratio of LA/GLA in the FA supplement. Questions about the mooted DGLA-AA-oxaluria pathway arise. We speculate that there exists a potential for using GLA as a conservative treatment for hypocitraturia. The observation of different responses in B and W indicates that such differences may play a role in stone formation and prevention.

Published

2018

5. Metabolic syndrome contributes to renal injury mediated by hyperoxaluria in a murine model of nephrolithiasis.

Author

Sáenz-Medina J, Jorge E, Corbacho C, Santos M, Sánchez A, Soblechero P, Virumbrales E, Ramil E, Coronado MJ, Castillón I, Prieto D, and Carballido J

Subjects

Animals, Calcium Oxalate urine, Creatinine, Diet, Carbohydrate Loading adverse effects, Disease Models, Animal, Ethylene Glycol, Fructose, Humans, Hyperoxaluria blood, Hyperoxaluria etiology, Hyperoxaluria urine, Kidney Tubules pathology, Kidney Tubules physiopathology, Male, Metabolic Syndrome blood, Metabolic Syndrome etiology, Metabolic Syndrome urine, Nephrolithiasis blood, Nephrolithiasis chemically induced, Nephrolithiasis urine, Osteopontin metabolism, Rats, Rats, Sprague-Dawley, Renal Insufficiency blood, Renal Insufficiency etiology, Renal Insufficiency urine, Calcium Oxalate metabolism, Hyperoxaluria metabolism, Metabolic Syndrome metabolism, Nephrolithiasis metabolism, Renal Insufficiency metabolism

Abstract

Metabolic syndrome (MS) individuals have a higher risk of developing chronic kidney disease through unclear pathogenic mechanisms. MS has been also related with higher nephrolithiasis prevalence. To establish the influence of MS on renal function, we designed a murine model of combined metabolic syndrome and hyperoxaluria. Four groups of male Sprague-Dawley rats were established: (1) control group (n = 10) fed with standard chow; (2) stone former group (SF) (n = 10) fed with standard chow plus 0.75% ethylene glycol administered in the drinking water; (3) metabolic syndrome group (MS) (n = 10), fed with 60% fructose diet; (4) metabolic syndrome + stone former group (MS + SF) (n = 10), 60% fructose diet and 0.75% EG in the drinking water. MS group showed a significant injury to renal function when hyperoxaluria was induced. It was demonstrated by a significant decrease of creatinine clearance (p < 0.001), with higher tubular damage (34.3%, CI 95% 23.9-44.7, p < 0.001), produced by deposition of crystals, and increased tubular synthesis of osteopontin as a response to tubular damage. Induction of hyperoxaluria in rats with MS causes severe morphological alterations with a significant impairment of renal function. This impairment is not produced in rats without MS. Therefore, this model can be useful for the study of the influence of MS in stone formation.

Published

2018

6. The role of intestinal oxalate transport in hyperoxaluria and the formation of kidney stones in animals and man.

Author

Whittamore JM and Hatch M

Subjects

Animals, Biological Transport, Humans, Intestinal Absorption, Hyperoxaluria metabolism, Intestinal Mucosa metabolism, Kidney Calculi etiology, Oxalates metabolism

Abstract

The intestine exerts a considerable influence over urinary oxalate in two ways, through the absorption of dietary oxalate and by serving as an adaptive extra-renal pathway for elimination of this waste metabolite. Knowledge of the mechanisms responsible for oxalate absorption and secretion by the intestine therefore have significant implications for understanding the etiology of hyperoxaluria, as well as offering potential targets for future treatment strategies for calcium oxalate kidney stone disease. In this review, we present the recent developments and advances in this area over the past 10 years, and put to the test some of the new ideas that have emerged during this time, using human and mouse models. A key focus for our discussion are the membrane-bound anion exchangers, belonging to the SLC26 gene family, some of which have been shown to participate in transcellular oxalate absorption and secretion. This has offered the opportunity to not only examine the roles of these specific transporters, revealing their importance to oxalate homeostasis, but to also probe the relative contributions made by the active transcellular and passive paracellular components of oxalate transport across the intestine. We also discuss some of the various physiological stimuli and signaling pathways which have been suggested to participate in the adaptation and regulation of intestinal oxalate transport. Finally, we offer an update on research into Oxalobacter formigenes, alongside recent investigations of other oxalate-degrading gut bacteria, in both laboratory animals and humans.

Published

2017

7. Hyperoxaluria-induced tubular ischemia: the effects of verapamil on the antioxidant capacity of the affected kidneys.

Author

Sarica K, Kafkasli A, Narter F, Ozturk O, Yazici O, Hamarat B, Sahin C, and Eryildirim B

Subjects

Animals, Ischemia metabolism, Male, Rats, Rats, Sprague-Dawley, Antioxidants therapeutic use, Calcium Channel Blockers therapeutic use, Hyperoxaluria complications, Hyperoxaluria metabolism, Ischemia drug therapy, Ischemia etiology, Kidney Tubules blood supply, Oxidative Stress drug effects, Verapamil therapeutic use

Abstract

To evaluate the potential protective effects of a calcium channel blocker (Verapamil) on the oxidative stress related changes with an emphasis on the antioxidant capacity of the kidneys an experimental study in rats was performed. A total of 44 rats have been included. Hyperoxaluria was induced in Group 1 by continuous administration of ethylene glycol (EG). Animals in Group 2 received Verapamil in addition to EG. Animals in Group 3 constituted the control group. In addition to the evaluation of tissue and serum levels of three scavenging enzymes, NO, MDA and T-AOC; the presence and degree of crystal formation in renal parenchyma were evaluated in all animals after 7 and 28 days. Our data demonstrated that in addition to the lower level of all three scavenging enzymes (SOD, CAT and GSH) particularly during late phase evaluation (4 weeks); the total antioxidant capacity (T-AOC) of these kidneys were also higher when compared with the animals receiving EG only. Tissue and serum levels of both NO and MDA indicated the preventive effect of Verapamil on the oxidative stress induced changes. Very limited or no crystallization in the kidneys treated with verapamil during early and late phase examination was observed when compared with considerable crystal formation in Group 2 animals. Verapamil treatment may preserve the oxidant capacity of the kidneys and subsequently limit the crystal deposition induced by hyperoxaluria. Verapamil could therefore be considered in the management of kidney stone formation particularly in cases with recurrent kidney stone disease.

Published

2016

8. Protective effects of N-acetylcysteine against hyperoxaluria induced mitochondrial dysfunction in male wistar rats.

Author

Sharma M, Kaur T, and Singla SK

Subjects

Animals, Calcium urine, Citric Acid Cycle drug effects, Creatinine metabolism, Glutathione metabolism, Glutathione Peroxidase metabolism, Glutathione Reductase metabolism, Hyperoxaluria metabolism, Hyperoxaluria urine, Kidney metabolism, Kidney physiopathology, L-Lactate Dehydrogenase urine, Lipid Peroxidation drug effects, Male, Mitochondria metabolism, Mitochondrial Diseases metabolism, Mitochondrial Diseases physiopathology, Mitochondrial Diseases urine, Nephrolithiasis metabolism, Nephrolithiasis physiopathology, Nephrolithiasis urine, Oxidative Stress drug effects, Rats, Rats, Wistar, Superoxide Dismutase metabolism, Acetylcysteine pharmacology, Hyperoxaluria physiopathology, Mitochondria drug effects, Mitochondrial Diseases drug therapy, Protective Agents pharmacology

Abstract

The purpose of the present study was to evaluate the nephro-protective potential of N-acetylcysteine against hyperoxaluria-induced renal mitochondrial dysfunction in rats. Nine days dosing of 0.4 % ethylene glycol +1 % ammonium chloride, developed hyperoxaluria in male wistar rats which resulted in renal injury and dysfunction as supported by increased level of urinary lactate dehydrogenase, calcium, and decreased creatinine clearance. Mitochondrial oxidative strain in hyperoxaluric animals was evident by decreased levels of superoxide dismutase, glutathione peroxidase, glutathione reductase, reduced glutathione, and an increased lipid peroxidation. Declined activities of respiratory chain enzymes and tricarboxylic acid cycle enzymes showed mitochondrial dysfunction in hyperoxaluric animals. N-acetylcysteine (50 mg/kg, i.p.), by virtue of its -SH reviving power, was able to increase the glutathione levels and thus decrease the oxidative stress in renal mitochondria. Hence, mitochondrial damage is, evidently, an essential event in ethylene glycol-induced hyperoxaluria and N-acetylcysteine presented itself as a safe and effective remedy in combating nephrolithiasis.

Published

2015

9. Osteopontin knockdown in the kidneys of hyperoxaluric rats leads to reduction in renal calcium oxalate crystal deposition.

Author

Tsuji H, Shimizu N, Nozawa M, Umekawa T, Yoshimura K, De Velasco MA, Uemura H, and Khan SR

Subjects

Animals, Calcium Oxalate chemistry, Cell Line, Crystallization, Disease Models, Animal, Epithelial Cells cytology, Hyperoxaluria genetics, Hyperoxaluria metabolism, Male, Nephrolithiasis genetics, Nephrolithiasis metabolism, Osteopontin metabolism, RNA, Messenger metabolism, RNA, Small Interfering genetics, RNA, Small Interfering pharmacology, Rats, Sprague-Dawley, Calcium Oxalate metabolism, Genetic Therapy methods, Hyperoxaluria therapy, Kidney physiology, Nephrolithiasis therapy, Osteopontin genetics

Abstract

Osteopontin (OPN) expression is increased in kidneys of rats with ethylene glycol (EG) induced hyperoxaluria and calcium oxalate (CaOx) nephrolithiasis. The aim of this study is to clarify the effect of OPN knockdown by in vivo transfection of OPN siRNA on deposition of CaOx crystals in the kidneys. Hyperoxaluria was induced in 6-week-old male Sprague-Dawley rats by administering 1.5% EG in drinking water for 2 weeks. Four groups of six rats each were studied: Group A, untreated animals (tap water); Group B, administering 1.5% EG; Group C, 1.5% EG with in vivo transfection of OPN siRNA; Group D, 1.5% EG with in vivo transfection of negative control siRNA. OPN siRNA transfections were performed on day 1 and 8 by renal sub-capsular injection. Rats were killed at day 15 and kidneys were removed. Extent of crystal deposition was determined by measuring renal calcium concentrations and counting renal crystal deposits. OPN siRNA transfection resulted in significant reduction in expression of OPN mRNA as well as protein in group C compared to group B. Reduction in OPN expression was associated with significant decrease in crystal deposition in group C compared to group B. Specific suppression of OPN mRNA expression in kidneys of hyperoxaluric rats leads to a decrease in OPN production and simultaneously inhibits renal crystal deposition.

Published

2014

10. Hyperoxaluria in patients with idiopathic calcium nephrolithiasis.

Author

Trinchieri A, Ostini F, Nespoli R, Rovera F, Zanetti G, and Pisani E

Subjects

Adult, Body Constitution, Diet, Female, Humans, Kidney Calculi metabolism, Male, Middle Aged, Calcium Oxalate metabolism, Hyperoxaluria metabolism, Kidney Calculi urine

Abstract

We studied 476 patients with idiopathic renal calcium stone disease (286 M, 190 F) while they ate their customary diets. Each subject collected a 24-hour urine sample and completed a dietary diary for a 3-day period. Daily urinary oxalate excretion (M 0.24 +/- 0.15 mg/dl, F 0.23 +/- 0.15 mg/dl) and nutrient intake values were calculated and multiple regression analyses were performed. Daily urinary oxalate excretion was significantly (p < 0.001) related to urinary volume (R = 0.24), vitamin C intake (R = 0.33) and body mass index (R = 0.37) and inversely related to calcium intake (R = -0.35). We conclude that urinary oxalate reflects endogenous oxalate production, presumably related to body size, but also intestinal absorption of oxalate, related to dietary intake and to the effect of dietary calcium intake which reduces intestinal oxalate absorption.

Published

1998

11. Oxalate and calcium oxalate crystals are injurious to renal epithelial cells: results of in vivo and in vitro studies.

Author

Thamilselvan S and Khan SR

Subjects

Animals, Cells, Cultured, Epithelial Cells metabolism, Epithelial Cells pathology, Hyperoxaluria etiology, Hyperoxaluria metabolism, Hyperoxaluria pathology, Kidney drug effects, Kidney pathology, Kidney Calculi metabolism, Kidney Calculi pathology, Lipid Peroxidation, Male, Rats, Rats, Sprague-Dawley, Calcium Oxalate toxicity, Kidney Calculi etiology, Oxalates toxicity

Abstract

Calcium oxalate (CaOx) nephrolithiasis was induced in male Sprague-Dawley rats by administration of 0.75% ethylene glycol. Urinary excretion of lactate dehydrogenase (LDH) was used as a marker of cellular injury. Lipid peroxides (LP), as marker for free radical injury, were measured as malondialdehyde (MDA) in urine and the kidneys. Urinary oxalate (Ox), LDH, LP, CaOx crystals, and renal LP and CaOx crystal deposits were examined on day 0, 5, 30 and 60 of the experiment. There were significant differences between control and experimental rats in all the parameters except LDH which did not show a significant increase after 15 days. Subconfluent cultures of MDCK and LLCPK1 cells were exposed to various concentrations of oxalate and/or 500 fg/ml CaOx crystals. Cell viability was assayed by trypan blue exclusion, cellular injury was determined by measuring LDH in the media, and free radical injury was measured as MDA contents of the cells. On exposure to both Ox and/or CaOx crystals trypan blue exclusion decreased and LDH and MDA increased significantly in both tissue cultures. LLC-PK1 appeared more sensitive. The results indicate that both oxalate and calcium oxalate crystals are injurious to renal epithelial cells in the kidneys as well as in culture.

Published

1998