The cytotoxic, genotoxic and mitotoxic effects of Atractylis gummifera extract in vitro.

Background: The Mediterranean thistle Atractylis gummifera L. (Asteraceae; AG) has diterpenoid glucosides; atractyloside and carboxyatractyloside that interact with mitochondrial protein adenine nucleotide translocator (ANT) and resulted in ATP inhibition. Despite its well-known toxicity, acute poisonings still occur with this plant. Although most symptoms are attributed to ANT and diterpenoids interaction, in-depth investigation of the effects of AG extract on various cellular processes has not been performed. Objective/method: We tested in vitro induction of mitochondrial permeability transition pore (MPTP) opening in bovine liver mitochondria and evaluated its cytotoxicity and genotoxicity using Allium cepa test. Cell division, mitotic index (MI) and total chromosomal and mitotic aberrations (TAs), that all seem potentially affected by ATP shortage, were studied in root cells of Allium cepa exposed to Atractylis gummifera extract. Results: With the two different doses of two purified AG fractions, stronger induction of MPTP was observed compared to the induction with the standard pure atracyloside. Aqueous AG extract exerted inhibition root growth in A. cepa at 6 different doses. The TAs was increased in a dose-dependent manner too, while mitotic index was decreased at the same doses. Evaluation of mitotic phases revealed mitodepressive effect of AG on A. cepa roots. Conclusion: this work highlights cellular and mitochondrial adverse effects of Atractylis gummifera extracts. A purified fraction that likely corresponds to ATR derivatives induces MPTP opening leading to swelling of mitochondria and its dysfunction. Allium cepa test provides the evidence for A. gummifera genotoxicity and cytotoxicity.

Direct and indirect targets of carboxyatractyloside, including overlooked toxicity toward nucleoside diphosphate kinase (NDPK) and mitochondrial H+ leak.

CONTEXT: The toxicity of atractyloside/carboxyatractyloside is generally well recognized and commonly ascribed to the inhibition of mitochondrial ADP/ATP carriers, which are pivotal for oxidative phosphorylation. However, these glycosides may 'paralyze' additional target proteins. OBJECTIVE: This review presents many facts about atractyloside/carboxyatractyloside and their plant producers, such as Xanthium spp. (Asteraceae), named cockleburs. METHODS: Published studies and other information were obtained from databases, such as 'CABI - Invasive Species Compendium', 'PubMed', and 'The World Checklist of Vascular Plants', from 1957 to December 2022. The following major keywords were used: 'carboxyatractyloside', 'cockleburs', 'hepatotoxicity', 'mitochondria', 'nephrotoxicity', and 'Xanthium'. RESULTS: In the third decade of the twenty first century, public awareness of the severe toxicity of cockleburs is still limited. Such toxicity is often only perceived by specialists in Europe and other continents. Interestingly, cocklebur is among the most widely distributed invasive plants worldwide, and the recognition of new European stands of Xanthium spp. is provided here. The findings arising from field and laboratory research conducted by the author revealed that (i) some livestock populations may instinctively avoid eating cocklebur while grazing, (ii) carboxyatractyloside inhibits ADP/GDP metabolism, and (iii) the direct/indirect target proteins of carboxyatractyloside are ambiguous. CONCLUSIONS: Many aspects of the Xanthium genus still require substantial investigation/revision in the future, such as the unification of the Latin nomenclature of currently distinguished species, bur morphology status, true fruit (achene) description and biogeography of cockleburs, and a detailed description of the physiological roles of atractyloside/carboxyatractyloside and the toxicity of these glycosides, mainly toward mammals. Therefore, a more careful interpretation of atractyloside/carboxyatractyloside data, including laboratory tests using Xanthium-derived extracts and purified toxins, is needed.

A validated method for quantifying atractyloside and carboxyatractyloside in blood by HPLC-HRMS/MS, a non-fatal case of intoxication with Atractylis gummifera L.

Atractyloside (ATR) and carboxyatractyloside (CATR) are diterpene glycosides that are responsible for the toxicity of several Asteraceae plants around the world. Mediterranean gum thistle (Atractylis gummifera L.) and Zulu impila (Callilepis laureola DC.), in particular, are notoriously poisonous and the cause of many accidental deaths, some suicides and even some murders. There is no current method for measuring the two toxins in biological samples that meet the criteria of specificity required in forensic medicine. We have endeavored to fill this analytical gap. Analysis was carried out using a solid-phase extraction and a high-performance liquid chromatography coupled with high-resolution tandem mass spectrometry detection. The method was validated in the whole blood with quantification limits of 0.17 and 0.15 µg/L for ATR and CATR, respectively. The method was applied to a non-fatal case of intoxication with A. gummifera. To the best of the authors' knowledge, this is the first time that a concentration of ATR and CATR in blood (883.1 and 119.0 µg/L, respectively) and urine (230.4 and 140.3 µg/L, respectively) is reported. ATR and CATR were quantified in A. gummifera roots by the standard method addition (3.7 and 5.4 mg/g, respectively).

Analytical confirmation of Xanthium strumarium poisoning in cattle.

Xanthium strumarium, commonly referred to as "cocklebur," rarely causes poisoning in cattle. When mature, this robust, annual weed bears numerous oval, brownish, spiny burs. Only the seeds in the burs and young seedlings (cotyledonary leaves) contain the toxic principle, carboxyatractyloside. In the Frankfort district of the Free State Province of South Africa, a herd of 150 Bonsmara cows were allowed to graze on the banks of a small river, where mature cocklebur was growing. Four cows died while grazing in this relatively small area. Clinical signs ranged from recumbency, apparent blindness, and hypersensitivity to convulsive seizures. During necropsy, burs completely matted with ingesta were located in the rumen content. The most distinctive microscopic lesions were severe, bridging centrilobular to midzonal hepatocyte necrosis and hemorrhage. Ultrastructurally, periacinar hepatocytes were necrotic, and novel electron-dense cytoplasmic needle-like crystals were observed, often in close association with peroxisomes. Carboxyatractyloside concentrations were determined using liquid chromatography-high-resolution mass spectrometry (LC-HRMS). Carboxyatractyloside was present in rumen contents at 2.5 mg/kg; in burs removed from the rumen at 0.17 mg/kg; in liver at 66 ng/g, and was below the limit of quantitation in the kidney sample, estimated at approximately 0.8 ng/g. Based on the presence of the plants on the riverbank, the history of exposure, the clinical findings, the presence of burs in the rumen, and the microscopic and ultrastructural lesions, X. strumarium poisoning in the herd of cattle was confirmed and was supported by LC-HRMS.

The degradation mechanism of toxic atractyloside in herbal medicines by decoction.

Atractyloside (ATR) is found in many Asteraceae plants that are commonly used as medicinal herbs in China and other eastern Asian countries. ATR binds specifically to the adenine nucleotide translocator in the inner mitochondrial membrane and competitively inhibits ADP and ATP transport. The toxicity of ATR in medical herbs can be reduced by hydrothermal processing, but the mechanisms of ATR degradation are not well understood. In this study, GC-MS coupled with SPE and TMS derivatisation was used to detect ATR levels in traditional Chinese medicinal herbs. Our results suggest that ATR molecules were disrupted by decomposition, hydrolysis and saponification after heating with water (decoction) for a long period of time. Hydrothermal processing could decompose the endogenous toxic compounds and also facilitate the detoxification of raw materials used in the Chinese medicine industry.

Mortality of a captive axis deer (Axis axis) and a llama (Lama glama) due to ingestion of Wedelia glauca.

The current study describes a naturally occurring cluster of cases of Wedelia glauca intoxication. Seven of 14 axis deer (Axis axis) and 1 of 8 llamas (Lama glama) in a zoo of Buenos Aires province, Argentina, died suddenly after ingestion of a new batch of alfalfa (Medicago sativa) hay bales contaminated with the hepatotoxic plant W. glauca. Necropsies of 1 deer and 1 llama were performed. Pathological findings in both animals included severe diffuse acute centrilobular hepatocellular necrosis and hemorrhage, and clear yellowish translucent gelatinous edema on the wall of the gall bladder and the serosa of the choledochoduodenal junction. Fragments of W. glauca plants were identified in the hay based on the botanical characteristics of the leaves. Samples of gastric contents were examined by microhistological analysis, which identified epidermal fragments of W. glauca based on the presence of characteristic uniseriate glandular hairs (trichomes), confirming recent ingestion of W. glauca in both cases. The fragments were quantified and represented 5% of all examined vegetal fragments in the deer and 10% in the llama.

Atractyloside induces low contractile reaction of arteriolar smooth muscle through mitochondrial damage.

Atractyloside is the principal naturally occurring active ingredient in ethnomedicines and animal grazing forage. Evidence that atractyloside can induce opening of the mitochondrial permeability transition pore (mPTP) indicates that mitochondrial mechanisms may play an important role in pathophysiological lesions of the heart, liver and kidney after atractyloside poisoning. Therefore, in this study we investigated the association of atractyloside-induced mitochondrial damage in arteriolar smooth muscle cells (ASMCs) with contractile reaction. Atractyloside led to depolarized and swollen or damaged ASMC mitochondria, which might be related to the concentration-dependent induction of mPTP opening. Relative ATP content in ASMCs was significantly reduced by 48%, 63% and 66% of control when cells were treated with 7.5, 10, and 15 µm atractyloside for 10 min, respectively, and ASMCs were hyperpolarized. In addition, the contractile responsiveness of ASMCs was eventually weakened. These results suggest that atractyloside has a toxic effect on vasoreactivity, which is possibly related to mitochondrial damage.

Hepatotoxicity of kaurene glycosides from Xanthium strumarium L. fruits in mice.

The fruit of Xanthium strumarium L. (Cang-Er-Zi) is a traditional Chinese medicine that is used in curing nasal diseases and headache according to the Chinese Pharmacopoeia. However, clinical utilization of Xanthium strumarium is relatively limited because of its toxicity. The present investigation was carried out to evaluate the toxic effects on acute liver injury in mice of the two kaurene glycosides (atractyloside and carbxyatractyloside), which are main toxic constituents isolated from Fructus Xanthii on acute liver injury in mice. Histopathological examinations revealed that there were not obviously visible injury in lungs, heart, spleen, and the central nervous system in the mice by intraperitoneal injection of atractyloside (ATR, at the doses 50,125 and 200 mg/kg) and carbxyatractyloside (CATR, at the doses 50,100 and 150 mg/kg) for 5 days. However, it revealed extensive liver injuries compared with the normal group. In the determination of enzyme levels in serum, intraperitoneal injection of ATR and CATR resulted in significantly elevated serum alanine aminotransferase (ALT), asparate aminotransferase (AST), alkaline phosphatase (ALP) activities compared to controls. In the hepatic oxidative stress level, antioxidant-related enzyme activity assays showed that ATR and CATR administration significantly increased hepatic malondialdehyde (MDA) concentration, as well as decreased superoxide dismutase (SOD), catalase (CAT) activities and glutathione (GSH) concentration, and this was in good agreement with the results of serum aminotransferase activity and histopathological examinations. Taken together, our results demonstrate that kaurene glycosides induce hepatotoxicity in mice by way of its induction of oxidative stress as lipid peroxidation in liver, which merited further studies. Therefore, these toxic constituents explain, at least in part, the hepatotoxicity of X. strumarium L. in traditional medicine.

Effects of glycyrrhizic acid on cocklebur-induced hepatotoxicity in rat and human hepatocytes.

Herbal medicines are gradually being accepted for their low toxicity and high efficacy, but their hepatotoxicity still needs to be recognized. For the multiple compounds in herbs, hepatocytes in vitro would be a useful tool for the evaluation of herbal hepatotoxicity. This study aimed at cocklebur/atractyloside-induced hepatotoxicity and the protective effects of glycyrrhizic acid (GA) against this toxicity using rat and human hepatocytes in monolayer culture. After a 48 h treatment, cocklebur as well as atractyloside induced concentration-dependent hepatotoxicity according to obvious decreases of cell viability, intracellular glutathione (GSH) content and albumin secretion in rat hepatocytes. Compared with rat hepatocytes, human hepatocytes seemed to be less sensitive to cocklebur-induced hepatotoxicity, indicative of species differences between humans and rats. Furthermore, as expected, GA showed significant protective effects on cocklebur hepatotoxicity in both human and rat hepatocytes. Overall, these results suggested that hepatocytes in vitro, particularly human hepatocytes, could be a useful tool for herbal hepatotoxicity screening in vitro.

Atractylis gummifera L. poisoning: an ethnopharmacological review.

Atractylis gummifera L. (Asteraceae) is a thistle located in the Mediterranean regions. Despite the plant's well-known toxicity, its ingestion continues to be a common cause of poisoning. The toxicity of Atractylis gummifera resides in atractyloside and carboxyatractyloside, two diterpenoid glucosides capable of inhibiting mitochondrial oxidative phosphorylation. Both constituents interact with a mitochondrial protein, the adenine nucleotide translocator, responsible for the ATP/ADP antiport and involved in mitochondrial membrane permeabilization. Poisoned patients manifest characteristic symptoms such as nausea, vomiting, epigastric and abdominal pain, diarrhoea, anxiety, headache and convulsions, often followed by coma. No specific pharmacological treatment for Atractylis gummifera intoxication is yet available and all the current therapeutic approaches are only symptomatic. In vitro experiments showed that some compounds such as verapamil, or dithiothreitol could protect against the toxic effects of atractyloside, but only if administered before atractyloside exposure. New therapeutic approaches could come from immunotherapy research: some studies have already tried to produce polyclonal Fab fragments against the toxic components of Atractylis gummifera.

Mitochondrial permeability transition as a novel principle of hepatorenal toxicity in vivo.

Atractyloside (Atr) binds to the adenine nucleotide translocator (ANT) and inhibits ANT-mediated ATP/ADP exchange on the inner mitochondrial membrane. In addition, Atr can trigger opening of a non-specific ion channel, within the ANT-containing permeability transition pore complex (PTPC), which is subject to redox regulation and inhibited by cyclosporin A (CsA). Here we show that the cytotoxic effects of Atr, both in vivo and in vitro, are determined by its capacity to induce PTPC opening and consequent mitochondrial membrane permeabilization (MMP). Thus, the Atr-induced MMP and death of cultured liver cells are both inhibited by CsA as well as by glutathione (GSH) and enhanced by GSH depletion. Similarly, the hepatorenal toxicity of Atr, assessed in vivo, was reduced by treating mice with CsA or a diet rich in sulfur amino acids, a regime which enhances mitochondrial GSH levels. Atr injection induced MMP in hepatocytes and proximal renal tubular cells, and MMP was reduced by either CsA or GSH. Acetaminophen (paracetamol)-induced acute poisoning was also attenuated by CsA and GSH, both in vitro and in vivo. Altogether these data indicate that PTPC-mediated MMP may determine the hepatorenal toxicity of xenobiotics in vivo.

Effects of the calcium channel blocker verapamil and sulphydryl reducing agent dithiothreitol on atractyloside toxicity in precision-cut rat renal cortical and liver slices.

The effects of dithiothreitol (DTT), a sulfhydryl-containing agent and verapamil (VRP), a calcium channel blocker as possible cytoprotectants against the atractyloside-induced toxicity were characterized in rat kidney and liver slices in vitro using multiple markers of toxicity. Precision-cut slices (200 microM thick) were either incubated with atractyloside (2 mM) or initially preincubated with either DTT (5 mM) or VRP (100 microM) for 30 min followed by exposure to atractyloside (2 mM) for 3 h at 37 degrees C on a rocker platform rotated at approximately 3 rpm. All of the toxicity parameters were sensitive to exposure to atractyloside, but treatment with DTT or VRP alone did not provide any indication of damage to the tissues. Preincubation of slices containing either DTT or VRP for 30 min provided total protection against atractyloside-induced increase in LDH leakage in both kidney and liver slices. Increased induction of lipid peroxidation by atractyloside in liver slices was completely abolished by DTT and VRP. Both DTT and VRP provided partial protection against atractyloside-induced inhibition of gluconeogenesis in both kidney and liver slices. Atractyloside-induced ATP depletion in both kidney and liver slices was partially abolished by VRP but not DTT. The significant depletion of GSH in the kidney slices by atractyloside was completely reversed by DTT only, while VRP alone reversed the same process in liver slices. Decreased MTT reductive capacity and significant increase in ALT leakage caused by atractyloside in liver slices was partially reversed. Complete protection was achieved with both DTT and VRP against atractyloside-induced inhibition of PAH uptake in kidney slices. These findings suggest that both DTT and VRP exert cytoprotective effects in atractyloside-induced biochemical perturbation, effects that differ in liver and kidney. The effect of these agents on atractyloside has provided us with a further understanding of the molecular mechanism of its action.

Adenine nucleotide and calpain inhibitor I protect against atractyloside-induced toxicity in rat renal cortical slices in vitro.

Atractyloside is a compound with a documented nephrotoxicity. It induces renal tubular necrosis at high doses and apoptosis at lower doses. This study investigates the potential protective effect of some chemical agents against atractyloside-induced nephrotoxicity in vitro using the precision-cut rat renal cortical slices obtained from kidneys of Wistar rats. For co-incubation experiments, slices were incubated for 3 h at 37 degrees C on a rocker platform with various chemical agents: ADP (5 mM), calpain inhibitor I (CPI, 1 mM), stevioside (STV, 2.5 mM) or probenecid (PRB, 2.5 mM) in the presence or absence of atractyloside (2 mM). For pre-incubation experiments, slices were incubated with the same chemical agents for 1 h before exposure to atractyloside. The nephrotoxic effects of atractyloside (2 mM) alone were manifested in several ways: by a marked increase in lactate dehydrogenase (LDH) and alkaline phosphatase (ALP) leakage, significant inhibition of p-aminohippurate (PAH) accumulation, marked depletion of intracellular ATP and reduced glutathione (GSH), and a significant reduction in pyruvate-stimulated gluconeogenesis. Co-incubation of slices with ADP or CPI and atractyloside completely blocked atractyloside-induced increase in LDH leakage, but not ALP leakage. Atractyloside-induced depletion of ATP and reduced gluconeogenesis was prevented by co-incubation with ADP or CPI. Furthermore, co-incubation of slices with STV and atractyloside, but not PRB, completely abolished atractyloside-induced depletion of ATP and decreased gluconeogenesis in the slices. Pre-incubation of slices with either ADP or CPI protected against atractyloside-induced increase in LDH leakage, reduced ATP and decreased gluconeogenesis. PAH uptake in the slices was inhibited by atractyloside and PRB in a time-dependent manner. While ADP and CPI were found to exert complete protection against atractyloside-induced toxicity irrespective of treatment schedule, STV is effective only under certain conditions, and PRB offer no protection at all. The results of this study demonstrate the usefulness of renal cortical slices as toxicology tool for evaluating and screening compounds for their potential protective effects, and are supportive of a role of adeninine nucleotide (ADP) and protease inhibitor (CPI) in protecting against atractyloside-induced cell injury.

The biochemistry and toxicity of atractyloside: a review.

Atractyloside poisoning is an infrequent but often fatal form of herbal poisoning, which occurs worldwide but especially in Africa and the Mediterranean regions. The primary mechanism of atractyloside poisoning is known to be inhibition of the mitochondrial ADP transporter. Poisoning in humans may present with either acute hepatic or renal pathology and it is possible that there is a second, different mechanism of toxicity to the hepatocyte. Atractyloside in large amounts gives rise to massive necrosis, but in vitro studies have shown that at lower doses cells progress to apoptosis. Simple methods for the detection of atractyloside poisoning are at present restricted to thin-layer chromatography in urine and are useful only in the case of severe poisoning. Immunoassays, high-performance liquid chromatography, nuclear magnetic resonance, and a recently developed high-performance liquid chromatography/mass spectrometry method have yet to be applied to clinical diagnoses. There is at present no treatment, but a fuller understanding of the mechanisms of toxicity may lead to the application of a number of compounds that are effective in vitro.

Atractyloside nephrotoxicity: in vitro studies with suspensions of rat renal fragments and precision-cut cortical slices.

The consumption of plants containing atractyloside, a diterpenoid glycoside, causes selective proximal tubule injury leading to renal failure and death in humans. The underlying mechanisms responsible for its toxicity are still not well understood. The present study was therefore carried out to determine the mechanism and the exact sequence of events that lead to molecular toxic injury. A comparative study using renal cortical slices, suspension of freshly isolated renal proximal tubular fragments and glomeruli of male Wistar rat was made. These in vitro systems were exposed to 100-1000 mM atractyloside for 2-3 h at 37 degrees C. Atractyloside caused a significant alteration in various toxicity parameters in a concentration- and time-dependent manner in renal cortical slices and proximal tubular fragments, but not in glomeruli. The earliest change following exposure to atractyloside (1000 microM) was a significant reduction of intracellular adenosine 5'-triphosphate (ATP) content occurring within 1 h in the tubules and 2 h in slices. The significant depletion of reduced glutathione (GSH) inhibitor of p-aminohippuric (acid) (PAH) uptake and gluconeogenesis occurred simultaneously following loss of cellular energy. These events were only limited to the renal cortical slices and proximal tubular fragments. Increased severity of cellular injury resulted in cytotoxicity with the significant increase in the leakage of alkaline phosphatase (ALP) and lactate dehydrogenase (LDH) in proximal tubular fragments (occurring at 2 h) and renal cortical slices (occurring at 3 h). There were, however, no alterations in oxidized glutathione (GSSG) levels or in the ratio of GSH/GSSG. Only limited lipid peroxidation in proximal tubular fragments and glomeruli was observed at atractyloside concentrations of 500 microM and above. In all cases of toxicity, the glomeruli were unaffected. Pretreatment of slices or fragments with probenecid (1.0 mM) failed to completely abolish atractyloside toxicity. These data demonstrate dose- and time-dependent toxicity of atractyloside and clearly confirmed the proximal tubular fragments as the target tissue. Atractyloside exhibits a toxicity profile that indicates early alteration in mitochondrial function and consequently loss of cellular energy, followed by reduced metabolic function and transport processes and ultimately cell death. This appears to be the most likely mechanism by which atractyloside exerted its acute cytotoxicity. Renal cortical slices, which maintain proximal tubule and glomeruli in their anatomic relationship, responded similarly to atractyloside toxicity as the proximal tubular fragments, and might be suggested as the most suitable in vitro model system for studying the mechanisms of atractyloside toxicity as they are more likely to mirror changes seen in the whole organ.

The toxic mechanism and metabolic effects of atractyloside in precision-cut pig kidney and liver slices.

The toxic and cellular metabolic effects of atractyloside, a diterpenoid glycoside, which causes fatal renal and hepatic necrosis in vivo in animals and humans, have been investigated in tissue slices prepared from male domestic pig kidney and liver. Precision-cut slices (200 microm thick) were incubated with atractyloside at concentrations of 200 microM, 500 microM, 1.0 mM and 2.0 mM for 3 h at 37 degrees C and changes in lipid profile and pyruvate-stimulated gluconeogenesis investigated. Lipid peroxidative changes, reduced glutathione (GSH) and ATP content, the release of lactate dehydrogenase (LDH), alkaline phosphatase (ALP), alanine and aspartate aminotransferase (ALT/AST) were also assessed. After 3 h of incubation, atractyloside caused a significant (P < 0.01) and concentration-dependent leakage of LDH and ALP from kidney slices. Only LDH leakage was significantly elevated in liver slices while ALT and AST leakage showed marginal increase. Atractyloside at concentrations of > or =200 microM caused a significant increase in lipid peroxidation, but only in liver slices. However, atractyloside at concentrations of > or =200 microM caused a marked depletion of GSH and ATP content in both kidney and liver slices. There was a marked decrease in total and individual phospholipid in kidney but not in liver slices. However, cholesterol and triacylglycerol levels were not affected by atractyloside in both kidney and liver slices. Renal and hepatic pyruvate-stimulated gluconeogenesis were significantly (P < 0.05) inhibited at atractyloside concentrations of > or =500 microM. Accumulation of organic anion p-amino-hippuric acid (PAH) was also inhibited in renal cortical slices at atractyloside concentrations of > or =500 microM. These results suggest that the observable in vivo effect of atractyloside can be reproduced in slices and that basic mechanistic differences exist in the mode of toxicity in liver and kidney tissues. The data also raise the possibility that the mechanistic basis of metabolic alterations in these tissues following treatment with atractyloside may be relevant to target selective toxicity.

Biochemistry and toxicology of the diterpenoid glycoside atractyloside.

Atractyloside (Atr) is a diterpenoid glycoside that occurs naturally in plants (many of which are used in ethnomedicines) found in Europe, Africa, South America, Asia and the far East. It is also present in animal grazing forage. Atr (and its analogues) may be present at levels as high as 600 mg/kg dried plant material. Consumption of the plants containing Atr or carboxyatractyloside (carboxyAtr) has caused fatal renal proximal tubule necrosis and/or centrilobular hepatic necrosis in man and farm animals. Although pure Atr and crude plant extracts disrupt carbohydrate homeostasis and induce similar pathophysiological lesions in the kidney and liver, it is also possible that the toxicity of Atr may be confounded by the presence of other natural constituents in plants. Atr competitively inhibits the adenine nucleoside carrier in isolated mitochondria and thus blocks oxidative phosphorylation. This has been assumed to explain changes in carbohydrate metabolism and the toxic effects in liver and kidney. Although the acute toxicity of Atr is well described, many aspects of Atr toxicity (subchronic and chronic toxicity, reproductive toxicity, mutagenicity and carcinogenicity) have not been investigated and pharmacokinetic and metabolism data are limited. In vitro proximal tubular cells are selectively sensitive to Atr, whereas other renal cell types are quite resistant. There are also differences in the response of liver and renal tissue to Atr. Thus, not all of the clinical, biochemical and morphological changes caused by Atr can simply be explained on the basis of inhibition of mitochondrial phosphorylation. The relevance to a wider human risk is shown by the presence of Atr analogues in dried roasted Coffea arabica beans (17.5 32 mg/kg). There are no data to help identify the risk of low dose chronic exposure in human coffee consumers, nor is there information on the levels of Atr or its analogues in other commonly consumed human foodstuffs.

Toxicity of atractyloside in precision-cut rat and porcine renal and hepatic tissue slices.

Atractyloside (ATR) causes acute fatal renal and hepatic necrosis in animals and humans. Precision-cut renal cortical and hepatic slices (200 +/- 15 microns) from adult male Wistar rat and domestic pigs, incubated with ATR (0.2-2.0 mM) for 3 h at 37 degrees C, inhibited pyruvate-stimulated gluconeogenesis in a concentration- and time-dependent manner. p-Aminohippurate accumulation was significantly inhibited in both rat and pig renal cortical slices from 0.2 mM ATR (p < 0.05). There was a small decrease in mitochondrial reduction of 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium to formazan in both rat and pig kidney slices, which was significant at > or = 2 mM, but no changes in liver slices from either species. However, cellular ATP was significantly depleted at > or = 0.2 mM ATR in kidney and in liver slices from both species. ATR also caused a marked leakage of lactate dehydrogenase and alkaline phosphatase from both pig and rat kidney slices at all concentrations, but only lactate dehydrogenase was significantly elevated in liver slices from both species. ATR > or = 0.5 mM caused a significant increase in lipid peroxidation, but only in liver slices of both species, and > or = 0.2 mM ATR caused a marked depletion of reduced glutathione and significant increase in oxidized glutathione in both kidney and liver slices of both species. However, GSH to GSSG ratio was only significantly altered in the liver slices, indicating that oxidative stress may be the cause of toxicity in this organ. Both rat and pig tissue slices from the same organ responded similarly to ATR, although their basal biochemistry was different. ATR toxicity to both kidney and liver showed similar patterns but it appears that the mechanisms of toxicity are different. While cytotoxicity of ATR in kidney is only accompanied with GSH depletion, that of the liver is linked to both lipid peroxidation and GSH depletion. Striated muscle slices from both species were not affected by the highest ATR concentration. This further strengthens the argument that the molecular basis of ATR, target selective toxicity, is not a measure of the interaction between ATR and mitochondria and that other factors such as selective uptake are involved. Precision-cut tissue slices show organ-specific toxicity in kidney and liver from both rat and pig and suggest different mechanisms of injury for each organ.

Inhibition of mitochondrial respiration and oxygen uptake in isolated rat renal tubular fragments by atractyloside.

Atractyloside (ATR) is widely used as a specific inhibitor of mitochondrial adenine nucleotide translocase and it is also a potent nephrotoxin that selectively injures the proximal tubule in vivo. This regioselectivity has been attributed to the prominence of mitochondria in the proximal tubule cells, but there have been no investigations to confirm this. In order to better understand the molecular basis of ATR-induced renal injury, oxidative phosphorylation was studied in freshly isolated rat proximal tubular and glomeruli fragments, and in isolated rat renal cortical mitochondria. In isolated renal mitochondrial, ATR significantly inhibited state 3 respiration in a dose-dependent manner, with the maximum inhibition achieved at the highest ATR concentration. Low doses of ATR (53 microM) inhibited respiration by 50%, an effect which was reversed by 2.5 mumol ADP. 2,4-Dinitrophenol (5 mM), which stimulated respiration in control mitochondria, failed to do this in the presence of ATR. Basal oxygen consumption was significantly inhibited by ATR (> 50 microM) in proximal tubule previously incubated for 1 h at 37 degrees C. The concentration-dependent inhibition of oxygen uptake by the proximal tubule was maintained in the presence of 1 mM ouabain or 0.25 mg/ml nystatin. Glomeruli have active mitochondrial respiration (about half that of the proximal tubules), but were not affected by ATR at concentrations up to 500 microM. These data demonstrates that both purified renal mitochondria and freshly isolated fragments of the proximal tubule exposed to ATR in vitro exhibit similar alteration in respiratory parameters that demonstrate inhibition of state 3 mitochondrial respiration, but there was no significant effect on glomeruli cells. Thus, the inhibition of oxidative phosphorylation may be an early event in ATR-induced nephrotoxicity, where the prominence of mitochondria in the proximal tubule explain, in part, the localised injury. The resistance of the glomeruli suggest that preferential transport of ATR may also contribute to the sensitivity of the proximal tubule.

Selective cytotoxicity associated with in vitro exposure of fresh rat renal fragments and continuous cell lines to atractyloside.

The consumption of plants containing the diterpenoid atractyloside (ATR) causes selective proximal tubule injury, renal failure and death in humans. We have compared the effects of ATR in freshly isolated renal proximal tubules and glomeruli from rat and also in cell lines: NRK, derived from the proximal tubules, and MDBK and MDCK more closely representing the distal nephron. The effects of ATR (10-500 microM) on proximal tubules and glomeruli were assessed by changes in lipid peroxidation, de novo protein synthesis and the leakage of alkaline phosphatase (ALP), lactate dehydrogenase (LDH), glutamate dehydrogenase (GDH) and N-acetyl-beta-D-glucosaminidase (NAG). The susceptibility of NRK, MDBK and MDCK cell lines to ATR was assessed by the 3-(4,5-dimethylthiazole-2-yl)-2,5-diphenyl tetrazolium bromide (MTT) assay, measuring mitochondrial reduction. Enzyme leakage was the most sensitive of the markers of cell injury in fresh fragments and ranked LDH > GDH > ALP > NAG in proximal tubules. As little as 20 microM ATR caused significant enzyme leakage from proximal tubules, but there were no increases in enzyme leakage from glomeruli at concentrations < and = 500 microM ATR. De novo protein synthesis was only inhibited 50% at ATR concentration > 5 mM in the proximal tubules, but there were no effects in glomeruli. Malondialdehyde production was significantly elevated at 1 mM ATR for proximal tubules, and 500 microM for glomeruli. NRK cells were sensitive to ATR (IC50, 120 microM), but MDBK or MDCK cells were unaffected by < and = 1 mM of this diterpenoid. Both freshly isolated fragments and continuous cell lines representing the proximal tubules are more sensitive to ATR than either glomeruli or cells representing the distal nephron. These data also show that protein synthesis is a less specific and sensitive measure of ATR cytotoxicity than enzyme leakage in fragments. MTT reduction to formazan was the most sensitive in the NRK cell line. The low levels of lipid peroxidation products in proximal tubular fragments or sensitive renal cell lines at toxic levels of ATR suggest that oxidative injury is not a key mechanism.