Arsenic-induced neurotoxicity in relation to toxicokinetics: effects on sciatic nerve proteins.

In our previous study in rats acutely exposed to As, we observed an effect of As on neurofilaments in the sciatic nerve. This study deals with the effects of inorganic As in Wistar rats on the cytoskeletal protein composition of the sciatic nerve after subchronic intoxication. Sodium meta-arsenite (NaAsO2) dissolved in phosphate-buffered saline (PBS) was administered daily in doses of 0, 3 and 10 mg/kg body weight/day (n=9 rats/group) by intragastric route for 4, 8 and 12 week periods. Toxicokinetic measurements revealed a saturation of blood As in the 3- and 10-mg/kg dose groups at approximately 14 microg/ml, with an increase in renal clearance of As at increasing doses. After exsanguination, sciatic nerves were excised and the protein composition was analyzed. Analysis of the sciatic nerves showed compositional changes in their proteins. Protein expression of neurofilament Medium (NF-M) and High (NF-H) was unchanged. Neurofilament protein Low (NF-L) expression was reduced, while mu- and m-calpain protein expression was increased, both in a dose/time pattern. Furthermore, NF-H protein was hypophosphorylated, while NF-L and microtubule-associated protein tau (MAP-tau) proteins were (hyper)-phosphorylated. In conclusion, we show that expression of mu- and m-calpain protein is increased by exposure to As, possibly leading to increased NF-L degradation. In addition, hyperphosphorylation of NF-L and MAP-tau by As also contribute to destabilization and disruption of the cytoskeletal framework, which eventually may lead to axonal degeneration.

Comparative toxicity of arsenite metabolites in wild type CHO cells and in cells deficient in excision repair cross-complementing 1 and 2.

Arsenic (As) has been shown to alter one or more DNA repair processes. Excision repair cross-complementing 1 and 2 (ERCC1 and ERCC2) have shown to be associated with arsenic-induced toxicity and carcinogenicity. In this study, we investigated cytotoxic effects of various As metabolites in relation to two nucleotide excision repair genes: ERCC1 and ERCC2. Various arsenate (pentavalent) and arsenite (trivalent) metabolites were tested in ERCC1, ERCC2 deficient and wild type cells. Our results showed that in the selected concentration range pentavalent As metabolites; iAs(V), MMA(V) and DMA(V) were not cytotoxic, unlike the trivalent As metabolites; iAs(III), MMA(III) and DMA(III). The measured LC(50) demonstrated a significant difference (p<0.01) for iAs(III) between the three cell lines, while MMA(III) and DMA(III) are more cytotoxic to all three cell lines. UV5 (ERCC2 deficient) cells also showed a lower resistance to iAs(III) in comparison to AA8 (wild type) and UV20 (ERCC2 deficient) cells. This might be explained through the generation of hydrogen peroxide (H(2)O(2)), which is generated by increase of intracellular Ca(2+) level. Generation of H(2)O(2) in UV5 cells after incubation with iAs(III) is significantly higher than AA8 and UV20 cells (p<0.01). In conclusion, absence of ERCC2 leads to a increased generation of H(2)O(2) by iAs(III) in UV5 cells, which is in contrast to AA8 and UV20 cells.

Mechanism of arsenic-induced neurotoxicity may be explained through cleavage of p35 to p25 by calpain.

In recent studies we have demonstrated that arsenic (As) metabolites change the composition of neuronal cytoskeletal proteins in vivo and in vitro. To further examine the mechanism of arsenic-induced neurotoxicity with various arsenate metabolites (iAsV, MMAV and DMAV) and arsenite metabolites (iAsIII, MMAIII and DMAIII), we investigated the role of the proteolytic enzyme calpain and its involvement in the cleavage of p35 protein to p25, and also mRNA expression levels of calpain, cyclin-dependent kinase 5 (cdk5) and glycogen synthase kinase 3 beta (gsk3ss). A HeLa cell line transfected with a p35 construct (HeLa-p35) was used as a model, since all other proteins such as calpain, CDK5 and GSK3beta are already present in HeLa cells as they are in neuronal cells. HeLa-p35 cells were incubated with various As metabolites and concentrations of 0, 10 and 30 microM for duration of 4 h. Subsequently the cells were either lysed to study their relative quantification levels of these genes or to be examined on their p35-protein expression. P35-RNA expression levels were significantly (p<0.01) increased by arsenite metabolites, while p35 protein was cleaved to p25 (and p10) after incubation with these metabolites. The cleavage of p35 is caused by calcium (Ca2+) induced activation of calpain. Inhibition of calpain activity by calpeptin prevents cleavage of p35 to p25. These results suggest that cleavage of p35 to p25 by calpain, probably As-induced Ca2+-influx, may explain the mechanism by which arsenic induces its neurotoxic effects.

Arsenic neurotoxicity--a review.

Arsenic (As) is one of the oldest poisons known to men. Its applications throughout history are wide and varied: murder, make-up, paint and even as a pesticide. Chronic As toxicity is a global environmental health problem, affecting millions of people in the USA and Germany to Bangladesh and Taiwan. Worldwide, As is released into the environment by smelting of various metals, combustion of fossil fuels, as herbicides and fungicides in agricultural products. The drinking water in many countries, which is tapped from natural geological resources, is also contaminated as a result of the high level of As in groundwater. The environmental fate of As is contamination of surface and groundwater with a contaminant level higher than 10 particle per billion (ppb) as set by World Health Organization (WHO). Arsenic exists in both organic and inorganic species and either form can also exist in a trivalent or pentavalent oxidation state. Long-term health effects of exposure to these As metabolites are severe and highly variable: skin and lung cancer, neurological effects, hypertension and cardiovascular diseases. Neurological effects of As may develop within a few hours after ingestion, but usually are seen in 2-8 weeks after exposure. It is usually a symmetrical sensorimotor neuropathy, often resembling the Guillain-Barré syndrome. The predominant clinical features of neuropathy are paresthesias, numbness and pain, particularly in the soles of the feet. Electrophysiological studies performed on patients with As neuropathy have revealed a reduced nerve conduction velocity, typical of those seen in axonal degeneration. Most of the adverse effects of As, are caused by inactivated enzymes in the cellular energy pathway, whereby As reacts with the thiol groups of proteins and enzymes and inhibits their catalytic activity. Furthermore, As-induced neurotoxicity, like many other neurodegenerative diseases, causes changes in cytoskeletal protein composition and hyperphosphorylation. These changes may lead to disorganization of the cytoskeletal framework, which is a potential mechanism of As-induced neurotoxicity.

Arsenic metabolites affect expression of the neurofilament and tau genes: an in-vitro study into the mechanism of arsenic neurotoxicity.

Neurological studies indicate that the central (CNS) and peripheral nervous system (PNS) may be affected by arsenic (As). As-exposed patients show significantly lower nerve conduction velocities (NCVs) in their peripheral nerves in comparison to healthy subjects. As may play a role in the disruption of neuroskeletal integrity, but the mechanisms by which it exerts a toxic effect on the peripheral and central nervous system are still unclear. In the present study, we examined the neurotoxic effects of various arsenic metabolites (iAs(III), iAs(V), MMA(V) and DMA(V)) on two different cell lines derived from the peripheral (ST-8814) and central (SK-N-SH) nervous system. The effects of the arsenic metabolites were examined on the relative quantification levels of the cytoskeletal genes, neurofilament-light (NEFL), neurofilament-medium (NEF3), neurofilament-heavy (NEFH) and microtubule-associated protein-tau (MAPT), using real-time PCR. Our results show that iAs(III) and iAs(V) have no significant effects on either cell lines. On the other hand, MMA(V) and DMA(V) cause significant changes in expression levels of NEF3 and NEFL genes, while the expression level of the NEFH gene is significantly increased in both cell lines.

Arsenic-induced toxicity: effect on protein composition in sciatic nerve.

Exposure to arsenic compounds may lead to skin and lung cancer and various disorders such as vascular disease and peripheral neuropathy in humans. Peripheral arsenic neurotoxicity has been demonstrated clinically and in electrophysiological studies. Patients intoxicated with arsenic show neurological symptoms in their feet and hands. These patients show significantly lower nerve conduction velocities (NCVs) in their peripheral nerves in comparison with controls. The mechanism of arsenic peripheral nervous system (PNS) toxicity, however, has never been described before. This is the first study to investigate the toxicity of arsenic on the PNS. Male Wistar rats were exposed to arsenite given as a single dose i.v. After sacrifice, sciatic nerves were excised and the protein composition was analysed. Protein analysis of sciatic nerves showed disappearance of neurofilament and fibroblast proteins in rats treated with arsenite doses of 15 and 20 mg/kg in comparison with the control groups. Some fibroblast protein bands had disappeared in the 20-mg/kg dose group. The analysed neurofilament-M and -L proteins decreased dose dependency over time. arsenic affects the composition of proteins in the rat sciatic nerve, especially the neurofilaments. The reduction of signals in Western blot analysis reveals changes in cytoskeletal composition, which may well lead to neurotoxic effects in vivo.

Complex cardiac defect with hypoplastic right ventricle in a fetus with valproate exposure.

We describe a fetus with a hypoplastic right ventricle detected by prenatal ultrasound examination. A possible causal relationship with prenatal valproate exposure is discussed.

Loss of homotypic epithelial cell adhesion by selective N-cadherin displacement in bismuth nephrotoxicity.

The nephrotoxicity of single high doses of bismuth (Bi)-containing therapeutic drugs is characterized morphologically by detachment of proximal tubular epithelial cells (PTECs) from each other, followed by cell death. We investigated whether Bi nephrotoxicity is mediated by changes in the distribution of proteins involved in intercellular adhesion. A nephrotoxic dose of colloidal bismuth subcitrate (CBS; 3.0 mmol Bi/kg) was orally administrated to 10 female Wistar rats. After 1 h, N-cadherin had disappeared from the adherence junctions of vital PTECs, whereas ZO-1, a tight junction marker, remained present at the cell-cell border until cell death occurred after 3 h. E-Cadherin, absent in PTECs, remained absent. Exposure of the renal epithelial cell lines NRK-52E and LLC-PK1 to 400 microM Bi(3+) also resulted in the disappearance of N-cadherin expression after 1 h, whereas ZO-1, E-cadherin, and Desmoplakin expression did not resolve before cell death at 24 h, thus confirming in vivo results. Our results are the first to indicate that Bi-induced death of PTECs is preceded by redistribution of N-cadherin and the disruption of homotypic cell adhesion.

Bismuth overdosing-induced reversible nephropathy in rats.

Overdosing of colloidal bismuth subcitrate (CBS), used to treat peptic ulcers and Helicobacter pylori infections, has been reported to result in serious, though reversible, nephrotoxicity in humans. However, little is known about the nature of the renal damage induced by bismuth (Bi), and no well-described experimental model exists. Single large oral CBS doses (0.75, 1.5, and 3.0 mmol Bi/kg) were administered to three groups of 20 female Wistar rats. A control group (n = 20) received only the vehicle. Standard kidney function parameters, urinary excretion of N-acetyl-beta-D-glucosaminidase (NAG) and the Bi content were monitored in blood, urine, liver, and kidneys for 14 days. A dose of 3.0 mmol Bi/kg, 100 times the daily therapeutic dose, caused kidney damage within 6 h as detected by proteinuria, glucosuria, and elevated plasma urea and plasma creatinine levels. The kidneys of all animals, except two that died, recovered functionally within 10 days. At a dose of 1.5 mmol Bi/kg, clinical parameters changed less and normalized within 48 h, whereas a dose of 0.75 mmol Bi/kg induced no changes. Histological evaluation revealed that the S3 tubular segment necrotized first with additional necrotization of the S1/S2 segment when more Bi was absorbed. The lesions were accompanied by interstitial infiltrates of CD45+ leukocytes. In summary, we developed a rat model for Bi-induced reversible nephropathy. A large single oral overdose of CBS administered to Wistar rats led to damage to the proximal tubule, especially in the last segment.

Bismuth biokinetics and kidney histopathology after bismuth overdose in rats.

Bismuth induced nephrotoxicity has been reported to occur after acute overdoses of Bi-containing therapeutic drugs. We studied the development of bismuth induced nephropathy and bismuth biokinetics in rats. Bismuth nephropathy was induced in 33 young adult female Wistar rats weighing ca. 175 g by feeding them a single overdose of colloidal bismuth subcitrate containing 3.0 mmol Bi/kg at (t = 0). Control animals (n = 7) were fed the vehicle only. The animals were sacrificed after 1-48 h. Plasma creatinine increased from 51 +/- 6 micromol/l at t = 0 to 550 +/- 250 micromol/l after 48 h in the experimental group. The S3 segment of the proximal tubule showed epithelial cell vacuolation after 1 h and necrosis after 3 h. Cells of the S1/S2 segment demonstrated vacuolation after 6 h and necrosis after 12 h. Biokinetics of bismuth in blood could best be described with a one-compartment model characterized by an absorption half-life of 0.32 h and an elimination halflife of 16 h. The peak concentration of about 7.0 mg Bi/l was reached after 2 h. In conclusion, cells of the S3 segment of the proximal tubule necrotized first after an oral colloidal bismuth subcitrate overdose and biokinetics of Bi in blood was best described by a one-compartment model.

Fluoride enhances the effect of aluminium chloride on interconnections between aggregates of hippocampal neurons.

The role of fluoride in aluminium neurotoxicity was studied using an in vitro system of cultured hippocampal neurons from foetal rats. Sodium fluoride (50 microM) and aluminium chloride (12.5 microM) were administered alone or in a specific combination (50 + 12.5 microM) in a 14-day culture in a chemically defined medium before staining of neurofilaments. Neuronal aggregates interconnected by neuritic fibers were detected light microscopically in control cultures. The aggregates and the fibers stained positive for neurofilament proteins. In cultures treated with aluminium chloride the development of the interconnecting fibers was affected, resulting in a fusion pattern of the aggregates. This phenomenon was enhanced when sodium fluoride was given together with aluminum chloride. It was concluded that aluminium interferes with the metabolism of the neuronal cytoskeleton and that this interference is potentiated by fluoride.

Mercury exposure of maroon workers in the small scale gold mining in Suriname.

Suriname is experiencing a revival of small scale gold mining activities, with about 10,000 to 15,000 workers involved in 1996. The estimated production in 1995 is at least 10,000 kg crude gold. Gold is extracted with mercury and methods used are comparable with those described for gold mining in the Amazon Basin. Since no data exist on the internal mercury exposure of workers in Suriname a study was performed. A group of mercury-exposed Maroons, who are principally involved in the mining located in the tropical rainforest, is compared with nonexposed Maroons living in a non-gold mining area. Blood and urine samples of both groups were analyzed for total mercury using an atomic absorption spectrometer with an FIAS hydride system. In the study 28 exposed and 17 controls with a comparable mean age (P=0.544; exposed 27+/-7.2 years, n=26; controls 26+/-7.7 years, n=17), all males, participated. The urine levels for both groups differ statistically significantly from each other (P<0.001; exposed mean 27.5+/-21.1 microg/g creatinine; controls mean 5. 2+/-2.9 microg/g creatinine). This is, however, not the case with the blood levels (P=0.036: exposed mean 18.1+/-11.0 microg/L, n=25; controls mean 26.8+/-14.6 microg/L, n=16). In contrast with blood the urine total mercury levels in this study confirm, on a group basis, exposure to mercury as described for individuals working in the gold mining in the Amazon Basin.

Comparison of enhanced elimination of bismuth in humans after treatment with meso-2,3-dimercaptosuccinic acid and D,L-2,3-dimercaptopropane-1-sulfonic acid.

Two groups of 12 human volunteers, who had been treated with colloidal bismuth subcitrate, because of Helicobacter pylori-associated gastritis, participated in the study. The patients received a single dose of meso-2,3-dimercaptosuccinic acid (DMSA) or D,L-2,3-dimercaptopropane-1-sulfonic acid (DMPS) at a dose of 30 mg kg-1 in a randomized single blind study. In contrast to DMPS, increasing concentrations of bismuth in blood were observed during the first 4 h after intake of DMSA. In urine, both chelators induced a 50-fold increase in urinary bismuth excretion compared with the control urines. The treatment was well tolerated. The results indicate that both DMSA and DMPS effectively increase the elimination of bismuth in human urine. Consequently, both chelators may be of benefit in the treatment of patients with bismuth intoxication.

Intestinal absorption of aluminum: effect of sodium and calcium.

Aluminum (Al) is recognized as a toxin in patients with deficient renal function. Moreover, Al may play a role in some neurodegenerative diseases. It is hypothesized that more than one intestinal absorption mechanism exists for Al, related to various intraluminal chemical species, and that Al shares intestinal transport routes for essential inorganic substances due to similarities in their chemical speciation characteristics. The purpose of the present investigation was to study the effects of ionic Na (0-120 mmol/l) and Ca (0-10 mmol/l), alone and in combination, on the intestinal absorption of ionic Al (20 and 30 mmol/l). A previously standardized method of perfusion of rat small intestine was used, combined with serial blood sampling. Mucosal uptake and systemic appearance of Al in the blood were monitored during 1 h perfusion, together with Na and Ca; the metals were given as the chloride. The intestinal absorption of Na and Ca was taking place according to previously reported mechanisms. A one-sided negative interaction was shown to exist between Ca and Al resp. Al and Na during both mucosal uptake and systemic appearance; Ca interacts negatively with Na during systemic appearance, but enhances mucosal uptake of Na. It may be speculated that Al mimicks Ca in its Na-dependent intestinal passage.

Serum aluminium levels of workers in the bauxite mines.

BACKGROUND/OBJECTIVE: Aluminium is produced from the mineral bauxite. Occupational exposure is reported during the industrial processing of aluminium and is associated with pulmonary and neurotoxicity. However, data on exposure and toxicity of workers in the open bauxite mining industry do not exist. Therefore, a study was performed to explore aluminium exposure in employees involved in this bauxite mining process in a Surinam mine. METHODS/DESIGN: A group of workers occupationally exposed to aluminium in an open bauxite mine were compared with a group of nonexposed wood processors. Serum aluminium was analyzed using atomic absorption spectrometry Data from the clinical chemistry of the blood and a questionnaire were used to explore determinants for aluminium exposure. RESULTS: No significant difference between serum aluminium in the exposed (4.4 +/- 2.0 micrograms/L, n = 27) and control group (5.1 +/- 1.5 micrograms/L, n = 27) was detected. For the serum concentration of the clinical chemical variables (calcium, citrate, and creatinine), a statistically significant difference was computed (p < or = 0.02) between the exposed and control group. All levels were slightly higher in the exposed group; no statistically significant correlations with serum aluminium were found. CONCLUSIONS: In this study, serum aluminium values were in the normal range, no significant difference between the groups could be detected despite long-term occupational exposure.

Idiopathic haemochromatosis: magnetic resonance signal intensity ratios permit non-invasive diagnosis of low levels of iron overload.

OBJECTIVE: The detection of low levels of iron overload by magnetic resonance imaging. METHODS: Eight consecutive patients suspected of having idiopathic haemochromatosis. Comparison of signal intensity ratios and absolute iron content of liver. RESULTS: There was a good correlation between the signal intensity ratios and iron content in the range 2-30 micrograms Fe/mg dry weight. CONCLUSIONS: The ability of a non-invasive technique to detect low levels of iron overload could be useful in the assessment of therapy and in the screening of relatives of probands with idiopathic haemochromatosis.

Absorption of bismuth from several bismuth compounds during in vivo perfusion of rat small intestine.

Evaluation of the amount of bismuth (Bi) absorbed from the gastrointestinal tract is important for assessment of the possible risks associated with the use of Bi compounds in the treatment of gastrointestinal disorders. We compared the absorption of Bi from media containing the equivalent of 1 g of elemental Bi from either Bi subnitrate (BSN), Bi subsalicylate (BSS), colloidal Bi subcitrate (CBS), Bi chloride (BiCl3), or Bi citrate (BCit) by an in vivo perfusion system of rat small intestine. The intestinal absorption was < 1% for all compounds, but higher from BCit and CBS than from BSN, BSS, and BiCl3. The dose dependency of Bi absorption from both CBS and BiCl3 in citrate buffer showed a nonlinear relationship between the concentration of Bi in perfusate and the concentration of Bi in blood after 60 min.

Effect of citric acid and maltol on the accumulation of aluminum in rat brain and bone.

Deposition of aluminum in the body is responsible for the development of dialysis-related diseases in patients with renal dysfunction and may play a role in the development of certain neurodegenerative disorders. Although citric acid is known to be a strong enhancer of gastrointestinal absorption of aluminum, its effect on aluminum distribution and accumulation is not yet clear. Maltol has been shown to increase the neurotoxicity of aluminum, but little is known about its effect on aluminum deposition in the body. To elucidate the role of citric acid and maltol in aluminum accumulation and toxicity, rats were loaded intraperitoneally during a 7-day period with different amounts of aluminum chloride in absence or presence of citric acid or maltol before analysis of aluminum in serum, brain, bone, and urine. Coadministration of citric acid led to relatively reduced serum levels, as compared with aluminum and aluminum-maltol treatment. This is explained by both tissue elimination and enhanced renal elimination. Only at the highest aluminum dose (8 mg/kg body weight) was an enhancing effect of citric acid on accumulation of aluminum in brain observed; no effect on bone aluminum was seen. Furthermore, it was seen that citric acid alters the distribution pattern of aluminum. This may be explained by the postulation of a characteristic aluminum citrate species in serum. Administration of citric acid may increase this aluminum fraction in serum, thereby inducing an alteration of the distribution pattern. Maltol was shown to be a strong enhancer of aluminum accumulation in serum, brain, and bone. The rise of aluminum in these target tissues was dose dependent.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of aluminum chloride, -citrate, and -maltol on the calcium-mediated degradation of neurofilament proteins.

Aluminum (Al) has been observed to cause neurofilament protein accumulation in both experimental animals and cultured cells. Impairment of axonal transport is thought to be a mechanism of toxicity. Inhibition of the degradation of neurofilament proteins, however, resulting in accumulation of these proteins may be an alternative mechanism for Al toxicity. In the present study, the effect of calcium (Ca) on the proteolysis of the neurofilament triplet proteins by calcium-activated neutral proteases (CANP) was studied in the isolated sciatic nerve explants. The extent of the degradation was found to be dependent on the Ca concentration. The effect of Al chloride, -citrate and -maltol on the calcium-induced degradation was studied. No effect of any of the Al compounds was observed, suggesting that the metal may exert its neurotoxic effect via a mechanism other than impairment of neurofilament proteolysis. Maltol itself was found to enhance the effect of Ca on the degradation of neurofilament proteins, probably by facilitating the movement of Ca across the neuronal membrane.