Influence of several chelating agents on the distribution and binding of cadmium in rats

Kinetics of the early subcellular distribution of cadmium in rat hepatocytes

The kinetics of the early subcellular distribution of cadmium (Cd) was characterized in primary cultures of rat hepatocytes exposed to 10, 50 and 100 microM Cd in a serum-free WME medium for 10, 30 or 60 min. Our results demonstrate a time- and concentration-dependent increase in Cd content with the highest metal concentration measured in the cytosol, whereas the lowest was observed in the mitochondria. With the exception of early localization in the plasma membrane, Cd concentrations in fractions were characterized by the following decreasing order of magnitude: cytosol > low density molecules approximately nuclei > lysosomes approximately mitochondria. We also found evidence for: (i) a two-step process for Cd distribution in the nuclei and mitochondria; and (ii) a time-dependent 'slow' process of transfer from the plasma membrane to the cytosol. Saturation in Cd uptake was observed at 50 microM in most cell fractions at 10 and 30 min, except for the plasma membrane. The lack of apparent saturation for Cd accumulation at 60 min was not related to an increase in metallothionein synthesis. Altogether, our data provide insights into the dynamics of transfer between intracellular compartments, and allow a better identification of the organelles that are the most subjected to Cd toxicity for early exposure conditions.

Combined Early Treatment with Chelating Agents DMSA and CaDTPA in Acute Oral Cadmium Exposure

The influence of chelating agents: meso-2,3-dimercaptosuccinic acid (DMSA); calcium trisodium diethylenetriaminepentaacetate (CaDTPA) and their combination on mobilisation of cadmium (Cd) was compared in female albino rats. After oral Cd administration chelators were applied either orally (DMSA) or intraperitoneally (CaDTPA) at various short time intervals after Cd. Three experiments were carried out with four treatment groups in each: 1) Cd (control); 2) Cd+DMSA; 3) Cd+CaDTPA; 4) Cd+DMSA+CaDTPA. Time intervals for chelator treatment after Cd administration were: immediate application in the first, half an hour in the second and one hour in the third experiment. At the end of each experiment cadmium was analysed in kidney and liver. Additionally in experiment 3 essential elements (Fe, Cu, Zn) were also determined in the same organs. In experiment 2 the effect of the treatment on urinary elimination of cadmium, copper and zinc were analysed. Results showed that the efficiency of Cd removal from the body (kidneys and liver) is lower when the time between Cd and chelating agents administration is longer. The two chelators differ in efficiency in mobilizing Cd, with DMSA being more efficient than CaDTPA. The combined therapy with the two chelators gave generally better results. It seems that DMSA which is given orally after oral Cd administration removes this element very efficiently from the gastrointestinal tract. CaDTPA, however, which is given parenterally removes absorbed Cd less efficiently, Organs are not significantly depleted in iron and copper after chelation treatment. Only zinc concentration was, however, significantly lower in the liver and higher in kidneys only after CaDTPA and combined DMSA+CaDTPA chelation.

Effects of dithiocarbamates and cadmium on the enzymatic activities in liver, kidney and blood of mice

The effects of N-benzyl-D-glucamine dithiocarbamate (BGD), diethyldithiocarbamate (DDTC), and N-p-hydroxymethylbenzyl-D-glucamine dithiocarbamate (HBGD) on the enzymatic activities in mice were studied. The mice were given i.v. injections of these chelating agents (1 mmol/kg) and 3 h later the activities of aspartate aminotransferase (AST), alanine aminotransferase (ALT), gamma-glutamyltranspeptidase (gamma-GTP), alkaline phosphatase (ALP), leucine aminopeptidase (LAP), and cholinesterase (ChE) in the liver, kidney, and blood were determined. These enzymatic activities were little changed by treatment with these chelating agents. Cadmium (Cd) administration markedly decreased the activities of AST and ALT in the liver and kidney and greatly increased these enzymatic activities in blood. The changes in the enzymatic activities by treatment with Cd were prevented by injection of BGD (1 mmol/kg). These results indicate that BGD, DDTC, and HBGD were not toxic to the liver or kidney of mice and that BGD treatment protected against the acute hepatic and renal toxicity induced by Cd.

Carbodithioate MeOBDCG for decreasing intracellular cadmium deposits in rats of different ages

The efficiency of chelating agents to remove aged intracellular deposits of cadmium in young and older rats was studied. The administration of the chelating agent sodium N-(4-methoxybenzyl)-D-glucamine-N-carbodithioate monohydrate (MeOBDCG) 2 wk after a single intraperitoneal 115m Cd administration reduced the whole body, liver, and kidney retention in suckling rats to about 63, 42, and 71 percent and in older rats to 39, 17, and 76 percent of values obtained in respective controls. Chelation therapy was generally more effective in older than younger rats and the age-related effect was most pronounced in the liver. These results indicate that specific features of young organisms may significantly alter the effect of chelation treatment.

Mobilization of cadmium by liposome-encapsulated meso-2,3-dimercaptosuccinic acid in pre-exposed mice

meso-2,3-Dimercaptosuccinic acid (DMSA) treatment in free of liposome-encapsulated form was given to mice pre-exposed to cadmium as CdCl2 (2 intraperitoneal injections; 0.5 mg Cd/kg along with 5 microCi 109CdCl2 in 4 ml volume within 24 h). Both treatments removed cadmium from liver, spleen, testis and blood with liposomal DMSA exhibiting higher efficacy in mobilizing cadmium not only from whole organs but also from liver proteins. It also resulted in higher excretion of cadmium via urine as compared with free DMSA or saline treatment. Whereas this treatment eliminated significantly higher amounts of cadmium via the fecal route throughout the period examined, free DMSA responded only 48 h after treatment and was less effective. The results suggest mobilization of cadmium from intracellular sites of deposition. However, DMSA in the dose administered (24 mumol/kg i.v.) in either form was ineffective in decorporating cadmium from the kidney, the critical organ in cadmium intoxication.

Effects of chelating agents on the cadmium burden of cells in culture

The effects of some new chelating agents on the cadmium burden of CHO cells in culture were investigated. The chelators were sodium-N-(4-methoxybenzyl)-D-glucamine-dithiocarbamate (MeOBG-DTC), sodium-N-benzyl-D-glucaminedithiocarbamate (BG-DTC) and diisopropylmeso-2,3-dimercapto succinate (DiP-DMSA). The results were compared with the effect of the well known dimercaptopropanol (BAL). The derivates of dithiocarbamate are much less toxic than DiP-DMSA and BAL. All chelators effectively prevent Cd uptake into the cells. Mobilization of intracellular Cd, however, is more effective by the DTC-derivatives than by DiP-DMSA or BAL. Within the cell the major fraction of Cd after 48 hours incubation is found in the nuclei and cytosol and very little in the peroxisomes. The chelating agents remove the metal mostly from nuclei and cytosol. Incubation of the cells with cadmium leads to the induction of a Cd binding protein of an apparent molecular weight of 12500 Da, presumably metallothionein. MeOBG-DTC is more effective in removing the metal from this protein than BG-DTC.

Effects of vitamin B12 on cadmium toxicity in rats

The survival rate was high among male Sprague rats treated with 0.15 mg/kg vitamin B12 (cyanocobalamine) after injection of 5 mg/kg CdCl2.H2O (LD50). The cadmium content of the liver and, for some protocols, in the kidney was significantly reduced in survivors. According to UV-V and multinuclear (1H, 13C, 31P, and 113Cd) magnetic resonance spectroscopy no direct interaction seems to take place between cyanocobalamine and CdCl2 in aqueous solution at pH 4.5. An indirect mechanism is put forward to explain the antidotal activity.

Intracellular cadmium mobilization sequelae

The consequences of the mobilization of aged intracellular cadmium from its in vivo deposits in mice by chelating agents were examined. The chelating agents used were BAL, sodium N-benzyl-D-glucamine dithiocarbamate (NaB), Diisopropyl meso-2,3-dimercaptosuccinate(Di-PDMS) and sodium N-(4-methoxybenzyl)-D-glucamine dithiocarbamate(4-Me0), all previously shown capable of causing statistically significant decreases in either renal or hepatic cadmium burdens in rodents. They were given at a level of 400 mumol/kg (i.p.) daily for 10 days to mice previously loaded with a total of 10 mg CdCl2.2.5 H2O/kg. Under these conditions a significant decrease in the renal cadmium level occurred following treatment with BAL, NaB, and 4-MeO; hepatic cadmium levels decreased significantly following treatment with NaB and 4-MeO. Pathological examination of the kidneys, liver, and testes in these animals showed that chelate mobilization of the cadmium produced no noticeable changes in the histopathology of these organs in comparison with that observed for the animals which had been given only cadmium and had undergone no chelate treatment. The results suggest that the mobilization of such aged cadmium from in vivo deposits need not result in any deleterious changes in the kidneys, liver or testes.

Comparison of effectiveness of 3 dithiocarbamates on excretion and distribution of cadmium in rats and mice

Sodium N-benzyl-D-glucamine dithiocarbamate (BGD), sodium N-p-methylbenzyl-D-glucamine dithiocarbamate (MBGD), and sodium N-p-isopropylbenzyl-D-glucamine dithiocarbamate (PBGD), which were recently synthesized, were evaluated for their efficacy in the distribution and excretion of cadmium in rats and mice exposed to cadmium. Rats and mice were injected i.p. with 109CdCl2 (1 mg Cd/kg and 2 microCi 109Cd/one animal) and 3 days later, they were treated with the dithiocarbamates (400 mumol/kg) every other day for 2 weeks. These dithiocarbamates were effective in removing cadmium from the body without increasing the cadmium content in the kidney. After treatment with BGD, MBGD, and PBGD, cadmium was excreted mainly in the feces and the effect of MBGD and PBGD on the fecal excretion of cadmium was much larger than that of BGD. The treatment with these dithiocarbamates did not cause the redistribution of cadmium to brain, testes, and heart in rats and mice. The treatment of mice with PBGD decreased the concentrations of essential metals in liver, kidney, and brain. The extent of acute toxicity of the dithiocarbamates in mice was in the order PBGD greater than MBGD greater than BGD.

Effect of chelating agent structure on the mobilization of cadmium from intracellular deposits

An examination of the efficacy of several structural types of chelating agents in the removal of cadmium from its intracellular deposits in mouse liver and kidneys reveals that of the structural types examined, only dithiocarbamates and a vicinal dithiol were able to mobilize cadmium from such intracellular sites. Esters of L-cysteine, a macrocyclic thioether, and a disulfide of a dithiocarbamate were unable to cause any appreciable decrease in either renal or hepatic cadmium levels. Charged groups such as carboxylic acid groups reduce the efficacy as well as the toxicity of the structural types that can otherwise mobilize such cadmium. It was also found that the administration of a cadmium-binding polymer ip leads to only a very slight net excretion of cadmium, while the po administration of this polymer leads to no net additional cadmium excretion. Of the compounds newly reported here, some are approximately equal in cadmium-mobilizing efficacy to the most effective of previously reported compounds.

Mechanistic aspects of the dithiocarbamate-induced mobilization of cadmium

The examination of some of the species involved in the in vivo processes in which dithiocarbamates mobilize cadmium from its intracellular deposits indicates that several competing reactions occur. Rates of hydrolytic decomposition of a series of dithiocarbamates capable of mobilizing cadmium in vivo have been determined, and the solubility behavior and nuclear magnetic resonance (NMR) spectra of their cadmium complexes have been examined. Some of the dithiocarbamates most effective in this mobilization process are shown to undergo slow conversion to oxazolidine-2-thiones in the presence of cadmium. All of the cadmium complexes involved in the mobilization process are shown to undergo rapid ligand exchange. While dissociative mechanisms based on the turnover of metallothionein are inconsistent with the experimental data, at least two associative mechanisms are possible. These involve attack on the metallothionein by the dithiocarbamate itself or by a compound derived from it by known metabolic processes.

Chelation in metal intoxication XXX: Alpha-mercapto-beta-aryl acrylic acids as antidotes to cadmium toxicity

alpha-Mercapto-beta-(2-furyl) acrylic acid (MFA), alpha-mercapto-beta-(2-hydroxyphenyl) acrylic acid (MHA), beta-1,2-phenylene di-alpha-mercaptoacrylic acid (1,2-PDMA) and beta-1,4-phenylene di-alpha-mercapto acrylic acid (1,4-PDMA) were compared to sodium N-benzyl-D-glucamine dithiocarbamate (NBG-DTC) an effective cadmium chelator, for their ability to mobilize Cd and influence the Cd induced tissue metallothionein (MT) in rats administered 109CdCl2, 72 hr earlier. MFA was almost as effective as NBG-DTC but more effective than MHA in enhancing urinary and faecal excretion of Cd, reducing tissue and blood levels of Cd and in lowering Cd induced increase in hepatic and renal MT contents. 1,2-PDMA and 1,4-PDMA were effective only in reducing the hepatic burden of Cd. The resuls do not indicate any direct relationship between the efficacy of alpha-mercapto-beta-aryl acrylic acids to decorporate body Cd and their lipophilic-hydrophilic character or number-arrangement of their sulfhydryl groups.

The mobilization of intracellular cadmium by butyl and amyl esters of meso-2,3-dimercaptosuccinic acid

The esters of the general structure, [CH(SH)COOR]2, i.e., Di-BDMS, R = CH2CH(CH3)2; Ds-BDMS, R = CH(CH3)CH2CH3; Di-ADMS, R = CH2CH2CH(CH3)2; and D3-ADMS, R = CH(CH2CH3)2 from the reaction of meso-2,3-dimercaptosuccinic acid with isobutyl, sec-butyl, isoamyl, and 3-amyl alcohols, respectively, have been prepared, characterized, and examined as chelating agents for the removal of cadmium from its aged intracellular deposits. All of these compounds depleted cadmium from such deposits and significantly reduced the whole body levels of cadmium. In the case of three (Ds-BDMS, Di-BDMS, and Di-ADMS) of these compounds, the reductions achieved are equal to or greater than that produced by 2,3-dimercapto-1-propanol (BAL) under similar circumstances. None of these compounds caused any redistribution of cadmium to the brain, and two of them (Di-BDMS and Di-ADMS) caused a very much larger reduction in the liver levels of cadmium than BAL. None was as effective as BAL in reducing kidney levels of cadmium. These compounds are not soluble in water and are administered as solutions in peanut oil. A comparison of the behavior of these compounds with others which have been reported to be effective in reducing body burdens of cadmium in chronic cadmium intoxication reveals that they are among the most effective. An analysis of the manner in which mobilizing efficacy changes with structure indicates that higher, purely alkyl analogs are not expected to be superior to these compounds, though other structural variations may be.

Two models for screening chelating agents for cadmium removal

The effectiveness of some chelating agents to mobilize cadmium from Chinese hamster ovary cells after chronic exposure (20 hr), as well as from cytosolic metallothionein, was studied. In the first protocol, the most effective substance was 2,3-dimercaptopropanol, followed by 2,3-dimercaptopropane-1-sulfonate and 2,3-dimercaptosuccinic acid, whereas CaNa3-diethylenetriamine pentaacetic acid X 5 H2O showed less effect. Simultaneous incubation of cells with cadmium and the chelating agent resulted in a different order of effectiveness: CaNa3 DTPA prevented cadmium uptake almost totally, 2,3-mercaptopropanol by 75% and 2,3-dimercaptopropane-1-sulfonate by 35%. Neither CaNa3-diethylenetriamine pentaacetic acid X 5 H2O nor 2,3-dimercaptosuccinic acid had altered the distribution of cadmium between the cytosolic protein fractions after a 2 hr incubation of cells, whereas after this period, 2,3-dimercaptopropanol had removed all cadmium from metallothionein, and 2,3-dimercaptopropane-1-sulfonate about 50%. None of the chelating agents had reduced the amount of Cd bound to high molecular weight proteins. In the cell-free system, 2,3-dimercaptopropanol and 2,3-dimercaptopropane-1-sulfonate were equally effective and removed all cadmium from metallothionein within ten minutes. CaNa3-diethylenetriamine pentaacetic acid X 5 H2O, however, even after 60 min, had removed only 50% of the cadmium. The remaining cadmium was found distributed to the high molecular weight and lower molecular weight protein fractions.

Factors influencing the uptake of cadmium into cells in vitro

The uptake of cadmium was studied in Chinese Hamster Ovary (CHO) cells. Cadmium accumulates rapidly against a concentration gradient and uptake is dependent on incubation temperature. The presence of serum or albumin results in a reduction in Cd uptake. Several substances known to influence certain metabolic steps of cell metabolism were used to influence Cd accumulation. Of these compounds, those that blocked the SH groups of the plasma membrane exerted the strongest influence. The effect of inhibitors of endocytosis was less pronounced.

Esters of meso-dimercaptosuccinic acid as cadmium-mobilizing agents

The dimethyl, diethyl, di-n-propyl, diisopropyl (Di-PDMS), and di-n-butyl esters of meso-2,3-dimercaptosuccinic acid were prepared by esterification of the parent acid and were subsequently purified and characterized. Their relative ability to mobilize cadmium from its aged (greater than 30 days) deposits was evaluated in mice in comparison with 2,3-dimercapto-1-propanol (BAL). All but the dimethyl ester were superior to BAL in reducing the hepatic cadmium levels, though none was superior in reducing renal cadmium levels. Their efficacy in reducing hepatic cadmium levels had the result that all except the dimethyl ester were significantly more effective than BAL in reducing total cadmium body burdens in mice. The most effective of these compounds, Di-PDMS, caused a reduction of whole body cadmium of 59% (i.e., to 41% of control values) under conditions where the corresponding reduction found for BAL was only 18% (i.e., to 82% of control value). The predominant route of excretion of cadmium subsequent to administration of these compounds is via the fecal route (greater than 99%). A synergistic effect was found in the reduction of whole body and kidney cadmium burdens when Di-PDMS was used in combination with trisodium calcium diethylenethriaminepentaacetate.