Cellular cadmium uptake mediated by the transport system for manganese

A soybean based-diet prevents Cadmium access to rat cerebellum, maintaining trace elements homeostasis and avoiding morphological alterations

Cadmium (Cd) is one of the most dangerous heavy metals that exists. A prolonged exposure to Cd causes toxic effects in a variety of tissues, including Central Nervous System (CNS), where it can penetrate the Blood Brain Barrier (BBB). Cd exposure has been linked to neurotoxicity and neurodegenerative diseases. Soy isoflavones have a strong antioxidant capacity, and they have been shown to have positive effects on cognitive function in females. However, the mechanisms underlying Cd neurotoxicity remain completely unresolved. The purpose of this study was to characterize the potential protective effect of a soy-based diet vs. a casein-based diet against Cd toxicity in rat cerebellum. Female Wistar rats were fed with casein (Cas) or soybean (So) as protein sources for 60 days. Simultaneously, half of the animals were administered either 15 ppm of Cadmium (CasCd and SoCd groups) in water or regular tap water as control (Cas and So groups). We analyzed Cd exposure effects on trace elements, oxidative stress, cell death markers, GFAP expression and the histoarchitecture of rat cerebellum. We found that Cd tissue content only augmented in the Cas intoxicated group. Zn, Cu, Mn and Se levels showed modifications among the different diets. Expression of Nrf-2 and the activities of CAT and GPx decreased in Cas and So intoxicated groups,while 3-NT expression increased only in the CasCd group. Morphometry analyses revealed alterations in the purkinje and granular cells morphology, decreased number of granular cells and reduced thickness of the granular layer in Cd-intoxicated rats, whereas no alterations were observed in animals under a So diet. In addition, mRNA expression of apoptotic markers BAX/Bcl-2 ratio and p53 expression increased only in the CasCd group, a finding confirmed by positive TUNEL staining in the cerebellum granule cell layer in the same group. Also, Cd intoxication elicited overexpression of GFAP by astrocytes, which was prevented by soy. White matter alterations were only subtle and characterized by intramyelinic edema in the CasCd group. Overall, these results unmask an irreversible toxic effect of a subchronic Cd intoxication on the cerebellum, and identify a protective role by a soy-based diet with potential as a therapeutic strategy for those individuals exposed to this dangerous environmental contaminant.

MhNRAMP1 From Malus hupehensis Exacerbates Cell Death by Accelerating Cd Uptake in Tobacco and Apple Calli

Excessive cadmium (Cd) damages plants by causing cell death. The present study discusses the function of natural resistance-associated macrophage protein (NRAMP) on cell death caused by Cd in Malus hupehensis. MhNRAMP1 was isolated from M. hupehensis roots, and its protein was located in the cell membrane as a transmembrane protein characterized by hydrophobicity. MhNRAMP1 expression in the roots was induced by Cd stress and calcium (Ca) deficiency. MhNRAMP1 overexpression increased Cd concentration in yeasts and enhanced their sensitivity to Cd. Phenotypic comparisons of plants under Cd stress revealed that the growth of transgenic tobacco and apple calli overexpressing MhNRAMP1 was worse than that of the wild type (WT). The Cd²⁺ influx of transgenic tobacco roots and apple calli was higher, and the recovery time of the Cd²⁺ influx to a stable state in transgenic apple calli was longer than that of the WT. Cd accumulation and the percentage of apoptotic cells in transgenic lines were higher. Correspondingly, the caspase-1-like and vacuolar processing enzyme (VPE) activities and MdVPEγ expression were higher in transgenic apple calli, but the expression levels of genes that inhibit cell death were lower than those in the WT under Cd stress. Moreover, the Cd translocation from the roots to leaves was increased after MhNRAMP1 overexpression, but the Cd translocation from the leaves to seeds was not affected. These results suggest that MhNRMAP1 exacerbated Cd-induced cell death, which was accomplished by mediating Cd²⁺ uptake and accumulation, as well as stimulating VPE.

Intestinal response to dietary manganese depletion inDrosophila

Metabolic adaptations to manganese deficiency.

Chronic cadmium exposure in Japanese quails perturbs serum biochemical parameters and enzyme activity

Cadmium is a heavy metal, toxic even in trace amounts and its biological function in the human body has not been described to date. It is assumed that cadmium manifests in dose-dependent genotoxic and cytotoxic effects on many organs and tissue types. In this study, we have analyzed the biochemical parameters in the serum of Japanese quails (Coturnix japonica) after chronic in vivo exposure to cadmium. Adult animals were exposed to cadmium in the form of CdCl₂ dissolved in water (0.20 mg/L) for 20 days. Significant differences between controls and exposed animals were found in 12 out of 13 analyzed biochemical parameters. Total bilirubin concentrations did not show any significant differences between the two groups. Exposure to cadmium has resulted in a significant increase in lactate dehydrogenase activity, sodium and chloride concentration, as well as significant reductions in total proteins, albumins, globulins, glucose, triglycerides, cholesterol, calcium concentration, and alkaline phosphatase activity. In this sense, chronic in vivo exposure to low doses of cadmium has induced severe changes in the levels of observed biochemical parameters and enzyme activity. Additionally, evident cytogenetic changes in the liver were also noted, where hepatocyte damage and even lack of organized nuclei, including nuclear fragmentation, clearly indicated ongoing apoptotic processes.

Repression of the Low Affinity Iron Transporter Gene FET4: A NOVEL MECHANISM AGAINST CADMIUM TOXICITY ORCHESTRATED BY YAP1 VIA ROX1

Cadmium is a well known mutagenic metal that can enter cells via nonspecific metal transporters, causing several cellular damages and eventually leading to death. In the yeast Saccharomyces cerevisiae, the transcription factor Yap1 plays a key role in the regulation of several genes involved in metal stress response. We have previously shown that Yap1 represses the expression of FET4, a gene encoding a low affinity iron transporter able to transport metals other than iron. Here, we have studied the relevance of this repression in cell tolerance to cadmium. Our results indicate that genomic deletion of Yap1 increases FET4 transcript and protein levels. In addition, the cadmium toxicity exhibited by this strain is completely reversed by co-deletion of FET4 gene. These data correlate well with the increased intracellular levels of cadmium observed in the mutant yap1. Rox1, a well known aerobic repressor of hypoxic genes, conveys the Yap1-mediated repression of FET4. We further show that, in a scenario where the activity of Yap1 or Rox1 is compromised, cells activate post-transcriptional mechanisms, involving the exoribonuclease Xrn1, to compensate the derepression of FET4. Our data thus reveal a novel protection mechanism against cadmium toxicity mediated by Yap1 that relies on the aerobic repression of FET4 and results in the impairment of cadmium uptake.

New insights into the Ca2+-ATPases that contribute to cadmium tolerance in yeast

Cadmium (Cd(2+)) is a toxic heavy metal which triggers several toxic effects in eukaryotes, including neurotoxicity and impaired calcium metabolism. In the model organism Saccharomyces cerevisiae, the best characterized pathway for Cd(2+) detoxification involves conjugation with glutathione (GSH) and subsequent transport to vacuoles by Ycf1p, an ATPase homologous to human MRP1 (Multidrug resistance associated protein 1). However, Cd(2+) tolerance also can be mediated by Pmr1p, a Ca(2+) pump located in the Golgi membrane, possibly through to the secretory pathway. Herein, we showed that inactivation of the PMR1 gene, alone or simultaneously with YCF1, delayed initial Cd(2+) capture compared to wild-type (WT) cells. In addition, Cd(2+) treatment altered the expression profile of yeast internal Ca(2+) transporters; specifically, PMC1 gene expression is induced substantially by the metal in WT cells, and this induction is stronger in mutants lacking YCF1. Taken together, these results indicate that, in addition to Pmr1p, the vacuolar Ca(2+)-ATPase Pmc1p also helps yeast cells cope with Cd(2+) toxicity. We propose a model where Pmc1p and Pmr1p Ca(2+)-ATPase function in cooperation with Ycf1p to promote Cd(2+) detoxification.

Protective effect of manganese in cadmium-induced hepatic oxidative damage, changes in cadmium distribution and trace elements level in mice

Oxidative tissue damage is considered an early sign of cadmium (Cd) toxicity and has been linked with carcinogenesis. Manganese(II)-at low doses, was found to act as a potent antioxidant against oxidative stress in different in vitro systems producing lipid peroxidation conditions. The present study investigates in vivo antioxidant effects of Mn²⁺ pretreatment in acute Cd intoxication with regard to lipid peroxidation, antioxidant defense system and cadmium distribution in the tissues of mice. Four groups of male mice (n=7–8) were used: Cd group was injected sc a single dose of CdCl₂ · 2½ H₂O · (7 mg/kg b.w.); Cd+Mn group was treated ip with MnCl₂ · 4H₂O (20 mg/kg b.w.) 24 hours before Cd intoxication; Mn group received manganese treatment only; Control group received saline only. Twenty-four hours after Cd intoxication an increased lipid peroxidation (p<0.05), depleted GSH level (p<0.01), increased activity of GSH-Px (p<0.05) and inhibited CAT activity (p<0.01) were found in Cd-treated group compared to controls. Manganese(II) pre-treatment either completely prevented (LP, GSH, GSH-Px) or significantly attenuated (CAT) these changes. Manganese(II) treatment alone decreased LP, enhanced hepatic GSH level and had no effect on antioxidant enzymes compared to control group. A significant increase of Cd concentration in the liver and decreased Cd concentration in the kidneys and testes were found in Cd+Mn treated mice compared to Cd-only treated group. The effect of manganese may result from a different metallothionein induction in particular organs. Manganese(II) pretreatment attenuated the interference of cadmium with Ca homeostasis, the alteration in Zn and Cu levels remained mostly unaffected.

Transport pathways for cadmium in the intestine and kidney proximal tubule: focus on the interaction with essential metals

Cadmium (Cd) is a toxic metal with a propensity to accumulate in the proximal tubules cells (PTC) of the kidney where it can lead to tubular dysfunction and eventually renal failure. Although Cd(2+)-induced nephrotoxicity has been well described there is still uncertainty about how this metal gains entry into these cells to induce toxicity. As a non-essential metal, specific transport proteins for Cd are unlikely to exist. Rather transport proteins/channels used by essential metals (iron, zinc, calcium) are thought to be responsible. When these dietary essential metals are in short supply and deficiencies develop, Cd absorption and toxicity are enhanced. This is primarily due to increased expression of essential metal transport proteins such as divalent metal transporter 1 (DMT1) which can transport Cd in the intestine and enhance toxicity in the kidney. The zinc/bicarbonate sympoters ZIP8 and 14 are expressed at the apical membrane of enterocytes and PTC, and can transport Cd into cells. TRPV5 and 6 are major transporters for calcium in intestine and kidney and may be involved in Cd transport in these locations. Cd in the circulation is bound to proteins such as metallothioneins (MT) which are readily filtered. Two multiligand receptors, megalin and cubulin, reabsorb filtered proteins including albumin and MT by the process of receptor-mediated endocytosis. This review summarises the transport pathways for Cd in the intestine and kidney proximal tubule focusing in particular at how Cd uses essential metal transport processes to gain entry to the circulation and the kidney.

Factors influencing intestinal cadmium uptake in pregnant Bangladeshi women--a prospective cohort study

Experimental studies indicate that zinc (Zn) and calcium (Ca) status, in addition to iron (Fe) status, affect gastrointestinal absorption of cadmium (Cd), an environmental pollutant that is toxic to kidneys, bone and endocrine systems. The aim of this study was to evaluate how various nutritional factors influence the uptake of Cd in women, particularly during pregnancy. The study was carried out in a rural area of Bangladesh, where malnutrition is prevalent and exposure to Cd via food appears elevated. The uptake of Cd was evaluated by associations between erythrocyte Cd concentrations (Ery-Cd), a marker of ongoing Cd exposure, and concentrations of nutritional markers. Blood samples, collected in early pregnancy and 6 months postpartum, were analyzed by inductively coupled plasma mass spectrometry (ICPMS). Ery-Cd varied considerably (range: 0.31-5.4microg/kg) with a median of 1.1microg/kg (approximately 0.5microg/L in whole blood) in early pregnancy. Ery-Cd was associated with erythrocyte manganese (Ery-Mn; positively), plasma ferritin (p-Ft; negatively), and erythrocyte Ca (Ery-Ca; negatively) in decreasing order, indicating common transporters for Cd, Fe and Mn. There was no evidence of Cd uptake via Zn transporters, but the association between Ery-Cd and p-Ft seemed to be dependent on adequate Zn status. On average, Ery-Cd increased significantly by 0.2microg/kg from early pregnancy to 6 months postpartum, apparently due to up-regulated divalent metal transporter 1 (DMT1). In conclusion, intestinal uptake of Cd appears to be influenced either directly or indirectly by several micronutrients, in particular Fe, Mn and Zn. The negative association with Ca may suggest that Cd inhibits the transport of Ca to blood.

Cadmium adaptation is regulated by multidrug resistance-associated protein-mediated Akt pathway and metallothionein induction

To elucidate the mechanisms involved in adaptation of lung epithelial cells to cadmium (Cd), we established a cell line that exhibits Cd-resistance (RWI38). RWI38 showed approximately 5-fold greater Cd-resistance (MTT assays) than WI38 cells, and cross-resistance to Zn and cisplatin. RWI38 cells also demonstrated an upregulated level of multidrug resistance-associated protein (MRP) and metallothionein (MT) (as shown by Western blot analysis and RT-PCR studies). The protein level of MRP decreased after Cd exposure in WI38 cells, but was sustained at high levels in RWI38 cells, leading led to enhanced calcein efflux. Cd induced Akt phosphorylation in RWI38 but not WI38 cells; this was prevented by probenecid or siRNA for MRP, both of which led to enhanced cell death, as demonstrated by capsase-3 activation and decreased cell viability. These results suggest a functional role for MRP in the regulation of the Akt pathway as well in the efflux pumping of drugs, thereby contributing toward the adaptation of cells to Cd toxicity. The findings of this study could be potentially beneficial in the design of therapeutic targets for Cd-induced tumor progression.

Prevention of cadmium accumulation in retinal pigment epithelium with manganese and zinc

Age-related macular degeneration (AMD) is a leading cause of irreversible blindness in the elderly. Risk factors include old age, female gender, obesity, smoking, low dietary intakes of antioxidants and increased exposure to the toxic metal cadmium (Cd(2+)). Supplementation with high-dose zinc (80 mg) provides some protection, but the mechanism(s) underlying such protection has not been fully elucidated. The present study had a focus on the human retinal pigment epithelial (RPE) cell line ARPE-19 in an attempt to demonstrate a reduction in intracellular Cd(2+) effect associated with heme oxygenase-1 (HO-1) expression by co-exposure with zinc (Zn(2+)) or manganese (Mn(2+)), which is known to be a more potent inhibitor of Cd(2+) uptake than Zn(2+). Our results indicated that co-exposure of 10 microM Cd(2+) with 5 microM Mn(2+) reduced the intracellular Cd(2+) effect by 50-60%, possibly by limiting the amounts of Cd(2+) entering cells through Mn(2+) transporter protein (ZIP8). A similar reduction in a Cd(2+) effect was achieved by co-exposure with 20 microM Zn(2+) while co-exposure with 5 and 10 microM Zn(2+) ions was ineffective. Mn(2+) ions as low as 2.5 microM were found to cause an increase in HO-1 mRNA expression levels in ARPE-19 cells, demonstrating for the first time that Mn(2+) is an inducer of HO-1. Mn(2+) ions at 1 microM induced HO-1 mRNA expression in the HEK293 human embryonic kidney cells. In contrast, Zn(2+) in 5, 10 or 20 microM concentrations did not induce expression of HO-1 in ARPE-19 cells or any other cells tested. These data suggest the superiority of Mn(2+) over Zn(2+) in preventing Cd(2+) uptake and accumulation in RPE to toxic levels. Further, induction of HO-1 by Mn(2+) could provide RPE with some resistance to enhanced oxidative stress arising from Cd(2+) accumulation in RPE as HO-1 is one of the frontline cellular antioxidant defense mechanisms.

Structural basis for the metal-selective activation of the manganese transport regulator of Bacillus subtilis

The manganese transport regulator (MntR) of Bacillus subtilis is activated by Mn(2+) to repress transcription of genes encoding transporters involved in the uptake of manganese. MntR is also strongly activated by cadmium, both in vivo and in vitro, but it is poorly activated by other metal cations, including calcium and zinc. The previously published MntR.Mn(2+) structure revealed a binuclear complex of manganese ions with a metal-metal separation of 3.3 A (herein designated the AB conformer). Analysis of four additional crystal forms of MntR.Mn(2+) reveals that the AB conformer is only observed in monoclinic crystals at 100 K, suggesting that this conformation may be stabilized by crystal packing forces. In contrast, monoclinic crystals analyzed at room temperature (at either pH 6.5 or pH 8.5), and a second hexagonal crystal form (analyzed at 100 K), all reveal the shift of one manganese ion by 2.5 A, thereby leading to a newly identified conformation (the AC conformer) with an internuclear distance of 4.4 A. Significantly, the cadmium and calcium complexes of MntR also contain binuclear complexes with a 4.4 A internuclear separation. In contrast, the zinc complex of MntR contains only one metal ion per subunit, in the A site. Isothermal titration calorimetry confirms the stoichiometry of Mn(2+), Cd(2+), and Zn(2+) binding to MntR. We propose that the specificity of MntR activation is tied to productive binding of metal ions at two sites; the A site appears to act as a selectivity filter, determining whether the B or C site will be occupied and thereby fully activate MntR.

Acquired cadmium resistance in metallothionein-I/II(-/-) knockout cells: role of the T-type calcium channel Cacnalpha1G in cadmium uptake

Metallothioneins (MTs) are cytoplasmic proteins that sequester certain divalent cations and are considered a primary cellular defense against the toxic transition metal cadmium (Cd(2+)). MT-I/II(-/-) knockout [MT(-/-)] cells are available and serve as an excellent tool to study non-MT-related mechanisms in metal tolerance. In the current study, Cd(2+)-resistant MT(-/-) (CdR) and CdR revertant (CdR-rev) cell lines were developed and characterized to investigate non-MT-mediated cellular protection mechanisms. Resistance to Cd(2+) was approximately 70-fold higher in CdR than the parental MT(-/-) cell line (IC(50) = 20 versus 0.3 microM, respectively) and was stable in the absence of Cd(2+) for 35 days. Accumulation of Cd(2+) by the CdR cell line was reduced by approximately 95% compared with parental cells, primarily because of a decreased Cd(2+) uptake. Cd(2+) uptake by the MT(-/-) parental cell line was independent of sodium, energy, and electrogenic potential. Uptake was saturable (K(m) = 65 nM; V(max) = 4.9 pmol/mg/min) and pH-dependent (maximal at pH 6.5-7). Potent inhibitors of Cd(2+) uptake included Zn(2+) (IC(50) = 7 microM), Mn(2+) (IC(50) = 0.4 microM), and the T-type Ca(2+) channel antagonist mibefradil (IC(50) = 5 microM), whereas other metals (including Fe(2+)) and L-type Ca(2+) channel antagonists had little effect. Immunoblot and real-time reverse transcription-polymerase chain reaction analysis indicated that the Cacnalpha(1G) T-type Ca(2+) channel was expressed at a reduced level in CdR compared with the parental MT(-/-) cell line, suggesting it is important for Cd(2+) uptake. The CdR1-rev cell line was found to have a Cd(2+) uptake and sensitivity level in between that of the CdR1 and MT(-/-) cell lines. Consistent with this was an intermediate expression of Cacnalpha(1G) in the CdR-rev cell line. These data suggest that decreased expression of Cacnalpha(1G) protects cells from Cd(2+) exposure by limiting Cd(2+) uptake.

Orally administrated rare earth element cerium induces metallothionein synthesis and increases glutathione in the mouse liver

The influence of oral administration of rare earth element cerium (Ce) was studied in relation to metallothionein (MT) and glutathione (GSH) content in the organs of ICR mice, which were administered heavy metal cadmium (Cd) for comparison. Male ICR mice were divided into 9 groups: 1 control group, 4 cerium groups and 4 cadmium groups, each with 4 mice, for a total of 36 mice. Ce groups included a 20 ppm CeCl3 diet (Ce-low) group and a 200 ppm CeCl3 diet (Ce-high) group, as did Cd groups, i.e., a 20 ppm CdCl2 diet (Cd-low) group and a 200 ppm CdCl2 diet (Cd-high) group. Each group was subdivided in 2 groups except a control group: 6-week administration group and 12-week administration group. The level of plasma aspartate aminotransferase(AST) activity, plasma alanine aminotransferase(ALT) activity, plasma cholesterol and plasma triglyceride in the Ce-low, Cd-low, Ce-high, and Cd-high group were higher than that of control group, although there were no significant differences (p > 0.05). By contrast, both Ce and Cd groups had higher levels of MT and GSH in hepatic cells compared to the control group (p < 0.05) and decreased liver tissue level of lipoperoxide (p < 0.05). These groups also had decreased plasma superoxide dismutase (SOD) activity (p < 0.05), and increased plasma level of lipoperoxide (p > 0.05). In conclusion, it is suggested that orally administered Ce increases MT and GSH as an antioxidant in the mouse liver, and these reaction are probably caused by increases in the oxidative stress with Ce.

Identification of mouse SLC39A8 as the transporter responsible for cadmium-induced toxicity in the testis

Testicular necrosis is a sensitive endpoint for cadmium (Cd(2+), Cd) toxicity across all species tested. Resistance to Cd-induced testicular damage is a recessive trait assigned to the Cdm locus on mouse chromosome 3. We first narrowed the Cdm-gene-containing region to 880 kb. SNP analysis of this region from two sensitive and two resistant inbred strains demonstrated a 400-kb haplotype block consistent with the Cd-induced toxicity phenotype; in this region is the Slc39a8 gene encoding a member of the solute-carrier superfamily. Slc39a8 encodes SLC39A8 (ZIP8), whose homologs in plant and yeast are putative zinc transporters. We show here that ZRT-, IRT-like protein (ZIP)8 expression in cultured mouse fetal fibroblasts leads to a >10-fold increase in the rate of intracellular Cd influx and accumulation and 30-fold increase in sensitivity to Cd-induced cell death. The complete ZIP8 mRNA and intron-exon splice junctions have no nucleotide differences between two sensitive and two resistant strains of mice; by using situ hybridization, we found that ZIP8 mRNA is prominent in the vascular endothelial cells of the testis of the sensitive strains of mice but absent in these cells of resistant strains. Slc39a8 is therefore the Cdm gene, defining sensitivity to Cd toxicity specifically in vascular endothelial cells of the testis.