Hitomi Fujishiro

The role of zinc transporters in cadmium and manganese transport in mammalian cells

To understand the mechanism of cadmium accumulation, it is important to know the precise mechanisms of transport systems for other metals. Recently, utilization of genomics and metallomics has clarified the involvement of specific metal transporter(s) in cadmium uptake. Studies with metallothionein (MT)-null cadmium-resistant cells have revealed the involvement of the manganese/zinc transport system in cadmium uptake. Genomic studies of strain differences in sensitivity to cadmium-induced testicular hemorrhage revealed that a zinc transporter, Zrt-, Irt-related protein (ZIP) 8 encoded by slc39a8, is responsible for the strain difference. Ectopic expression of ZIP8 in various cells enhanced the uptake of cadmium, manganese, and zinc. ZIP8-transgenic mice showed high expression of ZIP8 in the vasculature of testis and apical membrane of proximal tubules in kidney, and exhibited enhanced cadmium accumulation and toxicity when treated with cadmium. The expression of ZIP8 was found to be down-regulated in MT-null cadmium-resistant cells, in which the uptake rates of both cadmium and manganese were decreased. These data suggest that ZIP8 plays an important role in the uptake of both cadmium and manganese in mammalian cells. The role of ZIP14 in the uptake of cadmium and manganese is also discussed.

Zinc transporter SLC39A10/ZIP10 controls humoral immunity by modulating B-cell receptor signal strength.

Significance The essential micronutrient zinc is known to modulate adaptive immune responses and dysregulated zinc homeostasis leads to immunodeficiency. However, the molecular mechanisms underlying this zinc-mediated modulation are unknown. We show that the zinc transporter ZIP10 plays an important role in B-cell receptor (BCR) signaling. Zip10-deficiency in mature B cells attenuated both T-cell–dependent and –independent immune responses. Zip10-deficient mature B cells proliferated poorly in response to BCR cross-linking, as a result of dysregulated BCR signaling. Our data establish that ZIP10 functions as a cellular regulator to modulate BCR signaling in humoral immune responses. The humoral immune response, also called the antibody-mediated immune response, is one of the main adaptive immune systems. The essential micronutrient zinc (Zn) is known to modulate adaptive immune responses, and dysregulated Zn homeostasis leads to immunodeficiency. However, the molecular mechanisms underlying this Zn-mediated modulation are largely unknown. Here, we show that the Zn transporter SLC39A10/ZIP10 plays an important role in B-cell antigen receptor (BCR) signal transduction. Zip10-deficiency in mature B cells attenuated both T-cell–dependent and –independent immune responses in vivo. The Zip10-deficient mature B cells proliferated poorly in response to BCR cross-linking, as a result of dysregulated BCR signaling. The perturbed signaling was found to be triggered by a reduction in CD45R phosphatase activity and consequent hyperactivation of LYN, an essential protein kinase in BCR signaling. Our data suggest that ZIP10 functions as a positive regulator of CD45R to modulate the BCR signal strength, thereby setting a threshold for BCR signaling in humoral immune responses.

The role of ZIP8 down-regulation in cadmium-resistant metallothionein-null cells

The mechanisms of cellular cadmium uptake in mammalian cells remain obscure. To solve this problem, we established cadmium‐resistant cells (A7 and B5) from metallothionein‐null mouse cells, and found that cadmium accumulation was markedly suppressed in these cells. DNA microarray and real‐time PCR analyses revealed that expressions of ZIP (Zrt‐, Irt‐related protein) 8 and ZIP14 were down‐regulated in A7 and B5 cells. In particular, both mRNA and protein levels of ZIP8 were markedly suppressed in A7 and B5 cells. Introduction of short hairpin RNA (shRNA) of ZIP8 into parental cells reduced the accumulation of cadmium to about 35% of that of mock‐transfected cells, whereas the introduction of shRNA of divalent metal transporter 1 hardly changed cadmium accumulation. Thus, the cadmium resistance in A7 and B5 cells may be conferred primarily by the down‐regulation of ZIP8. In mouse tissues, high expression of ZIP8 was noted in the liver, kidney, lung and testis. These data suggest that ZIP8 plays an important role in cellular uptake of cadmium. Copyright

Involvement of DNA hypermethylation in down-regulation of the zinc transporter ZIP8 in cadmium-resistant metallothionein-null cells

The Zrt/Irt-related protein 8 (ZIP8) encoded by slc39a8 is now emerging as an important zinc transporter involved in cellular cadmium incorporation. We have previously shown that mRNA and protein levels of ZIP8 were decreased in cadmium-resistant metallothionein-null (A7) cells, leading to a decrease in cadmium accumulation. However, the mechanism by which ZIP8 expression is suppressed in these cells remains to be elucidated. In the present study, we investigated the possibility that epigenetic silencing of the slc39a8 gene by DNA hypermethylation is involved in the down-regulation of ZIP8 expression. A7 cells showed a higher mRNA level of DNA methyltransferase 3b than parental cells. Hypermethylation of the CpG island of the slc39a8 gene was detected in A7 cells. Treatment of A7 cells with 5-aza-deoxycytidine, an inhibitor of DNA methyltransferase, caused demethylation of the CpG island of the slc39a8 gene and enhancement of mRNA and protein levels of ZIP8. In response to the recovery of ZIP8 expression, A7 cells treated with 5-aza-deoxycytidine showed an increase in cadmium accumulation and consequently an increase in sensitivity to cadmium. These results suggest that epigenetic silencing of the slc39a8 gene by DNA hypermethylation plays an important role in the down-regulation of ZIP8 in cadmium-resistant metallothionein-null cells.

Direct Comparison of Manganese Detoxification/Efflux Proteins and Molecular Characterization of ZnT10 Protein as a Manganese Transporter

Manganese homeostasis involves coordinated regulation of specific proteins involved in manganese influx and efflux. However, the proteins that are involved in detoxification/efflux have not been completely resolved nor has the basis by which they select their metal substrate. Here, we compared six proteins, which were reported to be involved in manganese detoxification/efflux, by evaluating their ability to reduce manganese toxicity in chicken DT40 cells, finding that human ZnT10 (hZnT10) was the most significant contributor. A domain swapping and substitution analysis between hZnT10 and the zinc-specific transporter hZnT1 showed that residue Asn43, which corresponds to the His residue constituting the potential intramembranous zinc coordination site in other ZnT transporters, is necessary to impart hZnT10s unique manganese mobilization activity; residues Cys52 and Leu242 in transmembrane domains II and V play a subtler role in controlling the metal specificity of hZnT10. Interestingly, the His → Asn reversion mutant in hZnT1 conferred manganese transport activity and loss of zinc transport activity. These results provide important information about manganese detoxification/efflux mechanisms in vertebrate cells as well as the molecular characterization of hZnT10 as a manganese transporter.

High sensitivity of RBL-2H3 cells to cadmium and manganese: an implication of the role of ZIP8

Cellular incorporation of Cd involves multiple transport systems for other metals such as Fe, Zn, Mn, and Ca. Metal transporters including divalent metal transporter 1, Zrt/Irt-related protein (ZIP) 8, and ZIP14, and certain types of voltage-dependent Ca channels have been shown to be involved in cellular Cd uptake. However, tissue- or cell-specific roles of these metal transporters in the accumulation and toxicity of Cd remains unclear. In the present study, we compared the sensitivity to and accumulation of Cd, Mn, and Zn among four types of rat cell lines. Rat basophilic leukemia RBL-2H3 cells showed the highest sensitivity to Cd and Mn due to the highest accumulation of Cd and Mn among the four cell lines. The high accumulation of Cd and Mn was caused by high uptake rates of Cd and Mn. Since relatively high expression of ZIP8 and ZIP14 was found in RBL-2H3 cells, siRNAs of ZIP8 and ZIP14 were transfected into RBL-2H3 cells. The knockdown of ZIP8, but not of ZIP14, significantly reduced the uptake rates of Cd and Mn in RBL-2H3 cells, especially in the presence of bicarbonate. These results suggest that the high expression of ZIP8, which is known to have affinities for both Cd and Mn, resulted in high accumulation of Cd and Mn, leading to high sensitivity to these metals in RBL-2H3 cells. Thus, RBL-2H3 cells may serve as a good model for clarifying the mechanisms of Cd and Mn transport via ZIP8.

Cross-resistance of cadmium-resistant cells to manganese is associated with reduced accumulation of both cadmium and manganese.

The mechanism of cellular entry of cadmium remains unclear. We have previously established cadmium-resistant cells from mouse embryonic cells of metallothionein (MT)-null mice, and demonstrated that the down-regulation of a zinc transporter, Zrt/Irt-related protein (ZIP) 8, was responsible for the reduced cadmium incorporation into cells. In the present study, we developed cadmium-resistant cells (A+70 and B+70) from mouse embryonic cells of MT-expressing wild-type mice. The LC₅₀ values of CdCl₂ for A+70 and B+70 cells were about 200 μM while that of the parental cells was 30 μM. We found that the cadmium resistance of these cells was conferred not only by enhanced expression of MT, but also by a decrease in cadmium accumulation. Since the uptake rates of cadmium into A+70 and B+70 cells were lowered, we determined the expression levels of the metal transporters and channels potentially involved in the cellular uptake of cadmium. We found a down-regulation of multiple transport systems, including ZIP8, divalent metal transporter 1 (DMT1), and α₁ subunits of L-type (Ca(V)1.2) and T-type (Ca(V)3.1) voltage-dependent calcium channels, in A+70 and B+70 cells. Furthermore, A+70 and B+70 cells exhibited cross-resistance to cytotoxicity of MnCl₂, probably due to a marked decrease in manganese uptake in these cells. These results suggest that the suppressed expression of ZIP8 and DMT1, which are known to have affinities for both cadmium and manganese, may be responsible for the reduction in the uptake, and consequently the cytotoxicity, of cadmium and manganese in A+70 and B+70 cells.

Quantum dots induce heat shock-related cytotoxicity at intracellular environment

Quantum dots (QDs) are semiconductor nanocrystals with unique optical properties. Different proteins or polymers are commonly bound to their surfaces to improve biocompatibility. However, such surface modifications may not provide sufficient protection from cytotoxicity due to photodegradation and oxidative degradation. In this study, the cytotoxic effects of QDs, CdTe, and CdSe/ZnS were investigated using cadmium-resistant cells. CdTe QDs significantly reduced cell viability, whereas, CdSe/ZnS treatment did not markedly decrease the cell number. CdTe QDs were cytotoxic in cadmium-resistant cells suggesting that internalized QDs degraded and cadmium ions contributed to the cytotoxic effects. CdTe QDs were consistently more cytotoxic than CdSe/ZnS QDs, but both QDs as well as cadmium ions activated heat shock protein 70B′ promoter. QDs themselves are likely to contribute to HSP70B′ promoter activation in cadmium-resistant cells, because CdSe/ZnS QDs do not release sufficient cadmium to activate this promoter.

Concentration-dependent roles of DMT1 and ZIP14 in cadmium absorption in Caco-2 cells

Intestinal absorption of cadmium (Cd) is considered to be mediated mainly by the ferrous iron transporter DMT1, or the calcium transporter CaT1. The roles of zinc transporters such as ZIP8 and ZIP14 remain unclear, and the roles of these four transporters in the intestinal uptake of Cd under physiological conditions have not been compared. Here, we used a trans-well cell culture system to investigate the effects of the down-regulation of these four transporters on the uptake of Cd from the apical side of enterocytes. We used a Caco-2-kh cell line that can form tight junctions within a few days. The transfection of DMT1 siRNA significantly decreased the Cd uptake from the apical side at 5 μM, but not at 0.1 or 1 μM. The transfection of ZIP14 siRNA markedly decreased the Cd uptake at 0.1 and 1 μM, but not at 5 μM. The transfection of siRNA of CaT1 or ZIP8 did not alter the Cd uptake at any concentrations of Cd examined. These results suggest that DMT1 and ZIP14 play different roles in intestinal Cd absorption depending on the concentration of Cd.

Roles of Zinc Transporters in Cellular Transport of Cadmium and Manganese

As cadmium (Cd) is a nonessential metal, there is no specific transport system for cellular entry of Cd in the organisms. The establishment of Cd-resistant cells from metallothionein-null mouse cells, application of multi-tracer technique, and microarray analyses have revealed that Cd2+ shares the pathway for cellular incorporation with Mn2+, and the responsible transporters for this pathway were found to be ZIP8 (Zrt- and Irt-related protein 8) and ZIP14. Although other transport systems for iron or calcium are also utilized for cellular incorporation of Cd2+ and Mn2+, characterization of ZIP8 and ZIP14 has demonstrated important physiological and pathological roles of these transporters in metal transport. We show here the significant roles of ZIP8 in segment-specific transport of Cd in proximal tubule of the kidney and the roles of ZIP14 and ZnT10 in Mn transport in neuronal cells in the presence of cytokine. Recently, critical roles of Mn transport systems have been highlighted by the findings of human diseases related to the mutation in ZIP8 and ZnT10. This chapter summarized historical background and recent advances in the studies on the roles of ZIP8 and ZIP14 in the transport of Cd2+ and Mn2+.