Differential Localization of Divalent Metal Transporter 1 with and without Iron Response Element in Rat PC12 and Sympathetic Neuronal Cells

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The Journal of Neuroscience, October 15, 2000, 20(20):7595-7601

Differential Localization of Divalent Metal Transporter 1 with and without Iron Response Element in Rat PC12 and Sympathetic Neuronal Cells
Jerome A. Roth¹, Craig Horbinski¹, Li Feng¹, Kevin G. Dolan², Dennis Higgins¹, and Michael D. Garrick²
Departments of ¹ Pharmacology and Toxicology and ² Biochemistry, State University of New York, Buffalo, New York 14214

  ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Two isoforms of divalent metal transporter 1 (DMT1) (Nramp2 and DCT1) are encoded by two mRNA species, one of which containsan iron response element (IRE) motif in the 3'-noncoding region.The subcellular distribution of the two isoforms of DMT1 is distinct,and the $-$ IRE species accumulates in the nucleus of neuronal orneuronal-like cells. Reverse transcription-PCR and Western blotanalysis of PC12 cells reveals that these cells express both formsof DMT1. Immunofluorescence and immunoblotting studies, usingimmunospecific antibodies to the $-$ IRE form of DMT1, demonstratethat this form of the transporter, in PC12 cells, is predominantlylocalized in the nucleus, cell membrane, and neurites with onlyweak staining of the cell body. Studies using antibodies to the+IRE form indicate that this species of DMT1 is distributed withinvesicles in the cell body and neurite projections, with minimalnuclear staining. Similar staining patterns are observed for thetwo forms of DMT1 in cultures of sympathetic ganglion neuronsisolated from perinatal rat pups. To determine whether nuclearlocalization of the $-$ IRE form of DMT1 is constrained to neuronalor neuronal-like cells, immunocytochemical studies were performedwith human embryonic kidney 293T (HEK293T), HEP2G hepatoma andmedulloblastoma, and rat Schwann cells. The $-$ IRE-specific antibodiesstained nuclei from medulloblastoma, whereas little nuclear stainingwas observed with HEK293T, hepatoma, or Schwann cells. The unexpectedfinding that the $-$ IRE species of DMT1 selectively accumulatesin the nucleus of neuronal and neuronal-like cells leads us topostulate that the two proteins may have different functions invivo.

Key words: divalent metal transporter 1; DMT1; Nramp2; iron transport; PC12 cells; sympathetic neurons; nuclear localization; transferrin receptor; HEK293T cells

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Iron uptake in most mammalian cells occurs via the transferrin cycle. Iron is normally transported in the plasma in the ferricstate by transferrin (Ponka, 1997). Transferrin subsequently bindsthe transferrin receptor on the cell surface, which then undergoesendocytosis, generating endosomal vesicles within the cell. Theendosomes are acidified by a hydrogen ion ATPase pump, causingcooperative release of the metal from the transferrin-transferrinreceptor (TfR) complex. Ferrous iron is then transported acrossthe endosomal membrane via divalent metal transporter 1 (DMT1;Fleming et al., 1998). A proton gradient across the endosomalmembrane is the driving force supporting metal ion-proton cotransportout of the endosome by DMT1 (Gunshin et al., 1997). DMT1 has avery broad substrate specificity and potentially transports otherdivalent cations, including Mn²⁺, Cd²⁺, Zn²⁺, Co²⁺, Ni²⁺, Cu²⁺, and Pb²⁺ (Gunshin et al., 1997).

Two isoforms of DMT1 present in mammalian cells result from alternate splicing of a single gene product (Gruenheid et al.,1995; Fleming et al., 1998; Lee et al., 1998). The two polypeptidesshare 543 residues on the N-terminal end but differ primarilyin the last 18 or 25 C-terminal residues. Only one of the twoforms of mRNAs contains an iron response element (IRE) motif inthe 3'-noncoding region. Accordingly, we refer to these as $-$ IREand +IRE henceforth. Both isoforms contain 12 putative membrane-spanningdomains and a consensus transport motif in the fourth intracellularloop (Gunshin et al., 1997). The presence of the IRE providesa site for binding of iron response proteins 1 and 2 (IRP1 and2) (Rouault and Klausner, 1997; Haile, 1999; Schümann et al.,1999). Binding of either IRP should stabilize DMT1 mRNA and increaseexpression of the +IRE protein. Recent studies demonstrate thatIRP2 knock-out mice develop a progressive neurodegenerative disorder,including iron deposition in the CNS, similar to that observedin Parkinson's disease (Rouault, 1999). Thus, changes in the expressionof proteins that are regulated by IRP1 and 2, which include DMT1and TfR, may be responsible for the observed neurological disturbancesobserved in these knock-outmice.

Our laboratory has been characterizing the biochemical and molecular mechanisms responsible for heavy metal neurotoxicityand the contribution of transport in regulating these cytotoxicevents. We have used rat PC12 cells as a model system to studymanganese neurotoxicity, because these cells possess much of thebiochemical machinery of dopaminergic neurons. Manganese can inducePC12 cell neuronal differentiation similar to that of nerve growthfactor (NGF); however, it invariably leads to cell death (Linet al., 1993). Recent studies suggest that cell death inducedby manganese may be caused by either necrosis and/or apoptosisattributable to oxidative stress (Desole et al., 1996, 1997a,b;Hirata et al., 1998; Schrantz et al., 1999; Roth et al., 2000).Manganese has been reported to be taken up into PC12 cells bya transport system with characteristics resembling those of DMT1(Kim et al., 1993), although the significance of the resemblancehas been questioned (Yanagiya et al., 2000). Thus, studies wereperformed to determine whether DMT1 is present in PC12 cells toparticipate in manganese uptake. Our results reveal that PC12cells contain both species of DMT1 and that the two transportersare distributed in different cellular compartments within bothPC12 cells and cells of neuronal origin. In addition, the twoisoforms of DMT1 only partially colocalized withTfR.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cell culture. PC12 cells were maintained in DMEM (Life Technologies, Grand Island, NY) supplemented with 10% FBS (HyClone,Logan, UT), 5% horse serum (JRH Biosciences, Lenexa, KS), 100U/ml penicillin, and 100 µg/ml streptomycin (Lin et al., 1993).Cells were grown at 36.5°C in a humidified atmosphere containing5% CO₂ as described previously (Lin et al., 1993) and subculturedevery 2-3 d at ~70-80%confluency.

Antibodies to +IRE and $-$ IRE forms of DMT1. To characterize the subcellular distribution of the two species of DMT1, it wasnecessary to produce antibodies that can selectively recognizeeach specific isoform (Gunshin et al., 1997; Fleming et al., 1998).Accordingly, peptides corresponding to the C-terminal sequenceof each protein were synthesized for preparation of antibodies.Antibodies to the two forms of DMT1 were prepared by $alpha$ DiagnosticInternational Inc. (San Antonio, TX) from the following C-terminalpeptides: +IRE peptide (545-561), SISKVLLSEDTSGGNTK; and $-$ IREpeptide (547-568), GLTARPEIYLLNTVDAVSLVSR. These peptides werechosen on the basis of their representing the most structurallydistinct sequences of the two isoforms of the transporter andan evaluation of their potential immunogenicity. The peptideswere separately attached to keyhole limpet hemocyanin, and eachwas injected into two rabbits. The antisera were recovered, andthe antibodies were immunoaffinity-purified against the respectivepeptides attached to Sepharose. Titers were determined againstthe immunizing peptides by ELISA and were used as a guide in selectingdilutions for Western blotting and immunofluorescent microscopydescribedbelow.

Identification of the +IRE and $-$ IRE forms of DMT1 in PC12 cells by reverse transcription-PCR. Forward and reverse primersfor +IRE DMT1 and $-$ IRE DMT1 were used selectively to assess PCRproducts for the +IRE and $-$ IRE forms of DMT1 in PC12 cells andcultured rat sympathetic neurons. For the +IRE form the forwardprimer sequence was 5'-CGGTAAGCATCTCTAAAG, representing bp 1732-1750,and the reverse primer was 5'-TAGCAGCATGCTATTTGAC, representingbp 1980-1998. To assess PCR products for the $-$ IRE forms of DMT1,the forward primer sequence was 5'-TCTAGATGACCAACAGCC, representingbp 1699-1716, and the reverse primer was 5'-GCAGACACAAGCCTGCGT,representing bp 1945-1962. Both selections are in the 3' untranslatedregion. The reverse transcription-PCR reaction (25 cycles) wasperformed, and the resulting +IRE DMT1 and $-$ IRE DMT1 PCR products,267 and 264 bp, respectively identified on agarose gels, wereeach ligated into the pCR2.1-TOPO vector and transformed intoEscherichia coli. Colonies containing the +IRE DMT1 or $-$ IRE DMT1inserts were selected with ampicillin and identified by theirwhite color. These colonies were grown overnight in Luria-Bertanibroth containing ampicillin, and the plasmid DNA was isolated,digested with EcoRI, and resolved on 1% agarose gels to confirmthe presence and size of the inserts. The plasmid DNA containingthe expected size insert was sent to the Center for Advanced MolecularBiology and Immunology, State University of New York at Buffalo,for DNA sequence analysis, and the results were compared withthe sequence from GenBank (accession numbers AF008439 and AF029757).

Identification of the +IRE and $-$ IRE forms of DMT1 in PC12 cells by Western blot analysis. Western blot experiments were performedto determine the protein expression of DMT1 in PC12 cells. Whole-celllysates and isolated nuclei were prepared, and 60 µg of proteinfrom each sample was subjected to SDS-PAGE on a 12% acrylamidegel. Nuclei were isolated by differential centrifugation on adiscontinuous sucrose gradient according to the method of Cassanoet al. (1996). The proteins were transferred to an Immobilon-Pmembrane and were subsequently treated with affinity-purifiedantibodies to either the +IRE or $-$ IRE form of DMT1. DMT1 was detectedusing horseradish peroxidase-conjugated secondary antibody forrabbit IgG with Pierce (Rockford, IL) SuperSignal chemiluminescentsubstrate.

Isolation and culture of sympathetic neurons. Sympathetic neurons from perinatal Holtzman rat pups (Harlan Sprague Dawley,Indianapolis, IN) were isolated and maintained in culture as describedpreviously (Higgins et al., 1991). Dissociated cells were platedonto poly-D-lysine-coated (100 µg/ml) coverslips at a densityof ~10 cells/mm² and maintained in serum-free medium containing $beta$ NGF (100 µg/ml)and human transferrin (20 µg/ml). Non-neuronal cells (i.e., fibroblastsand Schwann cells) were eliminated by adding the antimitotic agentcytosine-D-arabinofuranoside for 48 hr. Bone morphogenic protein7 (BMP7; 50 µg/ml) was then added to induce dendritic outgrowth(Lein et al., 1995). DMT1 in these cells was detected immunocytochemicallywith the two antibodies to DMT1. In some experiments, the antimitoticagent was not added to compare the subcellular distributions ofDMT1 in Schwann cells to that inneurons.

Ectopic expression of DMT1. Ectopic expression of rat $-$ IRE DMT1 in human embryonic kidney 293T (HEK293T) cells followed themethod of Fleming et al. (1998) as modified by Garrick and Dolan(2000). Briefly, HEK293T cells were grown in DMEM with 10% FBSat 37°C in 95% O₂ and 5% CO₂ in a CO₂ incubator. Transfectionswere performed with DMRIE-C according to the manufacturer's instructions(Life Technologies, Rockville, MD). Cells transfected with 0.5µg of the pMT2-DMT1 expression plasmid in 1 ml of media were examined~48 hrlater.

Immunocytochemistry. Cell cultures were fixed in 4% paraformaldehyde in 0.1 mM phosphate buffer and permeabilized for 3 minwith 0.1% Triton X-100 in PBS (0.15 M NaCl and 0.01 M sodium phosphatebuffer, pH 7.3). The two forms of DMT1 were localized by indirectimmunofluorescence using previously described procedures of Higginset al. (1991). Affinity-purified polyclonal rabbit antiserum thatspecifically cross-reacts with either the +IRE or $-$ IRE speciesof the transporter was used as the primary antibody, and rhodamine-conjugatedgoat anti-rabbit IgG (Boehringer Mannheim, Indianapolis, IN) orAlexa-594 goat anti-rabbit IgG (Molecular Probes, Eugene, OR)for the HEK293T cells was used as the secondary antibody. In someexperiments OX-26 (murine monoclonal anti-rat transferrin receptor;Serotec, Raleigh, NC) was used as a second primary antibody, andAlexa-488 goat anti-mouse IgG (Molecular Probes) was used as thesecondary antibody. Immunostained cultures were mounted in Elvanol(DuPont, Wilmington, DE) and analyzed by conventional fluorescence(Optiphot; Nikon, Melville, NY) and confocal laser microscopy(Bio-Rad, Hercules, CA; 1024 confocal with a krypton-argon laserlinked to a Nikon Optiphot microscope). Images were obtained usinga 60× lens, numerical aperture (NA) 1.4, except for Figure 4,for which a 20× lens, NA 0.75, wasused.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Identification of DMT1 mRNA and protein in PC12 cells

Initial studies were performed to determine whether PC12 cells express DMT1 mRNA isoforms. As illustrated in Figure 1, reversetranscription (RT)-PCR products from the appropriate $-$ IRE and+IRE primers each yielded a single major band, consistent withthe expected number of base pairs for both forms of DMT1. Thenucleotide sequence of the two PCR products was analyzed and foundto correspond to the known sequences for the $-$ IRE and +IRE isoformsof DMT1. Using the cloned PCR products as probes, Northern blotsalso confirmed the presence of both species of DMT1 in PC12 cells(data not shown). Western blots detected the expression of the+IRE and $-$ IRE protein in these cells (Fig. 2). A single majorband was observed with both antibodies, with an M_r of ~65 kDa,in good agreement with the expected molecular weight based onthe amino acid sequences for both isoforms of DMT1.

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Figure 1. RT-PCR products of the +IRE and $-$ IRE species of DMT1 from PC12 cells. The two bands identified on the gel correspond to the expected oligonucleotide lengths based on the primers used for each isomer of DMT1.

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Figure 2. Western blots of the $-$ IRE and +IRE species of DMT1 from PC12 cells. Western blots were performed on protein isolated from PC12 cells as described in Materials and Methods. The M_r of ~65 kDa for the two bands appearing on the gel corresponds to the expected size of the two isoforms of DMT1 based on the known amino acid composition.

Subcellular localization of +IRE and $-$ IRE forms of DMT1 in PC12 cells

The subcellular distribution of the two isoforms of DMT1 was examined to help understand their function in iron and divalentmetal transport. Both forms of DMT1 are proteins with 12 putativemembrane-spanning domains that are presumed to be located at thecell membrane and/or within the endosomal fraction of the cell.This expectation is supported by previous immunocytochemical studiesusing antibody preparations that are unable to fully distinguishthe two species of the transporter (Su et al., 1998; Canonne-Hergauxet al., 1999; Gruenheid et al., 1999; Tabuchi et al., 2000; Trinderet al., 2000). Accordingly, immunocytochemical studies were performedwith PC12 cells treated with NGF for 5 d using affinity-purifiedantibodies specific for each form of DMT1. Confocal microscopyimages demonstrate that the +IRE form of DMT1 is mainly distributedin a punctate manner throughout the cell body with little if anystaining of the nucleus (Fig. 3B,D). The pattern of staining withinthe cell body is rather diffuse with relatively little stainingassociated with the plasma membrane. Although somewhat difficultto see in the optical sections used in these figures, there isalso intense staining within the neurites of NGF-treated PC12cells. In contrast, the pattern of staining with the $-$ IRE antibodyin PC12 cells is considerably different from that observed withthe +IRE antibody preparation (Fig. 3A,C). Most striking is theintense staining that is present in both the nucleus and the plasmamembrane. A minimum of 80% of the PC12 cells in the presence ofNGF display nuclear staining. A similar pattern of staining wasalso obtained in control cells not treated with NGF. In both cases,there is an absence of staining in the nucleolus and only weakand diffuse staining of the cell body. Although not shown, theintensity of nuclear staining appeared to be enhanced during longerculture times, and this response was independent of exposure toNGF. As shown in Figure 3A, there was also strong $-$ IRE stainingof the cytoplasmic fraction within the neurites and growth conesin cells treated with NGF.

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Figure 3. Confocal fluorescence micrographs of PC12 cells immunostained with antibodies specific for the $-$ IRE (A) and +IRE (B) species of DMT1, along with the corresponding phase-contrast images. Cells were exposed to NGF for 5 d before they were immunostained.

Western blots were also performed to verify the selective staining pattern of the two forms of DMT1 in isolated nuclei fromPC12 cells. As illustrated in Figure 4, a strong band at slightlyhigher than the expected 65 kDa appeared with the isolated nuclearfraction when immunostained with antibody for the $-$ IRE form ofDMT1. In contrast, antibody to the +IRE species failed to detecta band with the nuclear fraction on the same gels. However, bothantibodies recognized a strong band at ~65 kDa with the remainingcell fraction.

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Figure 4. Western blots of subcellular fractions to detect the $-$ IRE and +IRE sequences of DMT1. The +IRE species contains a major band at ~65 kDa and a diffuse band at ~91 kDa in the cytoplasmic cell fraction (cytosolic and membrane fraction) and no staining in the nuclear fraction. The $-$ IRE species is detected at ~65 kDa in the cytoplasmic fraction and at ~67 kDa in the nuclear fraction.

Subcellular localization of +IRE and $-$ IRE forms of DMT1 in rat sympathetic neurons

Previous studies indicated there was no nuclear staining of DMT1 in rat duodenal enterocytes using an antibody that reactedwith a common epitope to both forms of the transporter (Trinderet al., 2000). On the basis of these findings, we decided to determinewhether the nuclear staining observed with the $-$ IRE form of DMT1in PC12 cells is present in other neuronal cells. RT-PCR experimentsreveal that sympathetic neurons isolated from perinatal rat pupsexpress DMT1 mRNA. A single band appeared for both the +IRE and $-$ IRE isoforms of DMT1 corresponding to the expected base size(Fig. 5).

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Figure 5. RT-PCR products of the +IRE and $-$ IRE species of DMT1 from cultured rat sympathetic neurons treated for 5 d with BMP7. The two bands identified on the gel correspond to the expected oligonucleotide size based on the primers used for each isomer of DMT1.

When the subcellular distribution for both species of DMT1 was determined in these sympathetic neuronal cells, a pattern ofstaining similar to that observed with PC12 cells was obtained(Fig. 6). Selected optical sections from two neurons using antibodiesdirected against the $-$ IRE form of DMT1 demonstrate intense stainingof both the nucleus and cell membrane but not the nucleolus ofsympathetic neurons treated with BMP7 (Fig. 6A,C), and there wasrelatively weak staining of the cell body compared with that ofthe nucleus. In contrast, reactions using antibodies against the+IRE form of DMT1 (Fig. 6B,D) resulted in a punctate and diffusestaining pattern in the cell body, including the cell membranes,with essentially total absence of staining of the nucleus. Bothantibody preparations were capable of staining axonal and dendriticprojections of the BMP7-treated sympathetic neurons (Fig. 6A,B).

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Figure 6. Confocal fluorescence micrographs of cultured rat sympathetic neurons treated for 5 d with BMP7 (50 µg/ml) immunostained with antibodies specific for the $-$ IRE (A, C) and +IRE (B, D) species of DMT1. In the two optical sections (A, B), near the substratum on which the cells were grown, neurites are visible; in sections C and D, which are well above the substratum, staining patterns of the nucleus are most visible.

To demonstrate that the staining pattern observed in the sympathetic neurons was dependent on the specificity of the antibodies,studies were performed to ascertain whether the two peptides usedfor production of the antibodies could inhibit their respectiveimmune responses. As illustrated in Figure 7, A and B, the specificpeptide from the $-$ IRE species greatly attenuated the responsewith the $-$ IRE antibody, demonstrating that the antibody is reactingwith the expected DMT1 epitope. As shown in Figure 7, C and D,a similar result was observed when the peptide specific for the+IRE form of DMT1 was used to inhibit the +IRE-specific antibodyresponse. As an additional control to verify specificity of theresponses, studies were also performed to determine whether the+IRE peptide could inhibit the staining of the $-$ IRE antibody andwhether the $-$ IRE peptide could inhibit that of the +IRE antibody(data not shown). As expected, there was no diminution in signalstrength when the peptides were used in this manner, further confirmingthe specificity of the antibody preparations.

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Figure 7. Confocal fluorescence micrographs of cultured rat sympathetic neurons treated for 5 d with BMP7 immunostained with antibodies specific for the $-$ IRE (A, C) and +IRE (B, D) species of DMT1. Peptides to the C-terminal sequence, used to generate the antibodies, for either the $-$ IRE (C) or +IRE (D) forms of DMT1 were added before immunostaining. In both cases, addition of peptides attenuated the intensity of the immunostaining of the neurons.

Isoforms of DMT1 minimally colocalize with transferrin receptors in sympathetic neurons

TfR serves as a means of tracking intracellular iron metabolism and endocytosis, having already been well characterized inmany types of cells. Therefore, experiments were performed todetermine whether either species of DMT1 colocalizes with TfR,which has previously been reported to be primarily restrictedto the cell body and dendrites of cultured neurons (Cameron etal., 1991). Figure 8, A and C, illustrates selected optical sectionsfor TfR and the $-$ IRE form of DMT1, and Figure 8, B and D, showssections for TfR and the +IRE form of DMT1. TfRs are also foundpreferentially in perinuclear vesicles and in the region of thecell surface with total absence of staining of the nucleus (Fig.8C,D). Antibodies to TfR also strongly stain dendrites of thesympathetic neurons treated with BMP7 (Fig. 8A,B). A strikinglydifferent picture emerges when the staining pattern for the $-$ IREisoform of DMT1 is compared with that for TfR (Fig. 8A,C). Thetwo proteins only partially colocalize on the cell surface, withthe most intense staining of the $-$ IRE species of DMT1 observedin the nucleus. Considerably less staining of this form of DMT1is observed in the cytosol of the cell body; rather, it is presenton the cell surface and the surface of the dendrites, appearingin the dendrite extensions well away from the cell body in a punctatemanner. The staining pattern for the $-$ IRE isoform of DMT1 is minimallypresent in perinuclear vesicles, whereas staining for TfR is predominantlyperinuclear as expected. TfR staining is also relatively moreintense both in the cell surface and within the cell body thanthat for $-$ IRE protein, and, as noted above, TfR staining is totallyabsent from the nucleus. TfR also appears to be present on thecell surface independent of this isoform of the transporter. Thestaining pattern for the +IRE isoform of DMT1 and TfR (Fig. 8B,D)also reveals both different and similar localization patternsfor these proteins. TfR staining only partially colocalized withthat of the +IRE isoform within the cell body, and staining ofTfR within the dendrites is more intense. As illustrated in Figure8, B and D, and as noted above, the +IRE form of DMT1 is foundin vesicles distributed relatively uniformly within the cytosoland infrequently distributed on the cell surface. TfR also appearsto be present on the cell surface without the +IRE transporter.Comparison of TfR to the +IRE isoform of DMT1 in sections wherethe nucleus is visible (Fig. 8B) again reveals that neither antibodystains the nucleus.

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Figure 8. Confocal fluorescence micrographs of cultured rat sympathetic neurons treated for 5 d with BMP7 immunostained with antibodies specific for the $-$ IRE (A, C) and +IRE (B, D) species of DMT1 and TfR. Green and red denote TfR and DMT1, respectively. Orange and yellow patches represent areas in which TfR and DMT1 are colocalized. In the two optical sections (A, B), near the substratum on which the cells were grown, neurites are visible; in C and D, which are well above the substratum, staining patterns of the nucleus are most visible.

Subcellular localization of +IRE and $-$ IRE forms of DMT1 in HEK293T cells

Because enterocytes were reported to lack nuclear staining for DMT1 (Trinder et al., 2000), studies were also performed todetermine the subcellular distribution of these transporters inother non-neuronal cell preparations. These studies also serveas a means of further testing the specificity of these antibodiesand determining whether they cross-react with human DMT1 isoforms.Initial studies with HEK293T cells that were transfected withthe $-$ IRE construct of DMT1 demonstrate that the $-$ IRE-specificantibody is capable of cross-reacting with human DMT1 (Fig. 9).Untransfected cells exhibited a relatively low level of expressionof this form of DMT1. Approximately 20% of the cells were successfullytransfected, as indicated by a large increase in immunostainingwith the $-$ IRE form of DMT1. Unlike the observed distribution patternseen with the neuronal cell lines described above, staining exclusivelymanifested only in vesicles within the cell body and/or on thecell membrane, with a total absence of nuclear staining. The stainingpattern for the +IRE species of nontransfected HEK293T cells wasalso weak (Fig. 9B) and, as anticipated, did not change in cellstransfected with the $-$ IRE construct of DMT1. These results verifythe specificity of both the +IRE and $-$ IRE antisera and their abilityto cross-react selectively with the two isomers of human DMT1and demonstrate the absence of nuclear staining of the $-$ IRE speciesin HEK293T cells even when ectopically overexpressed.

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Figure 9. Confocal fluorescent micrographs of cultured HEK293T cells transfected with a construct of $-$ IRE DMT1 immunostained with antibodies specific for the $-$ IRE (A) and +IRE (B) species of DMT1. The more heavily stained cells seen with the $-$ IRE antibody correspond to cells successfully transfected with the $-$ IRE form of DMT1. No nuclear staining was observed in all cells, including those overexpressing the $-$ IRE isoform of DMT1.

Subcellular localization of +IRE and $-$ IRE forms of DMT1 in other cultured cells

The subcellular distribution of the two forms of DMT1 was also assessed in rat Schwann cells that are present when rat sympatheticneurons are grown in the absence of an antimitotic agent. As illustratedin Figure 10, staining of the $-$ IRE species of the transporter inrat Schwann cells was rather diffuse and evenly distributed throughoutthe cell in both the cytoplasm and nucleus, and unlike in thesympathetic neuronal cultures, there was no excess accumulationof this form of DMT1 in the nucleus. The absence of the antimitoticagent in the cultures does not account for the lack of nuclearstaining of the Schwann cells, because neuronal cells coculturedin the presence of these cells exhibited intense nuclear staining(results not shown). As illustrated in Figure 8B, staining ofthe +IRE form of DMT1 in Schwann cells was also diffuse throughoutthe cell body, although there was clearly a decreased signal inthe nucleus of these cells. In addition, we examined the $-$ IREand +IRE DMT1 staining pattern in several human cell lines, includingHEP2G hepatoma cells (Fig. 10C,D) and medulloblastoma cells (Fig.11A,B), to determine whether the antibody preparations would displaythe same subcellular distribution of DMT1 in non-neuronal andneuronal cells from human tissues. There was diffuse cytoplasmicstaining of both the +IRE and $-$ IRE species of DMT1 in the HEP2Gcells, but no nuclear staining was observed. In contrast, onlythe $-$ IRE isoform of DMT1 of human medulloblastoma cells displayednuclear staining (Fig. 11, compare A, B). The phase-contrast images(Fig. 11C,D) reveal that the nuclei of these cells are extremelylarge and represent a major portion of the cell volume. Thesedata reaffirm that the two antibody preparations are capable ofselectively recognizing appropriate epitopes on the +IRE and $-$ IREforms of human DMT1 and again support the previous data that the $-$ IRE species of this transporter preferentially distributes tothe nucleus in neuronal and neuronal-like cells. This is furthersupported by studies demonstrating that the $-$ IRE species is presentin the nucleus of rat dorsal root ganglion cells but is absentin isolated pancreatic islet cells (data not shown).

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Figure 10. Confocal fluorescent micrographs of rat Schwann cells (A, B) and human HEP2G cells (C, D) immunostained with antibodies specific for the $-$ IRE (A, C) and +IRE (B, D) species of DMT1.

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Figure 11. Confocal fluorescent micrographs of human medulloblastoma cells immunostained with antibodies specific for the $-$ IRE (A) and +IRE (B) species of DMT1 along with the corresponding phase-contrast images (C, D).

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We have previously shown that exposure of PC12 cells to manganese causes cell death in a time- and concentration-dependentmanner (Roth et al., 2000). Our finding that cell death is associatedwith a decrease in ATP levels implies that intracellular levelsof manganese may be mediating toxicity. Thus, the mechanism bywhich manganese is transported into PC12 cells becomes of primeimportance, and our initial studies focused on determining whetherthese cells contain one or both isoforms of DMT1. Results fromRT-PCR, immunoblots, and immunocytochemical studies confirm thepresence of both forms of the transporter in PC12 cells. Usingaffinity-purified antibody preparations selective for each formof DMT1, we demonstrated that both species of the transporterpossess a molecular weight of ~65 kDa, in agreement with the expectedvalue based on the known amino acid sequence for the two proteins.A range of values from 52 to 90-116 kDa has been previously reported(Su et al., 1998; Canonne-Hergaux et al., 1999; Gruenheid et al.,1999; Tabuchi et al., 2000; Trinder et al., 2000). The differencesprobably reflect variations in source, preparation, glycosylation,and means of detection. Our size matches that found by Tabuchiet al. (2000) in COS-7cells.

Immunocytochemical experiments clearly demonstrate that the two proteins are distributed in different subcellular compartments.The accumulation of the $-$ IRE isoform in the nucleus of neuronalcells is the most surprising finding, whereas the +IRE form waspresent on the cell membrane and dispersed in a punctate mannerwithin the cell but absent from the nucleus. A similar stainingpattern was observed with cultured rat sympathetic neurons. Immunoblotstudies are consistent with this in that only the $-$ IRE speciesis present in isolated nuclei of PC12 cells. Consistent with thisis the recent finding demonstrating the nuclear staining of DMT1in COS-7 cells using a nonselective antibody to common epitopeson the N-terminal region for both isoforms of the transporter(Tabuchi et al., 2000). In contrast, when COS-7 cells were transfectedwith chimeric green fluorescent protein (GFP)-DMT1, labeling wasdetected in late endosomes but not in the nucleus. This resultis again consistent with our findings, because the GFP-DMT1 chimericDNA contained the +IRE form of human DMT1, allowing one to inferthat only the $-$ IRE form is capable of accumulating within thenuclei. Interestingly, the nuclear signal is called p66, indicatingthat it has a size similar to that reportedherein.

The different staining patterns observed for the two species of DMT1 are not artifacts, because peptides used to prepare thetwo antibodies were able to inhibit their respective signals selectivelyin the sympathetic neurons. In addition, a PSI-Blast search ofthe GenBank database for the specific $-$ IRE peptide sequence usedto generate the antibody returned only DMT1 as containing therelevant amino acid sequence. Specificity of the affinity-purifiedantibody preparations was also confirmed by the fact that onlythe $-$ IRE antibody detected expression of a $-$ IRE DMT1 constructafter transient transfection of HEK293T cells. All of this evidencesupports the conclusion that staining of the nucleus is, mostlikely, caused by the presence of the $-$ IRE isoform of DMT1 inthe nucleus in both PC12 cells and rat sympatheticneurons.

Colocalization experiments of the +IRE and $-$ IRE forms of DMT1 with that of TfR demonstrate that these proteins generally donot colocalize extensively within the cells. TfR predominatesin vesicles both within the cell body and in dendrites of ratsympathetic neurons. The +IRE isoform of DMT1 only partially colocalizedwith TfR in both the cell body and neurite extensions, althoughboth proteins are excluded from the nucleus. The +IRE form ofDMT1 distributed relatively uniformly within the cell body butnot on the cell surface, whereas TfR is found preferentially onthe cell surface and in perinuclear vesicles considered to berecycling endosomes (Mellman, 1996). The $-$ IRE isoform of DMT1and TfR also clearly display distinct distribution patterns inthese neuronal cells. As noted above, most of the $-$ IRE speciesappear in both the nucleus and the cell surface, including thatof the dendrites and axons extensions. There is considerably lessassociated with the cell body, where it is not concentrated inperinuclear vesicles such as TfR. TfR, however, does appear tocolocalize with the $-$ IRE form of DMT1 on the cell surface, althoughTfR also appears on the surface independent of this species ofDMT1. The modest colocalization of TfR observed with either speciesof DMT1 is somewhat surprising, because TfR is presumed to workin synchrony with DMT1 to facilitate transport of iron and otherheavy metals into the cell. This implies that DMT1 may have differentfunctions with regard to iron distribution throughout the cell.During the course of our studies, a paper appeared by Tabuchiet al. (2000) indicating that TfR and DMT1, detected by commonepitopes on the N-terminal sequence, colocalize to only a modestextent in HEp2 cells, implying that DMT1 predominantly residesin the lateendosomes.

Studies were also performed to see whether nuclear accumulation of the $-$ IRE species would occur in the nucleus of other celltypes maintained in culture. Staining in Schwann cells was diffuseand observed in equal levels in both the cytoplasm and nucleus.These results indicate that the presence of the $-$ IRE form of DMT1in the nucleus of neurons is not simply dependent on culture conditionsthat often vary between cell lines. Thus, neuronal or neuronal-likecells appear preferentially to concentrate the $-$ IRE form of DMT1in the nucleus. Results with human HEK293T, HEP2G, and medulloblastomacells also confirm that the two affinity-purified polyclonal antibodypreparations can cross-react with human DMT1. The same uniquesubcellular distribution of the two isoforms of DMT1 observedwith rat cells is also observed with human cells, confirming thatthis distribution is independent of mammalianspecies.

As noted above, Tabuchi et al. (2000) found DMT1 to associate primarily with late endosomes, although they did not distinguishbetween the two isoforms. Transfection studies similar to ourswith epitope-tagged protein by Su et al. (1998) also failed toidentify DMT1 in the nucleus of HEK293T cells. Similarly, Gruenheidet al. (1999), using anti-DMT1 that recognized epitope(s) commonto both species of DMT1, detected a signal for both transferrinand DMT1 in endosomes but not in nuclei in Chinese hamster ovarycells, RAW cells, MEL cells, and TM4 cells. Subsequently, Trinderet al. (2000), using antibodies to a common epitope, noted thatDMT1 is not found in nuclei of hepatic and gastrointestinal tissues.Canonne-Hergaux et al. (1999), also using antibodies to a commonepitope, found that the transporter predominates near the apicalsurface of duodenal cells. These studies are consistent with thefindings presented in this manuscript demonstrating the selectivelocalization of the $-$ IRE form of DMT1 in nuclei of neuronal cellsor cells of neuronal origin. However, because we do not understandthe mechanisms directing the transport of this protein to thenucleus, at this point we cannot exclude the possibility thatother cells may also present a similar pattern of distributionfor the $-$ IRE species of DMT1. Thus, as noted above, the possibilitythat it may also occur in the nucleus of COS-7 cells deservesmoreinvestigation.

The concept of DMT1 has changed from its pre-1997 identity as a protein similar in sequence to Nramp1 (Gruenheid et al., 1995)to recognition of its role as a major duodenal ferrous iron transporter(Fleming et al., 1997; Gunshin et al., 1997, 1998) and exporterof ferrous iron (Garrick et al., 1993; Fleming et al., 1998) andother divalent metals (Gunshin et al., 1997) from endosomes aswell as its role in the transferrin-independent uptake of iron(Hodgson et al., 1995; Garrick et al., 1999). We have found thatthe +IRE form of DMT1 localizes in neurons and other cells ina manner consistent with a role in iron uptake and possibly witha role in the uptake of other metals. In particular, the +IREform is present on the cell surface and is within vesicles indendrites and axons and the cell body in a distribution consistentwith that of a subpopulation of endosomes but is not located inthe nuclei. The $-$ IRE form, however, is found in nuclei of neuronsas well as on the cell surface, although it has a more expecteddistribution (i.e., not enriched in nuclei) in a variety of non-neuronalcells. This unexpected finding leads us to postulate that thetwo isoforms have different functions, at least in neurons. Thenuclear localization of the $-$ IRE form could imply that it (1)sequesters a divalent metal within nuclei, (2) transports divalentmetals to nuclei, or (3) carries a signal (presumably relevantto metal homeostasis) to the nuclei. Studies are currently underway to characterize the structural components of this form ofDMT1, investigating its nuclear localization and the role of thisprotein in regulating the entrance of divalent metals into thenucleus.

  FOOTNOTES

Received May 31, 2000; revised July 19, 2000; accepted July 27, 2000.

This work was funded by US Environmental Protection Agency Grant R26248010 (J.A.R.), National Science Foundation Grant BNS8909373 (D.H.), and National Institutes of Health Grant HL48690(M.D.G.). We thank Dr. Wade Sigurdson for expert technical assistanceas the director of the Confocal Microscope and 3D Imaging Facilityat the University atBuffalo.
Correspondence should be addressed to Dr. Jerome A. Roth, Department of Pharmacology and Toxicology, 102 Farber Hall, Universityat Buffalo, Buffalo, NY 14214. E-mail: jaroth{at}buffalo.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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