J Biol Chem, Vol. 275, Issue 3, 1651-1655, January 21, 2000
Overexpression of the Ferritin Iron-responsive Element
Decreases the Labile Iron Pool and Abolishes the Regulation of Iron
Absorption by Intestinal Epithelial (Caco-2) Cells*
Marco A.
Gárate and
Marco T.
Núñez
From Departamento de Biología, Facultad de Ciencias,
Universidad de Chile, and Millennium Institute for Advances Studies in
Cell Biology and Biotechnology, Casilla 653, Santiago, Chile
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ABSTRACT |
Mammalian cells regulate iron levels tightly
through the activity of iron-regulatory proteins (IRPs) that bind to
RNA motifs called iron-responsive elements (IREs). When cells become
iron-depleted, IRPs bind to IREs present in the mRNAs of ferritin
and the transferrin receptor, resulting in diminished translation of
the ferritin mRNA and increased translation of the transferrin
receptor mRNA. Likewise, intestinal epithelial cells regulate iron
absorption by a process that also depends on the intracellular levels
of iron. Although intestinal epithelial cells have an active IRE/IRP system, it has not been proven that this system is involved in the
regulation of iron absorption in these cells. In this study, we
characterized the effect of overexpression of the ferritin IRE on iron
absorption by Caco-2 cells, a model of intestinal epithelial cells.
Cells overexpressing ferritin IRE had increased levels of ferritin,
whereas the levels of the transferrin receptor were decreased. Iron
absorption in IRE-transfected cells was deregulated: iron uptake from
the apical medium was increased, but the capacity to retain this newly
incorporated iron diminished. Cells overexpressing IRE were not able to
control iron absorption as a function of intracellular iron, because
both iron-deficient cells as well as iron-loaded cells absorbed
similarly high levels of iron. The labile iron pool of IRE-transfected
cell was extremely low. Likewise, the reduction of the labile iron pool
in control cells resulted in cells having increased iron absorption.
These results indicate that cells overexpressing IRE do not regulate
iron absorption, an effect associated with decreased levels of the
regulatory iron pool.
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INTRODUCTION |
Intestinal epithelial cells respond to a fall in body iron stores
by increasing the absorption of dietary iron, so the extent of iron
transport through the intestinal epithelium is inversely related to the
content of body iron stores (1-3). Knowledge of the molecular
mechanisms involved in the regulation of transepithelial iron
transport through the intestine remains elusive, in part because of the
heterogeneity in age and iron content of intestinal cells. The use of
cultured human cell lines that undergo spontaneous differentiation to
enterocytes helps to bypass this problem because they represent cell
populations homogeneous in age. In particular, Caco-2 cells have been
described as an excellent in vitro model of human
enterocytes (4, 5). Caco-2 cells grown on bicameral inserts exhibit
both apical iron uptake (3, 4) and transferrin-mediated basolateral
iron uptake (6). Caco-2 cells reduce Fe3+ to
Fe2+ in the apical medium, and this reduction correlates
with increased iron uptake (7, 8). Moreover, the levels of
intracellular iron (3) control the mechanisms responsible for the
regulation of iron absorption through as yet unknown mechanisms.
Iron-regulatory proteins
(IRPs)1 are cytosolic
proteins that bind to structural elements, named iron-responsive
elements (IREs). These IREs are present in the untranslated region of
mRNAs that codify for ferritin, the transferrin receptor, and
aminolevulinate synthase (9-16). Based on the structure of
mitochondrial aconitase (17), IRP1 (relative mobility 98 kDa) has been
proposed to possess four domains, in which domains 1, 2, and 3 are
connected to domain 4 through a hinge region (for review, see Ref. 11).
The activities of both IRP1 and IRP2 respond to cellular iron through
different mechanisms. Low levels of intracellular iron cause IRP1 to
bind to, and stabilize, transferrin receptor (TfR) mRNA and to bind to ferritin mRNA, diminishing its translation (9-11), whereas IRP2
activity is regulated through iron-induced IRP2 ubiquitination and
proteasome degradation (16). Overexpression of a mutant IRP1
constitutively active in binding to IRE produced cells that express
high levels of TfR despite iron repletion (18). This was the first
direct demonstration of IRP1 involvement on the expression of proteins
of iron metabolism.
Intestinal cells have an active IRE/IRP system (19-21). Caco-2 cells
cultured to different intracellular iron concentrations regulate in a
concerted way IRP1 and IRP2 activities, apical iron uptake activity,
ferritin levels, and transferrin receptor density (19). Interestingly,
a fraction of the IRP-2 activity in Caco-2 cells was unresponsive to
iron overload, producing basal levels of apical iron uptake and TfR
(19). IRP activity was found normal in individuals with hemochromatosis
(20), and a decrease in ferritin expression took place in the duodenum
from individuals with idiopathic hemochromatosis or iron deficiency
anemia (21). High IRP activity was found in monocytes of patients with
hereditary hemochromatosis, an indication that one characteristic of
this disease might be a decrease of the labile iron pool (22). Hence, there is convincing evidence of the presence of an active IRE/IRP system in intestinal cells, but its role in the regulation of intestinal iron absorption is unclear.
Because intracellular iron is involved in regulating both IRP activity
and iron absorption, we tested the hypothesis that iron absorption is
regulated by the IRE/IRP system. Reasoning that excess IRE should
functionally abrogate the mRNA binding activity of IRPs, we
generated Caco-2 cells that overexpressed IRE and characterized the
ability of these cells to regulate iron absorption.
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EXPERIMENTAL PROCEDURES |
Reagents--
Anti-human transferrin antibody was from
Calbiochem. Fetal bovine serum, culture medium, deferrioxamine, DTPA,
NTA, culture media, buffers, and salts were purchased from Sigma.
59Fe and 55Fe, in the ferric chloride form,
[
- 32P]ATP, and [
-33P]UTP were from
NEN Life Science Products. Culture plasticware and Transwell bicameral
inserts were from Costar (Cambridge, MA). To eliminate contaminant
iron, all buffer solutions were filtered through Chelex-100 (Sigma).
Cell Culture--
Caco-2 cells, from the American Type Culture
Collection (HTB37, Rockville, MD), were cultured in DMEM supplemented
with 10% fetal bovine serum (FBS). Culture medium was changed every 2 or 3 days. Cells were treated with trypsin and replated once a week. For transport and binding experiments, cells were grown on
1-cm2 polycarbonate cell culture inserts, with 0.4-µm
pore size membranes. Cells grown for 12-14 days were used.
Subcloning of IRE and Cell Transfections--
The DNA encoding
for human H ferritin IRE (11) was obtained by amplifying the polylinker
segment of the pSPT-fer plasmid (10) by polymerase chain reaction using
T7 and Sp6 as primers (Life Technologies, Inc). After restriction with
EcoRI and XbaI, the main IRE segment, 5'-
AATTCCTGCTTCAACAGTGCTTGGACGGAATCCCGGGGATCCT-3', was cloned
into the polylinker of pcDNA3 (Invitrogen, San Diego, CA),
previously restricted with EcoRI and XbaI.
Restriction analysis of pcDNA3 and pcDNA-IRE plasmid with
HindIII and NotI demonstrated that the IRE was
inserted in the plasmid. The plasmid obtained was named
pcDNA-IRE.
Caco-2 cells grown to half-confluence (2-3 days after plating) were
transfected with equal amounts of either pcDNA-IRE or pcDNA3
plasmids. LipofectAMINE (Life Technologies, Inc.) at 5 µl/µg of DNA
was used for the transfections. The DNA/LipofectAMINE mixture was
removed after 36 h of incubation at 37 °C. The cells were
incubated overnight in DMEM and 10% FBS and then changed to a
selection medium, DMEM with 10% FBS plus 0.4 mg/ml Geneticin (Life
Technologies, Inc. G418). The cells were grown for three passages
(one-week growth, trypsin treatment, and replating) under these
conditions. Wild type Caco-2 cells did not grow under these conditions.
Transfected cells were stored in liquid nitrogen.
Analysis of IRE Levels--
Total cell RNA was isolated from
Caco-2 cells as described elsewhere (23), and equal amounts of RNA were
electrophoresed in 1.5% agarose under denaturing conditions. To
confirm that each line contained equal amounts of RNA, the ribosomal
content of each line was determined with ethidium bromide. RNA,
transferred to Hybond-N membranes (Amersham Pharmacia Biotech), was
hybridized with a 32P-labeled IRE probe, consisting of a
28-mer antisense sequence of ferritin IRE, end-labeled with [-
32P]ATP. As a positive control, the sense ferritin IRE
sequence was electrophoresed and hybridized with the above probe.
Assay of IRP Activity--
32P-Labeled IRE was
prepared by in vitro transcription of pSPT-fer (10) using T7
RNA polymerase (Life Technologies, Inc.) and
[-33P]UTP. The IRE binding activity of IRPs was
determined by a band shift assay as described (19), reacting 20 µg of
cell extract/assay with 4 × 105 cpm of
33P-labeled IRE.
Determination of Intracellular Ferritin
Levels--
Intracellular levels of ferritin were determined in Caco-2
cell extracts containing different concentrations of iron, using a
sandwich enzyme-linked immunosorbent assay as described (19). Polyclonal rabbit anti-human ferritin and peroxidase-labeled rabbit anti-human ferritin antibodies were purchased from DAKO Corporation (Carpinteria, CA).
Measurement of Transferrin Receptor Density--
Transferrin
receptor density was determined in cell extracts by an enzyme-linked
immunosorbent assay (24) using OKT9 anti-TfR monoclonal antibody as
primary antibody and peroxidase-labeled goat anti-mouse IgG (Sigma) as
secondary antibody.
Equilibrium Loading of Caco-2 Cells with
55Fe--
Cells with known concentrations of intracellular
iron were obtained as described (3). Briefly, Caco-2 cells were seeded at 5 × 105 cells/25-cm2 flask and
incubated for a week in low iron Iscove medium (Life Technologies,
Inc.) and 10% low iron serum ([iron] < 0.3 µmol/liter) (1),
supplemented with variable amounts of Fe3+ as the complex
55FeCl3-sodium nitrilotriacetate
(55Fe-NTA, 1:2 molar ratio). During this period the cells
reached confluence, with 2-4 × 106
cells/25-cm2 flask. The cells were trypsin treated and
seeded at a density of 1 × 105 cells/flask and
cultured as above. After a second trypsin treatment, the cells were
plated on 1-cm2 polycarbonate inserts (Transwell, COSTAR,
Cambridge, MA) and were cultured in media as before for 12-14 days,
with change of media every 3 or 4 days. When needed, the insert-grown
cells were transfected with pcDNA3-IRE 7 days before the
experiment. Measuring the transepithelial electrical resistance with an
EVOM epithelial voltohmmeter (World Precision Instruments, Sarasota,
FL) monitored the formation of a cell monolayer in the inserts. The
total intracellular iron concentration was estimated from the specific
radioactivity of the 55Fe in the medium and a cell volume
of 3 µl/1-cm2 insert (3).
Cell Extracts--
To prepare cell extracts, cells were treated
with lysis buffer (50 µl/1 × 106 cells of 10 mM HEPES, pH 7.5, 3 mM MgCl3, 40 mM KCl, 1 mM phenylmethylsulfonyl fluoride, 10 µg/ml leupeptin, 0.5 µg/ml aprotinin, 0.7 µg/ml pepstatin A, 5%
glycerol, 1 mM dithiothreitol, 0.5% Triton X-100). The
mixture was incubated for 15 min on ice and sedimented for 10 min at
10,000 × g. The supernatant was stored at 
70 °C,
and aliquots were used for the determination of ferritin, TfR density,
IRP activity, and IRP immunodetection.
59Fe Fluxes--
For 59Fe flux
experiments we used 55Fe-equilibrated cells (see above),
grown on 1-cm2 inserts transfected with either pcDNA3
or pcDNA3-IRE. At this time there were, on average, 600,000 cells/insert, and the transepithelial electrical resistance was
250-300 ohms × cm2. To ensure integrity of the cell
barrier, we measured the transepithelial electrical resistance of the
inserts at the beginning and at the end of each experiment, discarding
all inserts with transepithelial electrical resistance lower than 220 ohms × cm2 at the end of the experiment. Cells were
incubated at 37 °C for 30-120 min with 10 µM
Fe3+, as the 59Fe·NTA complex, added to the
apical medium. The incubation medium was low iron Iscove medium. Iron
uptake was stopped by washing the inserts three times with ice-cold
saline supplemented with 1 mM EDTA. 59Fe
radioactivity in the cells, and in the basolateral media, was measured
in a Cobra II gamma counter (Packard Instrument Co., Merident, CT).
Uptake was expressed as the rates (mol of 59Fe × h
1 × insert1), estimated by linear
regression fitting of the data.
Determination of the Labile Iron Pool--
The intracellular
pool of reactive iron of Caco-2 cells was determined as described by
Epsztejn et al. (25). Briefly, Caco-2 cells were cultured on
coverslips for 10 days in DMEM, 10% FBS. Calcein-AM (0.5 µM, Molecular Probes, Eugene, OR), was then loaded into
for 5 min at 37 °C. After washing the calcein that was not internalized, the cells were transferred to a cuvette containing 3 ml
of MOPS saline (20 mM MOPS-OH, 150 mM NaCl, 1.8 mM CaCl2, 5 mM glucose, pH 7.4) and
5 µl of anti-calcein antibody (the kind gift of Dr. Z. I.
Cabantchik). After determination of the basal calcein fluorescence
(excitation 488 nm, emission 517 nm), the fluorescence of the
calcein-iron complex was dequenched by addition of 100 µM
SIH. The increase in fluorescence thus obtained was directly
proportional to the iron labile pool. In the experiments indicated in
the text, the cells were preincubated for 2.5 h either in
iron-rich medium (DMEM, 10% FBS + 10 µM Fe·NTA) or in
iron-poor medium (Iscove, 10% low iron FBS) prior to calcein loading.
Data Analysis--
Variables were tested in triplicate wells,
and experiments were repeated at least twice. The variability between
experiments was <20%. Curve fitting was done using the GraphPad Prism
program (GraphPad Software Inc., San Diego, CA).
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RESULTS |
Cellular Levels of IRE, Ferritin, and TfR in IRE-transfected
Cells--
The cellular level of IRE was determined in cells
transfected with pcDNA3-IRE and in cells transfected only with
pcDNA3 (Fig. 1). After hybridization
with 32P-antisense IRE, cells transfected with plasmid
alone showed one band of about 800 nucleotides, most probably
corresponding to ferritin mRNA (26). Cells transfected with
pcDNA3-IRE evidenced a band of about 800 nucleotides and a lower
band of about 200 nucleotides (Fig. 1A). This lower band
most probably corresponds to IRE, as shown by its hybridization with
the antisense IRE. An assay of IRP activity showed decreased activity
in IRE-transfected cells compared with cell transfected with pcDNA3
or not transfected (Fig. 1B). The decreased activity could
be caused by competition of [33P]IRE binding by unlabeled
endogenous IRE. In fact, little or no decrease in IRP activity was
observed when 2 µg of cell extract was used per assay instead of the
20 µg used in the present assay (not shown).
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Fig. 1.
Characterization of IRE-transfected
cells. Panel A, Northern blot of pcDNA3 (control)
and pcDNA3-IRE-transfected cells. Insert-grown Caco-2 cells were
transfected with either pcDNA3 or pcDNA3-IRE. After 7 days in
culture, total RNA was obtained and separated in denaturant agarose
gels. The proteins were blotted to Hybond-N membranes and were
hybridized with a 32P-labeled IRE probe, in the antisense
sequence of ferritin IRE, end-labeled with [-32P]ATP.
Left lane, sense IRE sequence; center lane, cells
transfected with pcDNA3; right lane, cells transfected
with pcDNA3-IRE. Panel B, band shift assay of
pcDNA3-tranfected (lanes 1 and 4),
pcDNA3-IRE-transfected (lanes 2 and
5), and wild type (lanes 3 and 6)
Caco-2 cells, in the absence (lanes 1-3) or presence
(lanes 4-6) of  -mercaptoethanol (-ME).
Panel C, 55Fe content in control and
IRE-transfected cells, after culture of cells for 7 days in media
containing low (0.5 µM), medium (2 µM), and
high (5 µM) 55Fe. Panel D,
ferritin levels of control and IRE-transfected cells grown as in
panel C. Panel E, TfR levels in control and
IRE-transfected cells grown as in panel C.
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After a week in culture with different concentrations of
55Fe in the culture media, the intracellular concentration
of 55Fe in control cells varied according to a previously
established pattern (3). For the experiment shown in Fig.
1C, the intracellular iron concentrations in cells grown in
culture media containing 0.5, 2, or 5 µM 55Fe
were 21.6, 62.3, and 243.5 µM, respectively. In contrast,
the intracellular concentration of 55Fe in IRE-transfected
cells remained relatively constant, regardless of the concentration of
iron in the culture. Intracellular 55Fe concentrations of
207.1, 210.1, and 238.3 µM were found for cells grown in
0.5, 2, or 5 µM 55Fe, respectively (Fig.
1C). At low intracellular iron concentration, the cell
ferritin concentration in IRE-transfected cells was higher than in
control cells, as expected from IRE binding to active IRP and hence
inhibiting IRP binding to the IRE motif in ferritin mRNA. Only at
high intracellular iron levels was the ferritin content equal in
control and IRE-transfected cells (Fig. 1D). At low
intracellular iron levels, TfR levels were about 2-fold lower in
IRE-overexpressing cells compared with control pcDNA3-transfected cells (Fig. 1E), probably reflecting the lack of
stabilization of TfR mRNA. Furthermore, TfR levels in
IRE-transfected cells did not change in response to changes in
intracellular iron, whereas control cells showed a significant decrease
with increasing cell iron (Fig. 1E). These results indicate
that in relation to control cells, cells transfected with
pcDNA3-IRE up-regulated their ferritin content, down-regulated
their TfR levels, and both ferritin and TfR levels did not change with
changes in cellular iron.
IRE-transfected Cells Have Deregulated Iron Transport
Activity--
Prior evidence indicates that IRP-1 activity, IRP-2
mass, TfR density, ferritin levels, and transepithelial iron transport respond similarly to changes in intracellular iron concentration (19).
These results suggest that a common iron-responsive factor regulates
both intracellular iron levels and iron absorption by Caco-2 cells.
Thus, it was of interest to study apical iron uptake and
transepithelial iron transport as a function of intracellular iron
concentration in IRE-transfected cells. For this purpose, control and
transfected cells were grown in bicameral inserts, and their capacities
for apical 59Fe uptake and transepithelial 59Fe
transport activities were compared (Fig.
2). The rate of 59Fe uptake
by IRE-transfected cells was about twice as large as that of control
cells (Fig. 2A). Most of the extra 59Fe taken up
by IRE-transfected cells was found in the basolateral medium (Fig.
2B). Thus, IRE-transfected cells behaved like iron-deficient cells, with elevated apical iron uptake and efficient transfer of iron
to the basolateral medium (3). Compared with control cells,
IRE-transfected cells retained slightly higher amounts of newly
entering 59Fe (Fig. 2B, filled
columns), probably a reflection of their increased ferritin
levels.
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Fig. 2.
59Fe uptake by IRE-transfected
cells. Panel A, kinetics of transepithelial
59Fe transport by control and IRE-transfected cells.
Insert-grown pcDNA3 or pcDNA3-IRE Caco-2 cells were incubated
with 10 µM 59Fe·NTA in the apical medium,
and the amount of 59Fe radioactivity found in the
basolateral medium was determined as a function of the incubation time.
The rates of 59Fe transport to the basolateral medium,
estimated from the slopes of the curves, were 6.0 ± 0.3 pmol × h1, and 13.7 ± 0.8 pmol × h1, for cells transfected with pcDNA3 and
pcDNA3-IRE, respectively. Panel B, 59Fe
distribution in cells and basolateral medium after incubation for
3 h with 10 µM 59Fe·NTA in the apical
medium. Data shown are the mean ± S.D. of three independent
experiments.
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The increased apical iron uptake could be caused by increased
expression of a putative apical iron transporter or increased activity
of the transporter. In the latter case, it is possible that the high
levels of ferritin and the low levels of TfR induced by IRE
overexpression resulted in low levels of the regulatory iron pool,
which in turn should result in the shifting of the chemical equilibrium
toward the entry of iron during apical iron uptake. Hence, we
determined the regulatory, or labile, iron pool of cells subjected to
varied manipulations (Fig. 3). Whereas
wild type and pcDNA3-transfected cells presented a sizable labile
iron pool (Fig. 3, A and D), cells transfected
with pcDNA3-IRE had a very small iron labile pool (Fig.
3E). The labile iron pool was diminished in cells
preincubated in low iron medium (Fig. 3B) and was increased
in cells preincubated in high iron medium (Fig. 3C).
Mean values, in arbitrary fluorescence units, for five independent
determinations were 190, 70, 338, 184, and 22, for normal, high iron,
low iron, pcDNA3-transfected, and pcDNA3-IRE-ransfected cells,
respectively.
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Fig. 3.
Determination of the labile iron pool.
Wild type Caco-2 cells (A-C), Caco-2 cells transfected with
pcDNA3 (D), or cells transfected with pcDNA3-IRE
(E), were grown in glass coverslips for 10 days in DMEM,
10% FBS. The labile iron pool was then measured either directly
(A, D, and E) or after incubation for
2.5 h in a iron-poor medium (B) or a iron-rich medium
(C). SIH is a membrane-permeant iron chelator that takes
iron from the calcein-iron chelate thus increasing calcein
fluorescence. Therefore, the level of the cellular labile iron pool is
directly proportional to the increase in SIH-induced calcein
fluorescence. Shown are representative traces of intracellular calcein
fluorescence. The right column shows the mean ± S.D.
of fluorescence changes in arbitrary fluorescence units ( AFU), for
six determinations.
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The decrease in the labile iron pool could be the cause of the
increased iron uptake observed in IRE-transfected cells, because a low
intracellular iron pool should drive the transport of iron toward the
cell interior. To test this hypothesis, the regulatory iron pool of
control cells was decreased by preincubation of the cells in iron-free
culture medium prior to the 59Fe transport assay.
Preincubation of Caco-2 cells in iron-free media induced a doubling in
the rate of apical to basolateral 59Fe transport after
5 h of preincubation, whereas preincubation of IRE-transfected
cells did not induce it (Fig. 4). Hence,
manipulation of the regulatory iron pool induced in Caco-2 cells a
quick response in the rate of apical iron uptake and transepithelial
iron transport. This response was abrogated in Caco-2 cells
overexpressing IRE.
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Fig. 4.
59Fe uptake by iron-depleted
cells. Wild type or IRE-transfected insert-grown Caco-2 cells were
preincubated for the times indicated in the figure in Iscove iron-free
medium, after which 59Fe transport was carried out for 60 min as described under "Experimental Procedures." The figure shows
59Fe apical to basolateral transport as a function of the
preincubation time in iron-free medium.
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DISCUSSION |
The cellular level of iron is regulated by the activity of
proteins known as IRPs. IRPs bind to hairpin motifs present in the
mRNA of several key proteins of iron metabolism, such as ferritin and TfR, modulating their translation. Because both the mRNA
binding activity of IRPs and iron uptake by intestinal epithelial cells are regulated by the cellular level of iron, in this study we investigated if the activity of the IRE/IRP system regulates intestinal iron absorption. To that end, we overexpressed IRE in Caco-2 cells, reasoning that by binding to available IRP, excess IRE should functionally decrease or eliminate IRP mRNA binding activity. This
approach was preferred to the expression of dominant negative IRP,
because intestinal cells have both IRP1 and IRP2, so cells should be
transfected with both IRP1 and IRP2 dominant negative genes to abrogate
IRP activity.
We found that regardless of the extracellular iron concentration
present during cell culture, cells overexpressing IRE presented constitutively high levels of intracellular iron, probably the result
of high ferritin levels (Fig. 1). But, contrary to expectations, apical
59Fe uptake was higher in IRE cells than in control cells
(Fig. 2). Because the passage of iron from the lumen of the intestine into the enterocyte is mediated by one or more membrane iron
transporters (27-29), the increased iron uptake observed in IRE cells
could be the result of increased expression of the transporters or
their increased activity. Two mammalian membrane iron transporters have been cloned, DCT1, also named Nramp2, (27, 28), and SFT (29). DCT1 is
an electrogenic cation-H+ co-transporter with high levels
of transcripts in kidney and the microvilli region of intestine (27).
STF is an iron transporter identified by expression cloning of a K562
library, found in perinuclear vacuolar structures resembling recycling
endosomes (29). The tissue and cellular locations of DCT1 and SFT
indicate that the primary function of STF may be the acquisition of
transferrin-derived iron through the endocytosis process, whereas the
function of DCT1 may be the apical transport of iron by intestinal
epithelial cells. Although the mRNA of STF does not have an IRE
motif, alternative splicing of DCT1 produces a DCT1 without IRE and a
DCT1 with one IRE motif in its 3'-untranslated region (30). If, by
analogy with TfR mRNA, the binding of IRP stabilizes DCT1(IRE)
mRNA, then decreased translation of this mRNA should be
expected in Caco-2 IRE cells.
The results found in this work indicate that apical iron transport
activity was increased in Caco-2 cells overexpressing ferritin IRE.
Therefore, any effect of IRE overexpression on decreasing DCT1(IRE)
mass was overcome by its effects on other component(s) involved in the
iron absorption process. Indeed, the high levels of ferritin and the
low levels of TfR induced by IRE overexpression resulted in very low
levels of the labile iron pool. This decrease should result in a
favorable chemical gradient for the entry of iron during apical iron
uptake. This favorable gradient may underlie the observed increase in
apical iron uptake by Caco-2-IRE cells. Nevertheless, the possible
participation of some yet not described IRE-containing element that
might exert a negative control on iron absorption cannot be discarded.
Decrease of the labile iron pool after a short preincubations in low
iron media produced a marked increase in transepithelial iron
transport. A correlate to these findings is found in the observation
that rats subjected to short term dietary iron depletion respond with a
quick increase in iron absorption, as if they were anemic (31). So it
is possible that the lowering of the labile iron pool sets in the cells
an "anemia signal," triggering, as a response, increased iron absorption.
In summary, Caco-2 cells overexpressing IRE presented elevated levels
of ferritin and diminished levels of TfR, as expected if excess IRE
should bind to active IRP and abolish IRP control of ferritin and TfR
synthesis. Moreover, IRE-overexpressing cells presented constitutively
low levels of the labile iron pool and high rates of apical iron uptake
and transepithelial iron transport. Thus, the present results indicate
that the IRE/IRP system regulates intestinal iron absorption through
the regulation of the labile iron pool.
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ACKNOWLEDGEMENTS |
We are grateful to Dr. Prem Ponka for
providing SIH.
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FOOTNOTES |
*
This work was supported by Fondo Nacional de Ciencia y
Tecnología Grants 1970465 and 2970003 and by a Cátedra
Presidencial en Ciencia (to M. T. N.)The costs of publication of this
article were defrayed in part by the
payment of page charges. The article must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
To whom correspondence should be addressed. Tel.: 56-2-678-7360;
Fax: 56-2-271-2983; E-mail: mnunez@abello.dic.uchile.cl.
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ABBREVIATIONS |
The abbreviations used are:
IRP(s), iron-regulatory protein(s);
IRE(s), iron-responsive element(s);
TfR, transferrin receptor;
DTPA, diethylenetriaminepentaacetic acid;
DMEM, Dulbecco's modified Eagle's medium;
FBS, fetal bovine serum;
NTA, nitrilo triacetate;
MOPS, 4-morpholinepropanesulfonic acid;
SIH, isonicotinoyl hydrazone;
DCT, divalent cation transporter;
STF, stimulator of iron transport.
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