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PLENARY PAPER
From INSERM U409 and INSERM U327, Faculté Xavier
Bichat; and Service d'Hématologie et d'Immunologie Biologiques,
and Service d'Anatomo- Pathologie, CHU Bichat, Paris, France; and
DIBIT, Department of Biological and Technological Research, IRCCS, San
Raffaele, Milan, Italy.
Ferritin, the iron-storing molecule, is made by the assembly of
various proportions of 2 different H and L subunits into a 24-mer
protein shell. These heteropolymers have distinct physicochemical properties, owing to the ferroxidase activity of the H subunit, which
is necessary for iron uptake by the ferritin molecule, and the ability
of the L subunit to facilitate iron core formation inside the protein
shell. It has previously been shown that H ferritin is
indispensable for normal development, since inactivation of the H
ferritin gene by homologous recombination in mice is lethal at an early
stage during embryonic development. Here the phenotypic analysis of the
mice heterozygous for the H ferritin gene
(Fth+/ Iron is essential to all living organisms. However,
it is poorly soluble at physiological pH and reacts with oxygen,
catalyzing the formation of potentially toxic reactive oxygen species.
Therefore, living organisms have developed ferritin, a highly
specialized molecule that can sequester iron in a nontoxic and readily
available form. Ferritins are made of 24 subunits assembled into a
protein shell that delimits an internal cavity where iron can
accumulate in large amounts.1 Mammalian ferritins are
heteropolymers of 2 subunit types, the H and the L chains. A third
subunit, the G subunit, is also found in serum but is thought to derive
from the L subunit through glycosylation during the secretion
process.2 Although the mechanism of serum ferritin
production is not fully understood, serum ferritin levels are a good
index of tissue iron stores. H and L ferritin subunits are encoded by 2 separate genes that are under specific transcriptional regulations. The
L gene has very little tissue-specific regulations whereas multiple
conditions activate H ferritin gene transcription,3
including cell differentiation, changes in the cell proliferation
status, oncogenes, cytokines, and heme. Iron does not change the
transcription rate of the H gene whereas it stimulates transcription of
the L gene, at least in the liver.4 However, the
translation of both H and L ferritin messenger RNAs (mRNAs) is
regulated by iron, through interactions between the iron regulatory
element (IRE) motif present in the 5' noncoding region of these mRNAs
and cytoplasmic iron sensors, called iron regulatory proteins
(IRPs).5 In the absence of iron, IRP1 and IRP2 have a high
RNA-binding affinity and their interaction with IRE motifs repress
ferritin mRNA translation and ferritin synthesis. Increase in the
intracellular iron pool leads to a change in IRP1
conformation6 or degradation of IRP27 and
subsequent translation of ferritin mRNAs. The translation of both H and
L ferritin mRNAs is generally considered to be activated by iron,
although tissue-iron overload progressively leads to the preferential
synthesis of L-rich isoferritins. This is usually accompanied by a
progressive increase in serum ferritin levels, and serum ferritin
determinations are widely used in clinics and have become part of the
routine assessment of body iron stores. It has become increasingly
evident that several clinical conditions can be associated with
elevated serum ferritin levels in the absence of iron overload,
although the origin of these hyperferritinemias is not fully
understood, with the exception of the hereditary hyperferritinemia-cataract syndrome. In this pathological condition, a
point mutation in the IRE of the L ferritin gene impairs the negative
feedback regulation that normally operates on ferritin synthesis in
conditions of low iron entry into the cells.8-10 This
results in inappropriate L ferritin synthesis in most tissues and
increased serum ferritin levels. The abnormal accumulation of iron-free
L ferritin in the lens is probably responsible for the onset of
cataract, by a mechanism that is not yet known. Besides cataracts, the
patients do not present any signs of abnormal iron metabolism,
suggesting that the L ferritin homopolymers that accumulate in the
various tissues are probably nonfunctional and do not interfere with
the normal cell iron metabolism. Measurements of iron uptake by
immortalized lymphoblastoid cells from patients with
hyperferritinemia-cataract syndrome have indeed confirmed this
hypothesis.11 Although ferritin has long been considered
to be the protein solely implicated in the constitution of iron stores,
it has now become evident that ferritin function extends well beyond
iron storage. The broad range of ferritin functions results from the
formation of functionally distinct heteropolymers, with different
subunit composition. The H subunit contains a ferroxidase center that
catalyzes Fe(II) oxidation, whereas the L subunit has no catalytic
activity but facilitates nucleation and mineralization of the iron
core.12 Experimental cellular models in which ferritin has
been overexpressed by transfection have shown that the H subunit has an
active role in chelating the intracellular iron pool.13,14
H ferritin-mediated depletion of the intracellular iron pool offers a
better protection of the cells against oxidative
stress14,15 and also impairs the cell
proliferation.16 Our observation that inactivation of the
H ferritin gene by homologous recombination in the mouse is lethal
during embryonic development has highlighted the lack of functional
redundancy between the 2 subunits.17 Homozygous mutants
for the H ferritin gene (Fth) die in utero between 3.5 and
9.5 days of gestation, suggesting that the complete absence of H
ferritin subunits is incompatible with life. On the other hand, the
heterozygous Fth+/ Animals
Histology
Electron microscopy For electron microscopy, tissues were cut into 1-µL blocks and immediately fixed in 2.5% glutaraldehyde-buffered solution (phosphate-buffered saline, pH 7.4) for 2 hours at +4°C. After washing in PBS, blocks were fixed for 2 hours in 1% buffered osmium tetroxide solution, dehydrated in graded series of ethanol, and embedded in epoxy resin. Semithin sections stained with toluidine blue were made on each block for orientation. Ultrathin sections stained with uranyl acetate and lead citrate were examined with a Jeol 1010 electron microscope (Tokyo, Japan). To identify electron-dense iron-containing granules, counterstaining was omitted in some cases.Tissue homogenization Mice tissues were collected, weighed, minced, and dissolved in 10 mL lysis buffer (20 mM Tris-HCl, pH 7.4, 1 mM sodium azide, 1 mM phenylmethyl sulfonyl fluoride, 10 µM leupeptin, 1 µM pepstatin, 1 mM benzamidin) per gram of wet tissue. Tissue homogenizer or sonication was used to disrupt the cells. Debris was precipitated by centrifugation at 10 000 rpm for 10 minutes. All the steps were performed at +4°C. Supernatants were use to determine iron and ferritin contents or, in some cases, to analyze IRE/IRP interactions. Protein concentration was determined with BCA reagent (Pierce) with the use of bovine serum albumin (BSA) as standard.Measurement of tissue iron Iron concentration was determined by atomic absorption spectrometry on a Spectra-A 4440 (Varian, Palo Alto, CA) as previously described.18Enzyme-linked immunosorbent assay for tissue H and L ferritin subunit determination Ferritin concentration was determined by enzyme-linked immunosorbent assays (ELISAs) specific for the H and L chains as previously described.18 Microtiter plates were coated with 1 µg polyclonal antibody specific for mouse H or L-chain ferritin. Soluble mouse-tissue homogenates or standard ferritins were diluted in PBST-BSA (50 mM sodium phosphate, pH 7.4, 150 mM NaCl, 0.05% vol/vol Tween-20, 1% BSA), and added to the plates. The presence of ferritin was revealed by incubation with the same antibody labeled with horseradish peroxidase. Peroxidase activity was developed with o-phenylenediamine dihydrochloride (Sigma). Standard ferritins consisted of recombinant mouse H or L ferritin subunits.Measurement of serum iron and ferritinemia We punctured 0.5 to 1 mL blood at the time of killing through the abdominal aorta onto dry tubes. Serum was collected after coagulation and centrifugation. Serum iron levels were determined by spectrophotometry with the FlexFer kit (Dabe Behring, Newark, DE). Serum L ferritin was measured by means of the the L-subunit-specific ELISA described above, with a minor modification. When necessary, serum dilutions were performed by means of a commercial diluant provided with the kit for human serum ferritin assays (Dabe Behring), instead of the PBST-BSA solution used for tissue extracts.RNAse protection assay Total RNA from mouse tissues was isolated by means of RNAplus (Q.Biogene, Illkirch, France). For quantification of L ferritin mRNA, a genomic fragment containing exon 1 from the mouse L ferritin gene and 60 base pairs of promoter region were used to generate a 190-base antisense RNA probe, using SP6 polymerase in the presence of [32P]-uridine 5'triphosphate. The rat glyceraldehyde-3-phosphate dehydrogenase (GAPDH) probe was synthesized by means of T7 RNA polymerase after digestion of a pBluescript GAPDH plasmid by PvuII and StyI. Unprotected riboprobe was 184 bases long with a 164-base protected fragment. We hybridized 5 µg total RNA with 5 × 104 cpm of each probe in 80% formamide-hybridization buffer overnight at 55°C. Following RNase A + T1 and proteinase K digestion, the protected fragments were separated on a denaturing 8% polyacrylamide gel. Radioactivity associated with the bands was quantified by means of an Instantimager (Packard Instruments, Meriden, CT).RNA gel shift assays of IRP activity Mouse tissue extracts were prepared as described above and diluted at 1 µg/µL in Tris buffer before use. IRE-IRP interactions were measured as previously described,10 by incubating a [32P]-labeled IRE-Fth mRNA probe (3 × 104 cpm at 104 cpm/ng), transcribed in vitro from pIL2CAT (kindly provided by Dr M. Hentze, Heidelberg, Germany) with 5 µg cytoplasmic extracts. After 15 minutes' incubation at room temperature, 5 mg/mL heparin was added for another 10 minutes. IRE-protein complexes were run on a 4% nondenaturing polyacrylamide gel. In parallel experiments, extracts were treated with 2% -mercaptoethanol (ME) prior to the addition of the
IRE probe to allow full expression of IRE binding activity. The IRE/IRP
complexes were quantified with an Instantimager.
Statistical analysis Statistical significance was evaluated by means of the unpaired Student t test with the Welch modification for comparison between 2 means. Tissue ferritin increase with age was analyzed by linear regression, and slopes were considered to be statistically different at P < .05. Serum ferritin increase with age was analyzed by nonlinear regression. GraphPad Prism software (GraphPad Software, San Diego, CA) was used for statistical evaluation.
Progressive iron loading of the spleen in both normal and heterozygous Fth knockout mice In a previous study, we showed that a complete defect in H ferritin subunit is lethal at an early stage during fetal life, between 3.5 and 9.5 days of embryonic development. We also showed that mice with a single disrupted Fth allele are phenotypically indistinguishable from their control littermates. They are healthy and fertile, do not present any gross tissue abnormality, and have normal hematological parameters in both blood and bone marrow.17Since H ferritin has been shown to control the size of the labile iron
pool (LIP) and to affect the IRE-IRP interactions, we explored the
possibility that the Fth+/
Up-regulation of L ferritin synthesis in
Fth+/  mice (Table
2). Tissue L ferritin content increased
progressively in the postnatal period and up to 45 weeks of age.
Furthermore, in the organs that have been tested, namely liver, spleen,
and heart, the trends in the data are consistent with a 1.5- to 2-fold higher L ferritin content in the heterozygous mice as compared with
their control littermates (Figure 3,
Table 2), although the differences were not statistically significant.
The mean ± SD calculated on 10 to 15 animals of each genotype
show important individual variability (Table 2), but this is due mostly
to the progressive increase in tissue L ferritin content with age.
Following iron dextran injections, the difference in L ferritin content between Fth+/+ and
Fth+/ mice became statistically significant
(Figure 4A), both in the spleen
(P = .0006) and in the liver (P = .006). In
iron-loaded animals, L ferritin was 2.5-fold higher in the liver of
heterozygous knockout mice as compared with their control littermates
and 3-fold higher in the spleen. In the heart, the increase in L
ferritin content following iron dextran injections was also higher in H ferritin-deficient mice. Stimulation of H ferritin synthesis following iron injections was moderate (2-fold), identical in all the organs and
in both genotypes (Figure 4B). Therefore, it appears that a partial
defect in tissue H ferritin synthesis leads to a moderate, nonstatistically significant increase in L ferritin synthesis, which
becomes statistically significant following iron injections. These
combined modifications result in markedly different H-to-L subunit
ratios (Table 2), which are likely to affect ferritin function in iron
homeostasis. In contrast, H ferritin synthesized by the remaining
allele is not up-regulated and injections of iron stimulate H ferritin
synthesis only moderately.
L ferritin mRNA is not modified in Fth
+/ and
Fth+/+ mice.
IRE-binding activity of IRP1 is not modified in
Fth+/ ME treatment of the
cytoplasmic extracts (Figure 6). No
IRP2-binding activity could be detected in the liver or in the spleen
(not shown). Quantification of the radioactivity associated with the
IRP1-IRE complexes, before and after 2% ME treatment, by means of
an Instantimager showed that on average, 70% of IRP1 is in the
apo-form possessing an IRE-binding activity, in both control
and Fth+/ mice. In the spleen, only 50% of
the IRP1 has an IRE-binding activity (not shown), but there again, no
difference is observed between the 2 genotypes. It is possible that
half of the normal amount of H ferritin results only in subtle
differences in the regulatory iron pool and in IRE-binding affinity of
IRP1, which are not possible to detect by gel retardation
assays.
The increase in tissue L ferritin results in hyperferritinemia
in Fth+/
We previously reported that a complete defect in Fth expression is lethal at an early stage during embryonic development, demonstrating that H ferritin is indispensable for normal development.17 In this paper, we show that a 2-fold reduction in the H ferritin content in tissues is sufficient to increase serum ferritin levels without changing tissue iron distribution. This shows that fine tuning between the 2 subunits is required for proper control of ferritin synthesis, irrespective of iron homeostasis. It has been shown that H and L subunits cooperate to facilitate iron
oxidation and storage by the ferritin molecule, through the ferroxidase
center of the H subunit, which stimulates iron uptake by the molecule,
and the nucleation center of the L subunit, which facilitates iron core
formation.12 It is likely that in the complete absence of
H subunit, L ferritin homopolymers are not competent in iron chelation
and storing and that cell division and differentiation are totally
impaired in the absence of iron stores. A minimum of 1 or 2 H subunits
in ferritin polymers is thought to be sufficient to allow formation of
ferritin molecules, which have the capacity to sequester
iron.19 However, from our data, we can infer that the
overall subunit composition of tissue ferritin is a key element in the
control of ferritin synthesis. The L-to-H subunit ratio is 3- to 4-fold
higher in the Fth+/ Tissue iron stores in mice progressively increase in the post-natal
period up to 25 weeks of age. Surprisingly, in adult mice, the spleen
appears as the major site of iron storage and contains 4- to 5-fold
more iron than the liver. This spleen iron is probably partially
associated with hemosiderin, since the iron-to-L ferritin ratio is
different in spleen and liver, being 37µg iron to 47µg L ferritin
in the liver vs 205 µg iron to 144µg L ferritin in the spleen.
Electron micrograph studies revealed that this iron is present almost
exclusively in macrophages and is located within vesicular structures.
Microcrystalline arrays of iron deposits are seen in lysosomelike
structures and have the typical appearance of iron deposits seen in the
liver of hemochromatotic patients.21 This iron
accumulation in the spleen is probably strain-specific and could be
related to the presence of a different allele at a locus that governs
iron recycling following red blood cell destruction in macrophages.
Abnormal iron loading of the spleen has been observed in ceruloplasmin
knockout mice. In that case, the targeting was obtained in
Swiss-Webster mice, which do not accumulate iron in their spleens, and
spleen iron overload developed only following absence of ceruloplasmin
expression.22 It is possible that various levels of
ceruloplasmin expression in the different strains is responsible for
incomplete iron recycling from macrophages. However, subunit
composition of the ferritin molecule is not a major regulator of this
process, since spleen iron levels were very similar in Fth+/+ and Fth+/ Tissue L ferritin was moderately elevated in mice with a mutated Fth allele as compared with their control littermates. However, tissue iron loads and serum iron values did not differ between the 2 types of mice at any age, even following repeated iron injections. Although this increased L ferritin content was not statistically
significant, it was observed in 3 different organs and at all ages
between 5 and 25 weeks after birth. Furthermore, this higher L ferritin
content in Fth+/ The most striking phenotype observed in the
Fth+/ The hyperferritinemia observed in the Fth+/
The authors wish to thank Alain Morau for technical assistance with the electron microscopy studies and Bernard Lardeux for providing the GAPDH RNA probe.
Submitted December 22, 2000; accepted April 4, 2001.
The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked "advertisement" in accordance with 18 U.S.C. section 1734.
Reprints: Carole Beaumont, INSERM U409, Faculté Xavier Bichat, BP 416, 16 Rue Henri Huchard, 75870 Paris cedex 18, France; e-mail: beaumont{at}bichat.inserm.fr.
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© 2001 by The American Society of Hematology.
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C. F. Woeller, J. T. Fox, C. Perry, and P. J. Stover A Ferritin-responsive Internal Ribosome Entry Site Regulates Folate Metabolism J. Biol. Chem., October 12, 2007; 282(41): 29927 - 29935. [Abstract] [Full Text] [PDF]
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K. Iwasaki, K. Hailemariam, and Y. Tsuji PIAS3 Interacts with ATF1 and Regulates the Human Ferritin H Gene through an Antioxidant-responsive Element J. Biol. Chem., August 3, 2007; 282(31): 22335 - 22343. [Abstract] [Full Text] [PDF]
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G. Hetet, I. Devaux, N. Soufir, B. Grandchamp, and C. Beaumont Molecular analyses of patients with hyperferritinemia and normal serum iron values reveal both L ferritin IRE and 3 new ferroportin (slc11A3) mutations Blood, September 1, 2003; 102(5): 1904 - 1910. [Abstract] [Full Text] [PDF]
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Top
Abstract
Introduction
Fe) iron dextran
injections
) and their control littermates
(
) were killed at different times after birth and up to 45 weeks.
Liver, spleen, and heart were excised, and L ferritin contents were
measured by ELISA with the use of polyclonal subunit-specific
anti-mouse ferritin antibodies. The results are expressed as
micrograms of recombinant mouse L subunit per gram of wet tissue. The
linear regression is shown for both genotypes.
),
spleen (
), and heart (
