Control Of Intestinal Iron Absorption Research Articles

SAPP modulates iron efflux from brain microvascular endothelial cells by stabilizing the ferrous iron exporter ferroportin.

A sequence within the E2 domain of soluble amyloid precursor protein (sAPP) stimulates iron efflux. This activity has been attributed to a ferroxidase activity suggested for this motif. We demonstrate that the stimulation of efflux supported by this peptide and by sAPPα is due to their stabilization of the ferrous iron exporter, ferroportin (Fpn), in the plasma membrane of human brain microvascular endothelial cells (hBMVEC). The peptide does not bind ferric iron explaining why it does not and thermodynamically cannot promote ferrous iron autoxidation. This peptide specifically pulls Fpn down from the plasma membrane of hBMVEC; based on these results, FTP, for ferroportin-targeting peptide, correctly identifies the function of this peptide. The data suggest that in stabilizing Fpn via the targeting due to the FTP sequence, sAPP will increase the flux of iron into the cerebral interstitium. This inference correlates with the observation of significant iron deposition in the amyloid plaques characteristic of Alzheimer's disease.

Ferrit(in)ing Out New Mechanisms in Iron Homeostasis

Exquisite control of intestinal iron absorption prevents iron deficiency and toxic iron overload. Absorption is modulated by a circulating hormone, hepcidin, which inactivates the iron transporter ferroportin. In this issue of Cell Metabolism, Vanoaica and colleagues show that absorption is also regulated within the intestinal epithelium, through production of the iron-sequestering protein H-ferritin.

Hepcidin inhibits apical iron uptake in intestinal cells

Hepcidin (Hepc) is considered a key mediator in iron trafficking. Although the mechanism of Hepc action in macrophages is fairly well established, much less is known about its action in intestinal cells, one of the main targets of Hepc. The current study investigated the effects of physiologically generated Hepc on iron transport in Caco-2 cell monolayers and rat duodenal segments compared with the effects on the J774 macrophage cell line. Addition of Hepc to Caco-2 cells or rat duodenal segments strongly inhibited apical (55)Fe uptake without apparent effects on the transfer of (55)Fe from the cells to the basolateral medium. Concurrently, the levels of divalent metal transporter 1 (DMT1) mRNA and protein in Caco-2 cells decreased while the mRNA and protein levels of the iron export transporter ferroportin did not change. Plasma membrane localization of ferroportin was studied by selective biotinylation of apical and basolateral membrane domains; Hepc induced rapid internalization of ferroportin in J774 cells but not in Caco-2 cells These results indicate that the effect of Hepc is cell dependent: in macrophages it inhibits iron export by inducing ferroportin degradation, whereas in enterocytes it inhibits apical iron uptake by inhibiting DMT1 transcription. Our results highlight the crucial role of Hepc in the control of intestinal iron absorption.

Molecular mechanisms of iron homeostasis

Iron metabolism in mammals requires a complex and tightly regulated molecular network. The classical view of iron metabolism has been challenged over the past ten years by the discovery of several new proteins, mostly Fe (II) iron transporters, enzymes with ferro-oxydase (hephaestin or ceruloplasmin) or ferri-reductase (Dcytb) activity or regulatory proteins like HFE and hepcidin. Furthermore, a new transferrin receptor has been identified, mostly expressed in the liver, and the ability of the megalin-cubilin complex to internalise the urinary Fe (III)-transferrin complex in renal tubular cells has been highlighted. Intestinal iron absorption by mature duodenal enterocytes requires Fe (III) iron reduction by Dcytb and Fe (II) iron transport through apical membranes by the iron transporter Nramp2/DMT1. This is followed by iron transfer to the baso-lateral side, export by ferroportin and oxidation into Fe (III) by hephaestin prior to binding to plasma transferrin. Macrophages play also an important role in iron delivery to plasma transferrin through phagocytosis of senescent red blood cell, heme catabolism and recycling of iron. Iron egress from macrophages is probably also mediated by ferroportin and patients with heterozygous ferroportin mutations develop progressive iron overload in liver macrophages. Iron homeostasis at the level of the organism is based on a tight control of intestinal iron absorption and efficient recycling of iron by macrophages. Signalling between iron stores in the liver and both duodenal enterocytes and macrophages is mediated by hepcidin, a circulating peptide synthesized by the liver and secreted into the plasma. Hepcidin expression is stimulated in response to iron overload or inflammation, and down regulated by anemia and hypoxia. Hepcidin deficiency leads to iron overload and hepcidin overexpression to anemia. Hepcidin synthesis in response to iron overload seems to be controlled by the HFE molecule. Patients with hereditary hemochromatosis due to HFE mutation have impaired hepcidin synthesis and forced expression of an hepcidin transgene in HFE deficient mice prevents iron overload. These results open new therapeutic perspectives, especially with the possibility to use hepcidin or antagonists for the treatment of iron overload disorders.

The "anemic" enterocyte in hereditary hemochromatosis: molecular insights into the control of intestinal iron absorption.

Studies of the molecular function of HFE, the protein defective in hereditary hemochromatosis, have provided important insights into the control of intestinal iron absorption. A recent study suggests that HFE controls the recycling rate of the transferrin receptor and thereby ultimately controls the iron status of the enterocyte. In hereditary hemochromatosis, a defect in HFE causes relative iron starvation in the enterocyte leading paradoxically to the development of an "anemic" enterocyte phenotype in the midst of bountiful body iron stores. Despite ever-increasing stores of body iron, the inappropriately low iron status of the hereditary hemochromatosis enterocyte continues to drive the hyper-absorption of dietary iron, eventually leading to iron overload.

The relative importance of luminal and systemic signals in the control of intestinal iron absorption

The relative importance of luminal and systemic signals in the control of intestinal iron absorption

The relative importance of luminal and systemic signals in the control of intestinal iron absorption

The relative importance of luminal and systemic signals in the control of intestinal iron absorption

The cellular mechanisms of body iron homeostasis

Cells tightly regulate iron levels 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. Similarly, body iron homeostasis is maintained through the control of intestinal iron absorption. Intestinal epithelia cells sense body iron through the basolateral endocytosis of plasma transferrin. Transferrin endocytosis results in enterocytes whose iron content will depend on the iron saturation of plasma transferrin. Cell iron levels, in turn, inversely correlate with intestinal iron absorption. In this study, we examined the relationship between the regulation of intestinal iron absorption and the regulation of intracellular iron levels by Caco-2 cells. We asserted that IRP activity closely correlates with apical iron uptake and transepithelial iron transport. Moreover, overexpression of IRE resulted in a very low labile or reactive iron pool and increased apical to basolateral iron flux. These results show that iron absorption is primarily regulated by the size of the labile iron pool, which in turn is regulated by the IRE/IRP system.

δ-Aminolevulenic acid (ALA) and the Control of Intestinal Iron Absorption

δ-Aminolevulenic acid (ALA) and the Control of Intestinal Iron Absorption

Importance of haem biosynthesis in the control of intestinal iron absorption.

Importance of haem biosynthesis in the control of intestinal iron absorption.

The Role of Macrophages in the Control of Intestinal Iron Absorption

The Role of Macrophages in the Control of Intestinal Iron Absorption

Control of Intestinal Iron Absorption in Hypotransferrinaemic (HPX/HPX) Mice

Control of Intestinal Iron Absorption in Hypotransferrinaemic (HPX/HPX) Mice

Thymus‐leukaemia antigens: The haemochromatosis gene product?

The gene for hereditary haemochromatosis (HFE) lies telomeric to HLA-A and is believed to be expressed in the intestinal mucosa. Its product has not been characterized, but iron overload and its pathological consequences occur only in homozygotes for this putative gene. The genes encoding the putative human counterparts of the mouse thymus-leukaemia (TL) antigens map to the area where the HFE gene lies. Here, we postulate that a human TL gene may encode a protein acting as or interacting with the transferrin (Tf) receptor in the intestinal mucosa. This hypothesis is based on the following observations: (i) hereditary haemochromatosis (HH) is due to excessive absorption of iron through the intestinal mucosa. HH has a strong association with HLA-A3, but HLA-A3 has no direct role in the pathogenesis and reflects linkage disequilibrium with a telomeric gene. (ii) An HLA-A3 homozygous genotype is associated with the highest relative risks for both early-onset leukaemia and HH. In analogy to the susceptibility locus in mice, this genotype may reflect a TL gene association in leukaemia and raise the possibility of a TL gene involvement in HH. (iii) A TL antigen-like human molecule encoded in the region telomeric to HLA-A, TCA, is expressed in leukaemia and recognized by a Tf receptor-specific monoclonal antibody. The Tf receptor is believed to have a role in the control of intestinal iron absorption. (iv) In mice, particular TL antigens are exclusively expressed in the intestinal mucosa.(ABSTRACT TRUNCATED AT 250 WORDS)

Computer Simulation of Iron Absorption: Regulation of Mucosal and Systemic Iron Kinetics in Dogs ,

The quantity and distribution of body iron normally vary little over time. This homeostasis is maintained primarily through control of intestinal iron absorption, but the mechanism of this regulation is unclear. Modern techniques for computer simulation and numerical analysis now make it possible to study the kinetics of iron absorption in vivo. We used a physiologically based mathematical model of iron metabolism to analyze tracer iron kinetics in normal and iron-deficient beagles. The model provides characteristic information about both intestinal and systemic iron exchange, thus permitting formulation of an hypothesis that may explain the regulation of iron absorption under these conditions. The results indicate that control of iron absorption is a function of independent expression of iron requirements by each tissue, including the intestinal mucosa. This hypothesis is consistent with other in vivo and in vitro observations in iron deficiency and may have implications for understanding the mechanism of the altered iron absorption in other disorders of iron metabolism.