Iron regulatory protein 2 is a suppressor of mutant p53 in tumorigenesis.

p53 is known to play a role in iron homeostasis and is required for FDXR-mediated iron metabolism via iron regulatory protein 2 (IRP2). Interestingly, p53 is frequently mutated in tumors wherein iron is often accumulated, suggesting that mutant p53 may exert its gain of function by altering iron metabolism. In this study, we found that FDXR deficiency decreased mutant p53 expression along with altered iron metabolism in p53R270H/- MEFs and cancer cells carrying mutant p53. Consistently, we found that decreased expression of mutant p53 by FDXR deficiency inhibited mutant p53-R270H to induce carcinoma and high grade pleomorphic sarcoma in FDXR+/-; p53R270H/- mice as compared with p53R270H/- mice. Moreover, we found that like its effect on wild-type p53, loss of IRP2 increased mutant p53 expression. However, unlike its effect to suppress cell growth in cells carrying wild-type p53, loss of IRP2 promoted cell growth in cancer cells expressing mutant p53. Finally, we found that ectopic expression of IRP2 suppressed cell growth in a mutant p53-dependent manner. Together, our data indicate that mutant p53 gain-of-function can be suppressed by IRP2 and FDXR deficiency, both of which may be explored to target tumors carrying mutant p53.

Iron regulatory protein 2 deficiency may correlate with insulin resistance.

Iron is known to be a crucial regulator of glucose, and several studies have demonstrated that iron overload is one of the risk factors for insulin resistance and diabetes; however, the mechanism has not yet been clarified. To investigate the effect of iron overload on glucose metabolism and the underlying mechanism, Irp2 knockout (Irp2-/-) mice (endogenous iron overload model) were used. We found that Irp2-/- mice exhibited hyperglycemia and iron overload in the liver and skeletal muscle. Increased MDA, decreased SOD levels, and increased cell apoptosis were also found in the liver and muscle of Irp2-/- mice. Glucose concentrations were significantly higher in Irp2-/- mice in insulin tolerance tests. However, early-phase insulin secretion was not altered in Irp2-/- mice. The expression of hepatic IRS2 and muscle GLUT4 was declined in Irp2-/- mice at both mRNA and protein levels when compared with those of wild-type control. In conclusions, Irp2-/- mice showed hyperglycemia, which might due to insulin resistance rather than due to impaired insulin secretion.

[Mechanism of α-lipoic acid promoting iron efflux in substantia nigra cells of Parkinson's disease rats].

Objective To observe the effect of α-lipoic acid (α-LA) on the expressions of iron regulatory protein 2 (IRP2) and ferroportin1 (FP1) in substantia nigra of rats with Parkinson's disease (PD) and explore the mechanism by which α-LA regulates iron efflux in substantia nigra cells of PD rat models. Methods Sixty healthy male SD rats were randomly divided into a sham group (n=15) and a model group (n=45). To establish the PD model, the rats of the model group were injected with 6-hydroxydopamine (6-OHDA) into their right striatum by the stereotactic technique, and the sham operation group was injected with the same dose of normal saline. Four weeks later, 30 model rats were randomly picked and divided into a PD model group (n=15) and a PD treatment group (n=15). The PD treatment group was intraperitoneally injected with α-LA (50 mg/kg) daily for 2 weeks, and the PD model group was given the same dose of saline. After 14 days of treatment, the left forelimb use rate was tested by cylinder test. The right middle cerebral substantia nigra was taken from each group, and the expression and distribution of tyrosine hydroxylase (TH) was detected by immunohistochemical staining; the number of iron positive cells was determined by Prussian blue staining; and the levels of IRP2 and FP1 were examined by Western blotting. Results Compared with the sham operation group, the left forelimb use rate of the PD model group was significantly reduced. The number of TH positive cells significantly decreased, and the number of iron positive cells in the substantia nigra significantly increased. The level of IRP2 significantly increased, and the level of FP1 decreased remarkably. Compared with PD model group, the left forelimb use rate of the PD treatment group was significantly raised. The number of TH positive cells was significantly elevated, and the number of iron positive cells in the substantia nigra was significantly reduced. The IRP2 level decreased and the FP1 level increased. Conclusion By decreasing the IRP2 level and via the IRP2/IRE pathway, α-LA can increase FP1 level, promote the outflow of iron ions from cells, and reduce iron deposition in the substantia nigra of PD model rats, thereby alleviating brain injury in PD rats induced by 6-OHDA.

Tumorigenic properties of iron regulatory protein 2 (IRP2) mediated by its specific 73-amino acids insert.

Iron regulatory proteins, IRP1 and IRP2, bind to mRNAs harboring iron responsive elements and control their expression. IRPs may also perform additional functions. Thus, IRP1 exhibited apparent tumor suppressor properties in a tumor xenograft model. Here we examined the effects of IRP2 in a similar setting. Human H1299 lung cancer cells or clones engineered for tetracycline-inducible expression of wild type IRP2, or the deletion mutant IRP2(Delta73) (lacking a specific insert of 73 amino acids), were injected subcutaneously into nude mice. The induction of IRP2 profoundly stimulated the growth of tumor xenografts, and this response was blunted by addition of tetracycline in the drinking water of the animals, to turnoff the IRP2 transgene. Interestingly, IRP2(Delta73) failed to promote tumor growth above control levels. As expected, xenografts expressing the IRP2 transgene exhibited high levels of transferrin receptor 1 (TfR1); however, the expression of other known IRP targets was not affected. Moreover, these xenografts manifested increased c-MYC levels and ERK1/2 phosphorylation. A microarray analysis identified distinct gene expression patterns between control and tumors containing IRP2 or IRP1 transgenes. By contrast, gene expression profiles of control and IRP2(Delta73)-related tumors were more similar, consistently with their growth phenotype. Collectively, these data demonstrate an apparent pro-oncogenic activity of IRP2 that depends on its specific 73 amino acids insert, and provide further evidence for a link between IRPs and cancer biology.

Iron regulatory protein 2 is involved in brain copper homeostasis.

Trace metal homeostasis is tightly controlled in the brain, as even a slight dysregulation may severely impact normal brain function. This is especially apparent in Alzheimer's disease, where brain homeostasis of trace metals such as copper and iron is dysregulated. As it is known that iron and copper metabolism are linked, we wanted to investigate if a common mechanism could explain the increase in iron and decrease in copper seen in Alzheimer's disease brain. Amyloid-beta protein precursor (AbetaPP) has been implicated in copper efflux from the brain. Furthermore, it was shown that iron regulatory proteins (IRP), which regulate iron homeostasis, can block AbetaPP mRNA translation. In a correlative study we have therefore compared brain regional copper levels and AbetaPP expression in mice with a targeted deletion of IRP2-/-. Compared with controls, six week old IRP2-/- mice had significantly less brain copper in the parietal cortex, hippocampus, ventral striatum, thalamus, hypothalamus, and whole brain, while AbetaPP was significantly upregulated in the hippocampus (p < 0.05) and showed a trend toward upregulation in the thalamus (p < 0.1). This is the first study to demonstrate that iron regulatory proteins affect brain copper levels, which has significant implications for neurodegenerative diseases.

In vivo role(s) of the iron regulatory proteins (IRP) 1 and 2 in aseptic local inflammation.

The maintenance of iron homeostasis is critical as both iron deficiency and iron excess are deleterious. In mammals, iron homeostasis is regulated systemically by the iron-hormone hepcidin, an acute-phase protein secreted by the liver which inhibits iron absorption and recycling. Cellularly, the interaction of iron regulatory proteins (IRP) 1 and 2 with iron-responsive elements controls the expression of target mRNAs encoding proteins of iron acquisition, storage, utilization, and export. These processes critically affect iron levels, which in turn impact on numerous aspects of inflammation. To explore the role of IRP1 and IRP2 in inflammation, IRP-deficient mice, i.e., mice with total and constitutive deficiency of either IRP, were subjected to acute aseptic local inflammation. Turpentine oil injection increases the expression of acute phase proteins in the liver and interleukin 6 levels in the serum of control mice. Both IRP-deficient mouse models mount the same responses, indicating that the treatment was efficient in all animals and that the acute phase response does not require expression of both IRPs. As expected, turpentine oil treatment enhances hepcidin mRNA expression in the liver of wild-type mice, associated with decreased serum iron levels. Importantly, Irp1 (-/-) and Irp2 (-/-) animals, respectively, display quantitatively similar hepcidin mRNA induction and the appropriate reduction of the serum iron values. Our data indicate that the response of Irp1 (-/-) and Irp2 (-/-) mice to acute local inflammation is largely preserved.

Iron regulatory proteins increase neuronal vulnerability to hydrogen peroxide.

Iron regulatory protein (IRP)-1 and IRP2 inhibit ferritin synthesis by binding to an iron responsive element in the 5'-untranslated region of its mRNA. The present study tested the hypothesis that neurons lacking these proteins would be resistant to hydrogen peroxide (H(2)O(2)) toxicity. Wild-type cortical cultures treated with 100-300microM H(2)O(2) sustained widespread neuronal death, as measured by lactate dehydrogenase assay, and a significant increase in malondialdehyde. Both endpoints were reduced by over 85% in IRP2 knockout cultures. IRP1 gene deletion had a weaker and variable effect, with approximately 20% reduction in cell death at 300microM H(2)O(2). Ferritin expression after H(2)O(2) treatment was increased 1.9- and 6.7-fold in IRP1 and IRP2 knockout cultures, respectively, compared with wild-type. These results suggest that iron regulatory proteins, particularly IRP2, increase neuronal vulnerability to oxidative injury. Therapies targeting IRP2 binding to ferritin mRNA may attenuate neuronal loss due to oxidative stress.

Iron regulatory proteins are essential for intestinal function and control key iron absorption molecules in the duodenum.

Iron regulatory proteins (IRPs) orchestrate the posttranscriptional regulation of critical iron metabolism proteins at the cellular level. Redundancy between IRP1 and IRP2 associated with embryonic lethality of doubly IRP-deficient mice has precluded the study of IRP function in vivo. Here we use Cre/Lox technology to generate viable organisms lacking IRP expression in a single tissue, the intestine. Mice lacking intestinal IRP expression develop intestinal malabsorption and dehydration postnatally and die within 4 weeks of birth. We demonstrate that IRPs control the expression of divalent metal transporter 1 (DMT1) mRNA and protein, a limiting intestinal iron importer. IRPs are also shown to be critically important to secure physiological levels of the basolateral iron exporter ferroportin. IRPs are thus essential for intestinal function and organismal survival and coordinate the synthesis of key iron metabolism proteins in the duodenum.

Iron homeostasis in chronic inflammation.

Inflammation induced anemia and resistance to erythropoietin are common features in patients with chronic kidney disease (CKD). Elevated levels of cytokines and enhanced oxidative stress, conditions associated with inflammatory states, are implicated in the development of anemia. Accumulating evidence suggests that activation of cytokine cascade and the associated acute-phase response, as it often occurs in patients with CKD, divert iron from erythropoiesis to storage sites within the reticuloendothelial system leading to functional iron deficiency and subsequently to anemia or resistance to erythropoietin. Other processes have also been shown to be involved in the pathogenesis of anemia provoked by the activated immune system including an inhibition of erythroid progenitor proliferation and differentiation, a suppression of erythropoietin production and a blunted response to erythropoietin. The present review concerns the underlying alterations in iron metabolism induced by chronic inflammation that result in anemia.

Altered body iron distribution and microcytosis in mice deficient in iron regulatory protein 2 (IRP2).

Iron regulatory protein 2 (IRP2)-deficient mice have been reported to suffer from late-onset neurodegeneration by an unknown mechanism. We report that young adult Irp2-/- mice display signs of iron mismanagement within the central iron recycling pathway in the mammalian body, the liver-bone marrow-spleen axis, with altered body iron distribution and compromised hematopoiesis. In comparison with wild-type littermates, Irp2-/- mice are mildly microcytic with reduced serum hemoglobin levels and hematocrit. Serum iron and transferrin saturation are unchanged, and hence microcytosis is not due to an overt decrease in systemic iron availability. The liver and duodenum are iron loaded, while the spleen is iron deficient, associated with a reduced expression of the iron exporter ferroportin. A reduction in transferrin receptor 1 (TfR1) mRNA levels in the bone marrow of Irp2-/- mice can plausibly explain the microcytosis by an intrinsic defect in erythropoiesis due to a failure to adequately protect TfR1 mRNA against degradation. This study links a classic regulator of cellular iron metabolism to systemic iron homeostasis and erythropoietic TfR1 expression. Furthermore, this work uncovers aspects of mammalian iron metabolism that can or cannot be compensated for by the expression of IRP1.

Aquisition, mobilization and utilization of cellular iron and heme: endless findings and growing evidence of tight regulation.

Iron is fastidiously utilized by living cells, since it is an essential element, but is toxic in excess. Cells take up iron via a transferrin-transferrin receptor-dependent endocytotic process. The iron thus taken up is used for essential biological functions including oxygen transport, electron transfer, and DNA synthesis. The intracellular level of iron is tightly controlled, through regulation of the cellular uptake of iron and the sequestering of low molecular labile iron into the storage protein ferritin. The known proteins of iron transport and storage, transferrin, transferrin receptor and ferritin, have been recently linked with a number of newly identified proteins that are responsible for inherited diseases of iron metabolisms and play critical roles in the maintenance of iron homeostasis. These proteins are involved in regulation of intracellular levels of iron, iron transport, and heme transport and the oxygen-dependent regulation of gene expression. On the other hand, most iron is transported into mitochondria and immediately used for the biosynthesis of heme in erythroid cells. The heme biosynthesis in mitochondria is coupled with the supply of iron, and the heme, exported from mitochondria, is utilized as prosthetic groups of hemeproteins. Furthermore, non-erythroid and erythroid cells possess the different regulatory systems for the biosynthesis of heme; iron positively regulates the biosynthesis in erythroid cells while heme negatively regulates it in non-erythroid cells. Because of the toxicity and insolubility of heme, the intracellular level of uncommitted heme is maintained at a low concentration (< 10(-9)M). The influx and efflux of heme also help to prevent cytotoxicity. Finally, heme-binding transcriptional factors such as Bach1 and NPAS2 regulate the transcription of several genes involved in the synthesis and degradation of heme-hemeproteins. The discovery of new molecules related to disorders of iron and heme metabolism is ascribable to a complete mechanistic understanding of the cellular network of iron homeostasis. The network of interactions that link iron and heme metabolisms with functions of cellular regulation involving oxidative stress and inflammations contributes to new insights into clinical aspects of disorders.

Does cellular iron dysregulation play a causative role in Parkinson's disease?

Selective dopaminergic cell loss in Parkinson's disease is correlated with increased levels of cellular iron. It is still hotly debated as to whether the increase in iron is an upstream event which acts to promote neurodegeneration via formation of oxidative stress or whether iron accumulates as a by-product of the neuronal cell loss. Here we review evidence for loss of iron homeostasis as a causative factor in disease-associated neurodegeneration and the primary players which may be involved. A series of recent studies suggest that iron regulatory proteins (IRPs) coordinate both cellular iron levels and energy metabolism, both of which are disrupted in Parkinson's disease (PD) and may in turn contribute to increased levels of oxidative stress associated with the disease. Iron has also been recently been implicated in promotion of alpha-synuclein aggregation either directly or via increasing levels of oxidative stress suggesting an important role for it in Lewy body formation, another important hallmark of the disease.

Genetic ablations of iron regulatory proteins 1 and 2 reveal why iron regulatory protein 2 dominates iron homeostasis.

The two iron regulatory proteins IRP1 and IRP2 bind to transcripts of ferritin, transferrin receptor and other target genes to control the expression of iron metabolism proteins at the post-transcriptional level. Here we compare the effects of genetic ablation of IRP1 to IRP2 in mice. IRP1-/- mice misregulate iron metabolism only in the kidney and brown fat, two tissues in which the endogenous expression level of IRP1 greatly exceeds that of IRP2, whereas IRP2-/- mice misregulate the expression of target proteins in all tissues. Surprisingly, the RNA-binding activity of IRP1 does not increase in animals on a low-iron diet that is sufficient to activate IRP2. In animal tissues, most of the bifunctional IRP1 is in the form of cytosolic aconitase rather than an RNA-binding protein. Our findings indicate that the small RNA-binding fraction of IRP1, which is insensitive to cellular iron status, contributes to basal mammalian iron homeostasis, whereas IRP2 is sensitive to iron status and can compensate for the loss of IRP1 by increasing its binding activity. Thus, IRP2 dominates post-transcriptional regulation of iron metabolism in mammals.

Iron regulatory protein 2 as iron sensor. Iron-dependent oxidative modification of cysteine.

Iron regulatory protein 2 coordinates cellular regulation of iron metabolism by binding to iron responsive elements in mRNA. The protein is synthesized constitutively but is rapidly degraded when iron stores are replete. This iron-dependent degradation requires the presence of a 73-residue degradation domain, but its functions have not yet been established. We now show that the domain can act as an iron sensor, mediating its own covalent modification. The domain forms an iron-binding site with three cysteine residues located in the middle of the domain. It then reacts with molecular oxygen to generate a reactive oxidizing species at the iron-binding site. One cysteine residue is oxidized to dehydrocysteine and other products. This covalent modification may thus mark the protein molecule for degradation by the proteasome system.

The iron regulatory proteins: targets and modulators of free radical reactions and oxidative damage.

Iron acquisition is a fundamental requirement for many aspects of life, but excess iron may result in formation of free radicals that damage cellular constituents. For this reason, the amount of iron within the cell is carefully regulated in order to provide an adequate level of a micronutrient while preventing its accumulation and toxicity. A major mechanism for the regulation of iron homeostasis relies on the post-transcriptional control of ferritin and transferrin receptor mRNAs, which are recognized by two cytoplasmic iron regulatory proteins (IRP-1 and IRP-2) that modulate their translation and stability, respectively. IRP-1 can function as a mRNA binding protein or as an aconitase, depending on whether it disassembles or assembles an iron-sulfur cluster in response to iron deficiency or abundancy, respectively. IRP-2 is structurally and functionally similar to IRP-1, but does not assemble a cluster nor exhibits aconitase activity. Here we briefly review the role of IRP in iron-mediated damage induced by oxygen radicals, nitrogen-centered reactive species, and xenobiotics of pharmacological and clinical interest.