Internal loop/bulge and hairpin loop of the iron-responsive element of ferritin mRNA contribute to maximal iron regulatory protein 2 binding and translational regulation in the iso-iron-responsive element/iso-iron regulatory protein family

Iron-responsive elements (IREs), a natural group of mRNA-specific sequences, bind iron regulatory proteins (IRPs) differentially and fold into hairpins [with a hexaloop (HL) CAGUGX] with helical distortions: an internal loop/bulge (IL/B) (UGC/C) or C-bulge. C-bulge iso-IREs bind IRP2 more poorly, as oligomers (n = 28-30), and have a weaker signal response in vivo. Two trans-loop GC base pairs occur in the ferritin IRE (IL/B and HL) but only one in C-bulge iso-IREs (HL); metal ions and protons perturb the IL/B [Gdaniec et al. (1998) Biochemistry 37, 1505-1512]. IRE function (translation) and physical properties (T(m) and accessibility to nucleases) are now compared for IL/B and C-bulge IREs and for HL mutants. Conversion of the IL/B into a C-bulge by a single deletion in the IL/B or by substituting the HL CG base pair with UA both derepressed ferritin synthesis 4-fold in rabbit reticulocyte lysates (IRP1 + IRP2), confirming differences in IRP2 binding observed for the oligomers. Since the engineered C-bulge IRE was more helical near the IL/B [Cu(phen)(2) resistant] and more stable (T(m) increased) and the HL mutant was less helical near the IL/B (ribonuclease T1 sensitive) and less stable (T(m) decreased), both CG trans-loop base pairs contribute to maximum IRP2 binding and translational regulation. The (1)H NMR spectrum of the Mg-IRE complex revealed, in contrast to the localized IL/B effects of Co(III) hexaammine observed previously, perturbation of the IL/B plus HL and interloop helix. The lower stability and greater helix distortion in the ferritin IL/B-IRE compared to the C-bulge iso-IREs create a combinatorial set of RNA/protein interactions that control protein synthesis rates with a range of signal sensitivities.     

Role of RNA secondary structure of the iron-responsive element in translational regulation of ferritin synthesis.

Iron regulates synthesis of the iron storage protein ferritin at the translational level through interaction between a stem-loop structure, the iron-responsive element (IRE), located in the 5'-untranslated region (5'-UTR) of ferritin mRNAs, and a protein, the iron regulatory protein (IRP). The role of IRE secondary structure in translational regulation of ferritin synthesis was explored by introducing ferritin constructs containing mutations in the IRE into Rat-2 fibroblasts. Our in vivo studies demonstrate that size and sequence of the loop within the IRE and the distance and/or spatial relationship of this loop to the bulged nucleotide region closest to the loop must be preserved in order to observe iron-dependent translation of ferritin mRNA. In contrast, changes in nucleotide sequence of the upper stem can be introduced without affecting translational regulation in vivo, as long as a stem can be formed. Our in vivo results suggest that only a very small variation in the affinity of interaction of IRP with IRE can be tolerated in order to maintain iron-dependent regulation of translation.     

Multiple,conserved iron-responsive elements in the 3'-untranslated region of transferrin receptor mRNA enhance binding of iron regulatory protein 2

Synthesis of proteins for iron homeostasis is regulated by specific, combinatorial mRNA/protein interactions between RNA stem-loop structures (iron-responsive elements, IREs) and iron-regulatory proteins (IRP1 and IRP2), controlling either mRNA translation or stability. The transferrin receptor 3'-untranslated region (TfR-3'-UTR) mRNA is unique in having five IREs, linked by AU-rich elements. A C-bulge in the stem of each TfR-IRE folds into an IRE that has low IRP2 binding, whereas a loop/bulge in the stem of the ferritin-IRE allows equivalent IRP1 and IRP2 binding. Effects of multiple IRE interactions with IRP1 and IRP2 were compared between the native TfR-3'-UTR sequence (5xIRE) and RNA with only 3 or 2 IREs. We show 1) equivalent IRP1 and IRP2 binding to multiple TfR-IRE RNAs; 2) increased IRP-dependent nuclease resistance of 5xIRE compared with lower IRE copy-number RNAs; 3) distorted TfR-IRE helix structure within the context of 5xIRE, detected by Cu-(phen)(2) binding/cleavage, that coincides with ferritin-IRE conformation and enhanced IRP2 binding; and 4) variable IRP1 and IRP2 expression in human cells and during development (IRP2-mRNA predominated). Changes in TfR-IRE structure conferred by the full length TfR-3'-UTR mRNA explain in part evolutionary conservation of multiple IRE-RNA, which allows TfR mRNA stabilization and receptor synthesis when IRP activity varies, and ensures iron uptake for cell growth.     

Alterations in the interaction between iron regulatory proteins and their iron responsive element in normal and Alzheimer's diseased brains.

Iron regulatory proteins (IRPs) are cytoplasmic mRNA binding proteins involved in intracellular regulation of iron homeostasis. IRPs regulate expression of ferritin and transferrin receptor at the mRNA level by interacting with a conserved RNA structure termed the iron-responsive element (IRE). This concordant regulation of transferrin receptors and ferritin is designed so a cell can obtain iron when it is needed, and sequester iron when it is in excess. However, we have reported that iron accumulates in the brain in Alzheimer's disease without a concomitant increase in ferritin. An increase in iron without proper sequestration can increase the vulnerability of cells to oxidative stress. Oxidative stress is a component of many neurological diseases including Alzheimer's. We hypothesized that alterations in the IRP/IRE interaction could be the site at which iron mismanagement occurs in the Alzheimer's brains. In this report we demonstrate that in normal human brain extracts, the IRP is detected as a double IRE/IRP complex by RNA band shift assay, but in 2 of 6 Alzheimer's brain (AD) extracts examined a single IRE/IRP complex was obtained. Furthermore, the mobility of the single IRE/IRP complex in Alzheimer's brain extracts is decreased relative to the double IRE/IRP complex. Western blot and RNA band super shift assay demonstrate that IRP1 is involved in the formation of the single IRE/IRP complex. In vitro analyses suggest that the stability of the doublet complex and single AD complex are different. The single complex from the AD brain are more stable. A more stable IRE/IRP complex in the AD brain could increase stability of the transferrin receptor mRNA and inhibit ferritin synthesis. At the cellular level, the outcome of this alteration in the molecular regulatory mechanism would be increased iron accumulation without an increase in ferritin; identical to the observation we reported in AD brains. The appearance of the single IRE/IRP complex in Alzheimer's brain extracts is associated with relatively high endogenous ribonuclease activity. We propose that elevated RNase activity is one mechanism by which the iron regulatory system becomes dysfunctional.     

Structured RNA upstream of insect cap distal iron responsive elements enhances iron regulatory protein-mediated control of translation

Iron regulatory protein (IRP) blocks ribosomal assembly by binding to an iron responsive element (IRE) located proximal (<60 nts) to the mRNA cap, thereby repressing translation. Constructs with IREs located 60–100 nts from the cap permit ribosomal assembly but the ribosomes pause at IRE/IRP complexes resulting in partial repression of translation. However, insect ferritin mRNAs have cap-distal IREs located 90–156 nts from the cap. Because iron can be toxic, it seems unlikely that insects would be unable to fully regulate ferritin synthesis at the level of translation. Calpodes ferritin consists of two subunits, S and G. In vitro translation of Calpodes ferritin and IRP1 from fat body mRNA yields only G subunits suggesting that IRP1 more efficiently represses translation of the S subunit than the G. When repression is removed by the addition of IRE competitor RNA, the synthesis of both subunits is greatly increased. S and G ferritin mRNAs have identical IREs in similar far cap-distal positions. While both ferritin mRNAs are predicted to have stem-loops between the IRE and the RNA cap, in general insect S mRNAs have more cap-proximal RNA structure than G mRNAs. Therefore, we examined the effect of upstream secondary structure on ribosomal assembly onto S ferritin mRNA constructs using sucrose gradient analysis of translation initiation complexes. We found no evidence for ribosomal assembly on wild type Calpodes S ferritin mRNA in the presence of IRP1 while constructs lacking the wild type secondary structure showed ribosomal pausing. Constructs with wild type secondary structure preceded by an unstructured upstream leader assemble ribosomes in the presence or absence of IRP1. Sequence and RNA folding analyses of other insect ferritins with cap-distal IREs failed to identify any common sequences or IRE-like structures that might bind to IRP1 with lower affinity or to another RNA binding protein. We propose that stem-loops upstream from the IRE act like pleats that shorten the effective distance between the IRE and cap and allow full translational repression by IRP1. In this way some cap-distal IREs may function like cap-proximal ones.     

Multiple determinants within iron-responsive elements dictate iron regulatory protein binding and regulatory hierarchy

Iron regulatory proteins (IRPs) are iron-regulated RNA binding proteins that, along with iron-responsive elements (IREs), control the translation of a diverse set of mRNA with 5′ IRE. Dysregulation of IRP action causes disease with etiology that may reflect differential control of IRE-containing mRNA. IREs are defined by a conserved stem–loop structure including a midstem bulge at C8 and a terminal CAGUGH sequence that forms an AGU pseudo-triloop and N19 bulge. C8 and the pseudo-triloop nucleotides make the majority of the 22 identified bonds with IRP1. We show that IRP1 binds 5′ IREs in a hierarchy extending over a ninefold range of affinities that encompasses changes in IRE binding affinity observed with human L-ferritin IRE mutants. The limits of this IRE binding hierarchy are predicted to arise due to small differences in binding energy (e.g., equivalent to one H-bond). We demonstrate that multiple regions of the IRE stem not predicted to contact IRP1 help establish the binding hierarchy with the sequence and structure of the C8 region displaying a major role. In contrast, base-pairing and stacking in the upper stem region proximal to the terminal loop had a minor role. Unexpectedly, an N20 bulge compensated for the lack of an N19 bulge, suggesting the existence of novel IREs. Taken together, we suggest that a regulatory binding hierarchy is established through the impact of the IRE stem on the strength, not the number, of bonds between C8 or pseudo-triloop nucleotides and IRP1 or through their impact on an induced fit mechanism of binding.     

Structure of the 5'' untranslated regulatory region of ferritin mRNA studied in solution.

Ferritin mRNAs are the first eukaryotic mRNAs for which a conserved, translational regulatory sequence has been identified. The sequence of twenty-eight nucleotides, called the IRE (iron regulatory element), is found in the 5'-noncoding region and is required for enhanced translation of ferritin mRNA by excess cellular iron; regulation occurs at initiation. The prediction of secondary structure in the IRE is a hairpin loop. We now report an analysis of the IRE structure in solution studied in natural ferritin mRNAs [H and H'(M) subunits] by primer extension, after modification or cleavage by dimethyl sulfate, RNAases T1 and V1, and the chemical nuclease 1, 10-phenanthroline-copper (OPCu) which cleaves single-stranded and bulged regions of RNA. Overall, the structure in solution of the ferritin mRNA regulatory region is a hairpin loop, with magnesium-sensitive features, in which half the stem is provided by the IRE and half by flanking regions; only secondary structure is conserved in the flanking regions. Predicted bulges or internal loops along the stem were clearly detected by OPCu but were missed by the more bulky probe RNAase T1, indicating the efficacy of OPCu in probing subtle features of RNA structure. Magnesium-dependent deviations from the predicted structure were observed in the stem between the hairpin loop and the bulge at C6. The location of the IRE in relation to the initiator AUG or the cap is variable in different ferritin mRNAs. However, the number of nucleotides in the base-paired flanking regions of known ferritin mRNAs is proportional to the distance of the IRE from the cap and places the secondary/tertiary structure 8-10 nucleotides from the cap where interference with initiation is likely.     

Mutagenesis of the iron-regulatory element further defines a role for RNA secondary structure in the regulation of ferritin and transferrin receptor expression.

Within the 5'-untranslated region of ferritin mRNAs, there is a conserved region of 28 nucleotides (nt) (the iron regulatory element (IRE)) that binds a protein (the IRE-binding protein (IRE-BP)) involved in the iron regulation of ferritin mRNA translation. We have examined the role of RNA secondary structure on the interaction of the IRE with the IRE-BP. First, the rat light ferritin IRE possesses a structure similar to that of the bullfrog heavy ferritin IRE (Wang, Y.-H., Sczekan, S. R., and Theil, E. C. (1990) Nucleic Acids Res. 18, 4463-4468). This includes an extended stem, interrupted at various points by bulge nucleotides and a 6-nt single-stranded loop (CAGUGU) at its top. Computer predictions and mapping results suggest the presence of a 3-nt (UGC) bulge 5 bases 5' of the loop in the rat IRE. Second, disruption of the base pairing in the upper stem alters IRE secondary structure and reduces the affinity with which the IRE-BP binds the IRE. Third, increasing the size of the loop or the distance between the UGC bulge and the loop reduces the IRE/IRE-BP interaction. Our results indicate that several aspects of IRE secondary structure are important for its high affinity binding to the IRE-BP.     

Selective Translational Control of the Alzheimer Amyloid Precursor Protein Transcript by Iron Regulatory Protein-1

Iron influx increases the translation of the Alzheimer amyloid precursor protein (APP) via an iron-responsive element (IRE) RNA stem loop in its 5′-untranslated region. Equal modulated interaction of the iron regulatory proteins (IRP1 and IRP2) with canonical IREs controls iron-dependent translation of the ferritin subunits. However, our immunoprecipitation RT-PCR and RNA binding experiments demonstrated that IRP1, but not IRP2, selectively bound the APP IRE in human neural cells. This selective IRP1 interaction pattern was evident in human brain and blood tissue from normal and Alzheimer disease patients. We computer-predicted an optimal novel RNA stem loop structure for the human, rhesus monkey, and mouse APP IREs with reference to the canonical ferritin IREs but also the IREs encoded by erythroid heme biosynthetic aminolevulinate synthase and Hif-2α mRNAs, which preferentially bind IRP1. Selective 2′-hydroxyl acylation analyzed by primer extension analysis was consistent with a 13-base single-stranded terminal loop and a conserved GC-rich stem. Biotinylated RNA probes deleted of the conserved CAGA motif in the terminal loop did not bind to IRP1 relative to wild type probes and could no longer base pair to form a predicted AGA triloop. An AGU pseudo-triloop is key for IRP1 binding to the canonical ferritin IREs. RNA probes encoding the APP IRE stem loop exhibited the same high affinity binding to rhIRP1 as occurs for the H-ferritin IRE (35 pm). Intracellular iron chelation increased binding of IRP1 to the APP IRE, decreasing intracellular APP expression in SH-SY5Y cells. Functionally, shRNA knockdown of IRP1 caused increased expression of neural APP consistent with IRP1-APP IRE-driven translation.     

An atypical iron-responsive element (IRE) within crayfish ferritin mRNA and an iron regulatory protein 1 (IRP1)-like protein from crayfish hepatopancreas

A putative crayfish iron-responsive element (IRE) is present in the 5'-untranslated region of the crayfish ferritin mRNA. The putative crayfish IRE is in a cap-proximal position and shares most of the structural features of the consensus IRE, but the RNA stem-loop structure contains a bulge of a guanine instead of a cytosine at the expected position, so far thought to be a hallmark of IREs. By using an electromobility shift assay this IRE was shown to specifically bind purified recombinant human iron regulatory protein 1 (IRP1) as well as a factor(s) present in a homogenate of crayfish hepatopancreas, likely to be a crayfish IRP1 homologue. With mutations in the crayfish IRE, the affinity of IRP to IRE was drastically decreased. A cDNA encoding an IRP1-like protein was cloned from the hepatopancreas of crayfish. This protein has sequence similarities to IRP, and contains all the active-site residues of aconitase, two putative RNA-binding regions and a putative contact site between RNA and IRP. These results show that a crayfish IRE, lacking the bulged C, can bind IRP1 in vitro and that an IRP1-like protein present in crayfish hepatopancreas may have both aconitase and RNA-binding activities.     

Accommodating variety in iron-responsive elements: Crystal structure of transferrin receptor 1 B IRE bound to iron regulatory protein 1

Iron responsive elements (IREs) are short stem-loop structures found in several mRNAs encoding proteins involved in cellular iron metabolism. Iron regulatory proteins (IRPs) control iron homeostasis through differential binding to the IREs, accommodating any sequence or structural variations that the IREs may present. Here we report the structure of IRP1 in complex with transferrin receptor 1 B (TfR B) IRE, and compare it to the complex with ferritin H (Ftn H) IRE. The two IREs are bound to IRP1 through nearly identical protein-RNA contacts, although their stem conformations are significantly different. These results support the view that binding of different IREs with IRP1 depends both on protein and RNA conformational plasticity, adapting to RNA variation while retaining conserved protein-RNA contacts.     

Excess capacity of the iron regulatory protein system

Iron regulatory proteins (IRP1 and IRP2) are master regulators of cellular iron metabolism. IRPs bind to iron-responsive elements (IREs) present in the untranslated regions of mRNAs encoding proteins of iron storage, uptake, transport, and export. Because simultaneous knockout of IRP1 and IRP2 is embryonically lethal, it has not been possible to use dual knockouts to explore the consequences of loss of both IRP1 and IRP2 in mammalian cells. In this report, we describe the use of small interfering RNA to assess the relative contributions of IRP1 and IRP2 in epithelial cells. Stable cell lines were created in which either IRP1, IRP2, or both were knocked down. Knockdown of IRP1 decreased IRE binding activity but did not affect ferritin H and transferrin receptor 1 (TfR1) expression, whereas knockdown of IRP2 marginally affected IRE binding activity but caused an increase in ferritin H and a decrease in TfR1. Knockdown of both IRPs resulted in a greater reduction of IRE binding activity and more severe perturbation of ferritin H and TfR1 expression compared with single IRP knockdown. Even though the knockdown of IRP-1, IRP-2, or both was efficient, resulting in nondetectable protein and under 5% of wild type levels of mRNA, all stable knockdowns retained an ability to modulate ferritin H and TfR1 appropriately in response to iron challenge. However, further knockdown of IRPs accomplished by transient transfection of small interfering RNA in stable knockdown cells completely abolished the response of ferritin H and TfR1 to iron challenge, demonstrating an extensive excess capacity of the IRP system.     

Involvement of the Iron Regulatory Protein from Eisenia andrei Earthworms in the Regulation of Cellular Iron Homeostasis

Iron homeostasis in cells is regulated by iron regulatory proteins (IRPs) that exist in different organisms. IRPs are cytosolic proteins that bind to iron-responsive elements (IREs) of the 5′- or 3′-untranslated regions (UTR) of mRNAs that encode many proteins involved in iron metabolism. In this study, we have cloned and described a new regulatory protein belonging to the family of IRPs from the earthworm Eisenia andrei (EaIRP). The earthworm IRE site in 5′-UTR of ferritin mRNA most likely folds into a secondary structure that differs from the conventional IRE structures of ferritin due to the absence of a typically unpaired cytosine that participates in protein binding. Prepared recombinant EaIRP and proteins from mammalian liver extracts are able to bind both mammalian and Eisenia IRE structures of ferritin mRNA, although the affinity of the rEaIRP/Eisenia IRE structure is rather low. This result suggests the possible contribution of a conventional IRE structure. When IRP is supplemented with a Fe-S cluster, it can function as a cytosolic aconitase. Cellular cytosolic and mitochondrial fractions, as well as recombinant EaIRP, exhibit aconitase activity that can be abolished by the action of oxygen radicals. The highest expression of EaIRP was detected in parts of the digestive tract. We can assume that earthworms may possess an IRE/IRP regulatory network as a potential mechanism for maintaining cellular iron homeostasis, although the aconitase function of EaIRP is most likely more relevant.