Iron regulatory protein prevents binding of the 43S translation pre-initiation complex to ferritin and eALAS mRNAs.

Translation of ferritin and erythroid 5-aminolevulinate synthase (eALAS) mRNAs is regulated by iron via mRNA-protein interactions between iron-responsive elements (IREs) and iron regulatory protein (IRP). In iron-depleted cells, IRP binds to single IREs located in the 5' untranslated regions of ferritin and eALAS mRNAs and represses translation initiation. The molecular mechanism underlying this translational repression was investigated using reconstituted, IRE-IRP-regulated, cell-free translation systems. The IRE-IRP interaction is shown to prevent the association of the 43S translation pre-initiation complex (including the small ribosomal subunit) with the mRNA. Studies with the spliceosomal protein U1A and mRNAs which harbour specific binding sites for this protein in place of an IRE furthermore reveal that the 5' termini of mRNAs are generally sensitive to repressor protein-mediated inhibition of 43S pre-initiation complex binding.     

Localization of an RNA binding element of the iron responsive element binding protein within a proteolytic fragment containing iron coordination ligands.

The iron responsive element binding protein (IRE-BP) regulates iron storage and uptake in response to iron. This control results from the interaction of the IRE-BP with the iron responsive element (IRE), a conserved sequence/structure element located near the 5' end of all ferritin mRNAs and in the 3' UTR of transferrin receptor mRNAs. Proteolysis was used to probe for functional elements of the IRE-BP. Partial chymotrypsin digestion generates a simple digestion pattern yielding fragments of 68, 56, 41, and 30 kDa. The 68 and 30 kDa fragments are derived from a single cleavage at Trp623. Further cleavages of the 68 kDa polypeptide yield the 56 and 41 kDa peptides. A combination of UV-crosslinking and chymotrypsin digestion was used to localize an RNA binding element within the C-terminus of the 68 kDa fragment, between amino acid residues 480 and 623. This region includes cysteine residues 503 and 506 which have been shown to be required for iron-sulfur cluster assembly and for iron regulation of the IRE-BP. Proteolytic fragments of the IRE-BP that contain this RNA binding region can be crosslinked to the IRE but do not bind with high affinity, suggesting that elements within the IRE-BP, in addition to those located between residues 480 and 623, are required for high affinity binding to the IRE.     

Homology between IRE-BP, a regulatory RNA-binding protein, aconitase, and isopropylmalate isomerase.

Iron-responsive elements (IREs) are regulatory RNA elements which serve as specific binding sites for the IRE-binding protein (IRE-BP). Interaction between IREs and IRE-BP induces repression of ferritin mRNA translation and transferrin receptor mRNA stabilization. We describe the identification of extensive amino acid sequence homology between IRE-BP and two known isomerases, aconitase and isopropylmalate (IPM) isomerase. We discuss the implications of this observation with regard to structure/function relationships of IRE-BP. The structural conservation between a regulatory RNA-binding protein and two enzymes involved in intermediary metabolism provides a surprising example of the functional flexibility in biological structures.     

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.     

Regulation of interaction of the iron-responsive element binding protein with iron-responsive RNA elements.

The 5' untranslated region of the ferritin heavy-chain mRNA contains a stem-loop structure called an iron-responsive element (IRE), that is solely responsible for the iron-mediated control of ferritin translation. A 90-kilodalton protein, called the IRE binding protein (IRE-BP), binds to the IRE and acts as a translational repressor. IREs also explain the iron-dependent control of the degradation of the mRNA encoding the transferrin receptor. Scatchard analysis reveals that the IRE-BP exists in two states, each of which is able to specifically interact with the IRE. The higher-affinity state has a Kd of 10 to 30 pM, and the lower affinity state has a Kd of 2 to 5 nM. The reversible oxidation or reduction of a sulfhydryl is critical to this switching, and the reduced form is of the higher affinity while the oxidized form is of lower affinity. The in vivo rate of ferritin synthesis is correlated with the abundance of the high-affinity form of the IRE-BP. In lysates of cells treated with iron chelators, which decrease ferritin biosynthesis, a four- to fivefold increase in the binding activity is seen and this increase is entirely caused by an increase in high-affinity binding sites. In desferrioxamine-treated cells, the high-affinity form makes up about 50% of the total IRE-BP, whereas in hemin-treated cells, the high-affinity form makes up less than 1%. The total amount of IRE-BP in the cytosol of cells is the same regardless of the prior iron treatment of the cell. Furthermore, a mutated IRE is not able to interact with the IRE-BP in a high-affinity form but only at a single lower affinity Kd of 0.7 nM. Its interaction with the IRE-BP is insensitive to the sulfhydryl status of the protein.     

Translational repression by the human iron-regulatory factor (IRF) in Saccharomyces cerevisiae.

The regulation of the synthesis of ferritin and erythroid 5-aminolevulinate synthase in mammalian cells is mediated by the interaction of the iron regulatory factor (IRF) with a specific recognition site, the iron responsive element (IRE), in the 5' untranslated regions (UTRs) of the respective mRNAs. A new modular expression system was designed to allow reconstruction of this regulatory system in Saccharomyces cerevisiae. This comprised two components: a constitutively expressed reporter gene (luc; encoding luciferase) preceded by a 5' UTR including an IRE sequence, and an inducibly expressed cDNA encoding human IRF. Induction of the latter led to the in vivo synthesis of IRF, which in turn showed IRE-binding activity and also repressed translation of the luc mRNA bearing an IRE-containing 5' UTR. The upper stem-loop region of an IRE, with no further IRE-specific flanking sequences, sufficed for recognition and repression by IRF. Translational regulation of IRE-bearing mRNAs could also be demonstrated in cell-free yeast extracts. This work defines a minimal system for IRF/IRE translational regulation in yeast that requires no additional mammalian-specific components, thus providing direct proof that IRF functions as a translational repressor in vivo. It should be a useful tool as the basis for more detailed studies of eukaryotic translational regulation.     

In vitro mutational analysis of cis-acting RNA translational elements within the poliovirus type 2 5'' untranslated region.

Initiation of translation on poliovirus RNA occurs by internal binding of ribosomes to a region within the 5' untranslated region (UTR) of the mRNA. This region has been previously roughly mapped between nucleotides 140 and 631 of the 5' UTR and termed the ribosome landing pad. To identify cis-acting elements in the 5' UTR of poliovirus type 2 (Lansing strain) RNA that confer cap-independent internal initiation, we determined the in vitro translational efficiencies of a series of deletion and point mutations within the 5' UTR of the mRNA. The results demonstrate that the 3' border of the core poliovirus ribosome landing pad is located between nucleotides 556 and 585, whereas a region extending between nucleotides 585 and 612 confers enhanced translation. We studied two cis-acting elements within this region of the 5' UTR: a pyrimidine stretch which is critical for translation and an AUG (number 7 from the 5' end) that is located approximately 20 nucleotides downstream from the pyrimidine stretch and augments translation. We also show that the stem-loop structure which contains this AUG is not required for translation.     

Insulin inhibition of apolipoprotein B mRNA translation is mediated via the PI-3 kinase/mTOR signaling cascade but does not involve internal ribosomal entry site (IRES) initiation

Although insulin normally activates global mRNA translation, it has a specific inhibitory effect on translation of apolipoprotein B (apoB) mRNA. This suggests that insulin induces a unique signaling cascade that leads to specific inhibition of apoB mRNA translation despite global translational stimulation. Recent studies have revealed that insulin functions to regulate apoB mRNA translation through a mechanism involving the apoB mRNA 5' untranslated region (5' UTR). Here, we further investigate the role of downstream insulin signaling molecules on apoB mRNA translation, and the mechanism of apoB mRNA translation itself. Transfection studies in HepG2 cells expressing deletion constructs of the apoB 5' UTR showed that the cis-acting region responding to insulin was localized within the first 64 nucleotides. Experiments using chimeric apoB UTR-luciferase constructs transfected into HepG2 cells followed by treatment with wortmannin, a PI-3K inhibitor, and rapamycin, an mTOR inhibitor, showed that signaling via PI-3K and mTOR pathways is necessary for insulin-mediated inhibition of chimeric 5' UTR-luciferase expression. In vitro translation of chimeric cRNA confirmed that the effects observed were translational in nature. Furthermore, using RNA-EMSA we found that wortmannin pretreatment blocked insulin-mediated inhibition of the binding of RNA-binding factor(s), migrating near the 110 kDa marker, to the 5' UTR. Radiolabeling studies in HepG2 cells also showed that insulin-mediated control of the synthesis of endogenously expressed full length apoB100 is mediated via the PI-3K and mTOR pathways. Finally, using dual-cistronic luciferase constructs we demonstrate that apoB 5' UTR may have weak internal ribosomal entry (IRES) translation which is not affected by insulin stimulation, and may function to stimulate basal levels of apoB mRNA translation.     

Insulin-mediated suppression of apolipoprotein B mRNA translation requires the 5' UTR and is characterized by decreased binding of an insulin-sensitive 110-kDa 5' UTR RNA-binding protein

Insulin has been shown to acutely regulate hepatic apolipoprotein B (apoB) secretion at both translational and post-translational levels; however, mechanisms of apoB mRNA translational control are largely unknown. Recent studies of apoB untranslated regions (UTRs) revealed a potentially important role for cis-trans interactions at the 5' and 3' UTRs. In the present paper, deletion constructs of the UTR regions of apoB revealed that the 5' UTR was necessary and sufficient for insulin to inhibit synthesis of apoB15. Metabolic radiolabeling and in vitro translation experiments in the presence of protease inhibitors confirmed that the effect of insulin on the apoB 5' UTR was translational in nature. Using the nondenaturing electrophoretic mobility shift assay (EMSA), protein-RNA complexes were detected binding to the apoB 5' and 3' UTRs. Denaturing EMSA identified a 110-kDa protein interacting at the 5' UTR. Nondenaturing EMSA determined that insulin altered binding of large protein complexes to the 5' UTR. Binding specificity was determined by competition with both specific and nonspecific competitors. Insulin treatment decreased binding of the 110-kDa protein to the 5' UTR as visualized by EMSA. Absence of insulin increased binding of this trans-acting factor to the 5' UTR by 2-fold. Analysis of the 3' UTR showed no significant insulin-mediated changes in binding of trans-acting factors. We thus propose the existence of a novel RNA-binding insulin-sensitive factor that binds to the 5' UTR and may regulate apoB mRNA translation. Perturbations in hepatic insulin signaling as observed in insulin-resistant states may alter cis-trans interactions at the 5' UTR, leading to alterations in the rate of apoB mRNA translation, thus contributing to apoB-lipoprotein overproduction.     

The inhibition of the iron responsive element RNA-protein interaction by heme does not mimic in vivo iron regulation

Hemin at greater than 1 microM concentrations inhibits the interaction of the iron responsive element (IRE) and the iron responsive element binding protein (IRE-BP) as measured by gel retardation and UV cross-linking. Heme has recently been proposed to inhibit the repression of translation of an IRE-containing mRNA (Lin, J. J., Daniels-McQueen, S., Patino, M. M., Gaffield, L., Walden, W. E., and Thach, R. E., (1990) Science 247, 74-76). Our binding inhibition provides structural support for these observations. The action of hemin, however, does not mimic the physiologically demonstrated inhibition of high affinity binding of the IRE to IRE-BP by the oxidation of a sulfhydryl of the IRE-BP. In addition to this effect, hemin also inhibits a wide variety of RNA and DNA binding proteins, restriction endonucleases, and nucleases. Therefore, in vitro, the inhibitory effects of hemin are not limited to the interaction of the IRE-BP and the IRE, but are nonspecific and affect a wide variety of nucleic acid-protein interactions. Any hypothesis on the effects on protein-nucleic acid interactions employing greater than 1 microM concentrations of hemin should be interpreted with caution.     

Interplay between hnRNP A1 and a cis-acting element in the 3' UTR of CYP2A5 mRNA is central for high expression of the gene

Our previous evidence suggests that heterogeneous nuclear ribonucleoprotein (hnRNP) A1 plays a part in the regulation of the Cyp2a5 gene by interacting with the 3' untranslated region (UTR) of the CYP2A5 mRNA. However, the exact role of this interaction is not clear. The aim of the present work was to gain further insight into the regulation process of Cyp2a5. For this purpose the 3' UTR of CYP2A5 was fused to the coding region of luciferase mRNA. Luciferase recombinants containing either the full length 3' UTR, or the 3' UTR lacking a previously described 71 nucleotide (nt) region (the hnRNP A1 primary binding site), were transiently expressed in cells expressing or lacking hnRNP A1. The expression of the luciferase recombinants was examined both at mRNA and enzyme activity levels. The results disclosed that the presence of hnRNP A1 was required for the high expression of the recombinant carrying the full length 3' UTR of CYP2A5. Deletion of the hnRNP A1 primary binding site dramatically modified the expression pattern: the mRNA levels and luciferase activities of the deletion mutant were independent from hnRNP A1. These results conclusively demonstrate that the 71 nt region in the 3' UTR of CYP2A5 mRNA can confer hnRNP A1-dependent regulation to a gene. In addition, comparison of RNA levels and luciferase activities suggested that regions flanking the hnRNP A1 binding site could regulate translation of the CYP2A5 mRNA. These results are consistent with a model in which the binding of hnRNP A1 to the 71 nt putative hairpin-loop region in the CYP2A5 mRNA 3' UTR upregulates mRNA levels possibly by protecting the mRNA from degradation.