The ferritin Iron regulatory element (IRE), a conserved sequence of 28 nucleotides in a hairpin loop, is a conserved mRNA-spedflc translational regulatory element; flanking the IRE are regions of varying sequence, which form 9-17 base pairs close to the 5' cap. P-90 is a ferritin mRNAspecific translation regulatory protein purified from animal liver and reticulocytes. To study the P-90-RNA interaction, protein nucleases (RNase Si and Ti) and chemical nucleases FeEDTA and/or 1,10-phenanthroline-Cu were used as probes of an oligonucleotide (n = 55), containing the IRE and flanking regions (FL), and natural ferritin mRNA. Footprints and "toeprints" showed that P-90 binding was confined to the stem and loop of the IRE itself. However, P-90 altered the structure of the flanking region by increasing base stacking or helicity (RNase V1 sensitivity). Comparison of the reactivity of the IRE and flanking regions in natural mRNA and the 55-mer showed that long-range interactions included protecting bulges, singlestranded, and stacked regions from protein nucleases as well as stabilizing the P-90-RNA interaction. Structural integration of the IRE with the base-paired fanking regions was indicated by common features of reactivity (periodic hypersensitivity to FeEDTA) and changes in the FL region caused by P-90. The increased secondary structure of the IRE flanking regions caused by P-90 binding to the IRE provides a likely mechanism for blocking initiation of ferritin mRNA translation, since the combined structure (IRE + FL) is so close (8-17 nucleotides) to the cap.Ferritin mRNAs, encoding the subunits of a large iron storage protein, contain a regulatory sequence in the 5' noncoding region that is conserved among all vertebrates studied (reviewed in ref. 1). The conserved mRNA sequence, IRE or iron regulatory element, is a 28-nucleotide hairpin loop, which is required for self-regulation of ferritin synthesis by iron; IRE flanking sequences form a 9-to 17-base-paired stem near the cap (2,'3). Increased cellular iron, which is the best-known regulatory signal, increases ferritin synthesis and iron storage by recruiting ferritin mRNA for polyribosomes, while decreasing transferrin receptor synthesis and iron uptake by degrading the receptor mRNA (4-9). Concerted regulation of the mRNA for the two metabolically related proteins uses the same RNA-protein interactions combined with additional sequences (1,7,8,(10)(11)(12)(13)(14). Opposite effects of iron on translation of ferritin mRNA and destabilization of the transferrin receptor mRNA coincide with the different locations ofthe IRE, in either the 5' noncoding region (ferritin mRNA) or the 3' noncoding region (transferrin receptor mRNA).Cell-free extracts from animal cells (rabbit reticulocytes) reproduce the ferritin mRNA-specific block in translation initiation, independently of added iron (10), indicating the presence of trans-acting factors. Ferritin mRNA-specific trans-acting factors have not been detected in plants (5, 10); § wheat germ extracts were used to...
