Involvement of heme in the degradation of iron-regulatory protein 2.

Iron-regulatory proteins (IRPs) recognize and bind to specific RNA structures called iron-responsive elements. Mediation of these binding interactions by iron and iron-containing compounds regulates several post-transcriptional events relevant to iron metabolism. There are two known IRPs, IRP1 and IRP2, both of which can respond to iron fluxes in the cell. There is ample evidence that IRP1 is converted by iron to cytoplasmic aconitase in vivo. It has also been shown that, under certain conditions, a significant fraction of IRP1 is degraded in cells exposed to iron or heme. Studies have shown that the degradation of IRP1 that is induced by iron can be inhibited by either desferrioxamine mesylate (an iron chelator) or succinyl acetone (an inhibitor of heme synthesis), whereas the degradation induced by heme cannot. This suggests that heme rather than iron is responsible for this degradation. Several laboratories have shown that IRP2 is also degraded in cells treated with iron salts. We now show evidence suggesting that this IRP2 degradation may be mediated by heme. Thus, in experiments analogous to those used previously to study IRP1, we find that IRP2 is degraded in rabbit fibroblast cells exposed to heme or iron salts. However, as shown earlier with IRP1, both desferrioxamine mesylate and succinyl acetone will inhibit the degradation of IRP2 induced by iron but not that induced by heme.

Regulation of iron metabolism: translational effects mediated by iron, heme, and cytokines.

Recent advances in the knowledge of iron metabolism underscore its complex relationship to overall cell metabolism. One of the key components of the iron uptake and storage pathway is ferritin, a protein that sequesters iron in a nontoxic form. Ferritin synthesis is translationally regulated by iron. Molecules such as nitric oxide and cytokines also affect transcriptional and/or posttranscriptional ferritin synthesis. Conversely, iron-containing molecules affect expression of mitochondrial aconitase, erythroid aminolevulinic acid synthase, and nitric oxide synthase. This observation indicates a complex linkage between iron metabolism and a variety of other important cell activities. The finding that the cytoplasmic iron-responsive protein (IRP) has two forms also raises intriguing questions about the relationship between the cytoplasmic aconitase and translational regulation of mRNAs such as ferritin. At least one of the IRPs can be phosphorylated. These recent discoveries open exciting new avenues for research that should lead to a better understanding of cellular iron metabolism.

Irreversible steps in the ferritin synthesis induction pathway.

The ability of cells to re-repress ferritin synthesis after removal of an inducing agent (iron or heme) was investigated. Re-repression was found to be a slow process, requiring approximately 4 (after iron removal) to 10 h (after heme removal) for completion. Desferrioxamine mesylate (Desferal) had only a slight effect on the rate of re-repression, whereas cycloheximide was strongly inhibitory, indicating that new protein synthesis is required for re-repression. Re-repression occurred at a slow but significant rate in the presence of both Desferal and cycloheximide. These results indicate that, in the absence of an iron chelator, the induction of ferritin synthesis is essentially irreversible. The kinetics of the previously reported covalent modification of IRE-binding protein (IRE-BP) were then examined, to see whether this phenomenon might account (at least in part) for the irreversibility of induction. It was found that the heme- or iron-dependent disappearance of 98-kDa IRE-BP occurred rapidly (within 1 h), and was equally rapidly reversed upon removal of heme after a 1-h exposure. By contrast, after a 4-h exposure to heme, little 98-kDa IRE-BP could be regenerated after heme removal. These results suggest that the slow, irreversible covalent modification of IRE-BP correlates closely over time with the induction of ferritin synthesis. The covalent modification of IRE-BP depends on cell growth rate, and is most readily detected in rapidly growing cells.

The pathogenesis of superficial siderosis of the central nervous system.

In advanced cases of superficial siderosis of the human central nervous system, the clinical triad of hearing loss, cerebellar ataxia, and myelopathy permits the diagnosis at the bedside, and magnetic resonance imaging readily confirms the hemosiderin deposits in brainstem, cerebellum, and spinal cord. To study the pathogenesis of this condition and explain the selective vulnerability of the cerebellum, experimental siderosis was induced in rabbits by the repeated intracisternal injection of autologous red blood cells. The earliest cellular response in the cerebellar molecular layer was hyperplasia and hypertrophy of microglia as displayed by immunocytochemistry for ferritin. Microglia also contained iron, but ferritin biosynthesis appeared to proceed without commensurate iron accumulation. This early apoferritin response probably occurred due to the presence of heme, rather than iron, in the cerebrospinal fluid and subpial tissue. Ferritin biosynthesis is accelerated when the ferritin repressor protein is dissociated from ferritin messenger ribonucleic acid. A specific antiserum localized ferritin repressor protein predominantly to astrocytes including Bergmann glia. It is proposed that abundance and proximity of ferritin repressor protein--immunoreactive Bergmann glia and ferritin-containing microglia in the cerebellar molecular layer permit prompt cellular interaction in the conversion of heme to ferritin and ultimately hemosiderin.

Inducible expression bovine papillomavirus shuttle vectors containing ferritin translational regulatory elements.

The combination of transcriptional and translational control elements in an inducible expression vector suitable for use in stably transformed cell lines was explored. To this end, ferritin translational control elements have been inserted downstream from a mouse metallothionein (mMT-I) transcriptional promoter (PmMT-I), and upstream from various reporter protein-encoding open reading frames (ORFs), all carried on a bovine papillomavirus shuttle vector. Protocols which stimulate transcription (with zinc) and translation (with iron) were developed to optimize the induction of reporter protein synthesis. It was found that insertion of an iron regulatory element between the PmMT-I and a reporter ORF bestowed a sixfold inducibility of reporter protein synthesis with iron and a 90-fold inducibility with iron plus zinc in a classical superinduction protocol. Surprisingly, inclusion of other rabbit ferritin light chain sequences (rFL), including the ORF, enhanced reporter inducibilities to over 15- and 500-fold, respectively. These additional rFL sequences not only increased inducibility but also (i) increased the half-life of the mRNA and (ii) strongly inhibited translation of an ORF located downstream from the 5' proximal ORF. The maximum levels of reporter proteins attained in transformed cells after prolonged induction represented from 1% to 7% of total cellular protein. These inducible expression vectors should prove useful for the production and study of cytotoxic proteins.

Enhanced degradation of the ferritin repressor protein during induction of ferritin messenger RNA translation.

Induction of ferritin synthesis in cultured cells by heme or iron is accompanied by degradation of the ferritin repressor protein (FRP). Intermediates in the degradative pathway apparently include FRP covalently linked in larger aggregates. The effect of iron on FRP degradation is enhanced by porphyrin precursors but is decreased by inhibitors of porphyrin synthesis, which implies that heme is an active agent. These results suggest that translational induction in this system may be caused by enhanced repressor degradation. While unique among translational regulatory systems, this process is common to a variety of other biosynthetic control mechanisms.

Crosslinking of hemin to a specific site on the 90-kDa ferritin repressor protein.

Incubation of a 90-kDa ferritin repressor protein (FRP) with small amounts of radiolabeled hemin resulted in the formation of a strong interaction between the two that was stable to SDS/PAGE. (We refer to this interaction as a "crosslink," without intending to imply knowledge as to its chemical nature.) Of seven other proteins tested individually, only apohemopexin and bovine serum albumin showed similar crosslinking ability, albeit to a much lower extent. [14C]Hemin specifically crosslinked to FRP in the presence of a 50-fold excess of total wheat germ proteins. Inclusion of catalase did not prevent the reaction of hemin with FRP, suggesting that H2O2 is not involved. The subsequent addition of a stoichiometric amount of apohemopexin did not reverse the reaction. Exhaustive digestion of the complex with Staphylococcus aureus V8 protease produced a major labeled peptide of 17 kDa. These results show the existence of a highly specific, uniquely reactive hemin binding site on FRP.

Specificity of the induction of ferritin synthesis by hemin.

We have previously reported that hemin derepresses ferritin mRNA translation in vitro. As noted earlier, pre-incubation of a 90 kDa ferritin repressor protein (FRP) with hemin prevented subsequent repression of ferritin synthesis in a wheat germ extract. The significance of this observation has been investigated further. Evidence is presented here that this inactivation of FRP is temperature dependent. Neither FeCl3, Fe3+ chelated with EDTA, nor protoporphyrin IX caused significant inactivation of FRP under comparable conditions, whereas Zn2(+)-protoporphyrin IX produced an intermediate degree of inhibition. The presence of a glutathione redox buffer (GSB), which was previously shown to minimize non-specific side-effects of hemin, was not necessary for the derepression reaction. Inclusion of mannitol, a free radical scavenger, did not alter the inactivation caused by hemin. Calculation of the expected ratio of hemin monomers to dimers suggests that the active species is the monomer.

Derepression of ferritin messenger RNA translation by hemin in vitro.

Incubation of a 90-kilodalton ferritin repressor protein (FRP), either free or complexed with an L-ferritin transcript, with hemin or Co3+-protoporphyrin IX prevented subsequent repression of ferritin synthesis in a wheat germ extract. Neither FeCl3 in combinations with H2O2, nor Fe3+ or Fe2+ chelated with EDTA, nor Zn2+-protoporphyrin IX, nor protoporphyrin IX caused significant inactivation of FRP. FRP that had been inactivated by hemin remained chemically intact, as revealed by SDS-polyacrylamide gel electrophoresis. Inclusion of chelators of iron or free radical scavengers did not alter the inactivation produced by hemin. These and other results indicate that hemin derepresses ferritin synthesis in vitro.

Induction of ferritin synthesis in vitro: problems of specificity inherent in the use of iron compounds.

The potential importance of heme as a translational regulator has been recognized for nearly 30 years. However, the ability to distinguish the specific regulatory effects of heme from the nonspecific effects has been hampered by its high reactivity and its tendency to generate reactive by-products in most systems. In this article we discuss some of the technical difficulties in studying the effects of iron salts and compounds, notably heme, in biochemical systems in vitro. Data are presented which show that the nonspecific inhibitory effects of heme on two restriction endonucleases can be eliminated by (a) including a redox buffer in the reaction mixture, and (b) maintaining a sufficiently high total protein concentration. Under these conditions, the specific effects of hemin on the ferritin repressor protein are still observed. A possible relationship between these observations and the status of 'free' heme in vivo is considered.

Inducible expression of encephalomyocarditis virus 3C protease activity in stably transformed mouse cell lines.

An inducible expression vector system has been developed to facilitate the study of the effects of individual virus gene products on cell function. The vector utilizes the mouse metallothionein promoter carried on the bovine papillomavirus genome. Conditions which optimize the induced expression of open reading frames inserted downstream from the mouse metallothionein promoter have recently been described. In this communication we describe the use of this system to clone and express the encephalomyocarditis virus 3C protease in cultured mouse cells. Stably transformed cell lines could be induced to produce levels of 3C protease activity comparable to those observed during normal virus infection. In spite of this, no effects on cellular protein synthesis rate or membrane permeability were observed. It was also discovered that 3C protease as well as 3C protease-containing polyproteins are turned over. This was true not only in the induced cell clones, but also during the normal course of encephalomyocarditis virus infection, as well as in translation systems in vitro. This phenomenon was highly specific for this family of polypeptides, perhaps explaining their apparent lack of cytotoxic effects.

Requirements for the translational repression of ferritin transcripts in wheat germ extracts by a 90-kDa protein from rabbit liver.

A specific repressor of ferritin mRNA translation originally detected in rabbit reticulocyte lysates has now been purified to homogeneity from rabbit liver, as described in a companion paper (Walden, W. E., Patino, M. M., and Gaffield, L. (1989) J. Biol. Chem. 264, 13765-13769). This repressor is a 90-kDa protein that binds to a sequence in the 5'-untranslated region of ferritin mRNA. In this communication we describe the molecular features of a ferritin light chain transcript that are required for the repression of its translation by this protein. Addition of small amounts of the 90-kDa ferritin repressor protein (FRP) completely inhibited translation of ferritin transcripts in a wheat germ system. This repression did not require mRNA sequences contained in the 3'-untranslated region or in the majority of the ferritin coding region. In contrast, the first 130 nucleotides of the 5'-untranslated region, which contains the 28-nucleotide "iron responsive element" (IRE), was required for the repressive effect. Moreover, repression of full length transcripts was relieved by addition of a molar excess of a 92-nucleotide transcript of the 5'-untranslated region which also contained the IRE. These results suggest that no sequence information other than a portion of the 5'-untranslated region containing the IRE sequence is required for action of the 90-kDa FRP. In addition, a quantitative comparison of the repression of transcript with that of poly(A+) RNAs indicates that no post-transcriptional modifications of the latter (other than cap addition) are involved in the action of the 90-kDa FRP.

Dissociation of double-stranded polynucleotide helical structures by eukaryotic initiation factors, as revealed by a novel assay.

A new technique has been applied to the study of the RNA secondary structure unwinding activity of the eukaryotic initiation factors (eIFs) 4F, 4A, and 4B. Secondary structures were generated at the 5' ends of reovirus and globin mRNA molecules by hybridization with 32P-labeled cDNA molecules 15 nucleotide residues long. The dissociation of the labeled cDNAs from the mRNAs was assayed by a gel filtration chromatography procedure which separates the free cDNAs from mRNAs and mRNA/cDNA hybrids. When the three factors were tested alone, only eIF-4F stimulated dissociation of hybrids. The combination of eIF-4A plus eIF-4B also exhibited a strong hybrid dissociating activity, which was markedly temperature dependent. Under optimum conditions, up to 90% of the hybrid structures are disrupted in 60 min. These results demonstrate for the first time that stable double-stranded regions can be melted and dissociated by eIFs. They also characterize more precisely the first step in the structure unwinding reaction.

Translational repression in eukaryotes: partial purification and characterization of a repressor of ferritin mRNA translation.

Mouse and rabbit ferritin mRNAs translate very poorly in rabbit reticulocyte lysates relative to most other mRNAs. This translational deficiency is not seen in wheat germ lysates, suggesting the presence of an inhibitor in reticulocyte lysate that is specific for ferritin mRNA. A specific repressor of ferritin mRNA translation has been partially purified from rabbit reticulocytes by differential ultracentrifugation, ammonium sulfate fractionation, and chromatography on phosphocellulose, DEAE-cellulose, and Sephacryl S-300. The elution profile from the latter suggests an aggregate molecular mass of approximately 180 kDa for the repressor. The inhibitory activity of this repressor against native ferritin mRNA can be relieved by adding in vitro transcripts of ferritin light-chain RNAs that contain the first 92 nucleotides of the 5' untranslated region. No other sequences appear to be necessary for this effect.

Induction of eIF-4E phosphorylation by the addition of L-pyrroline-5-carboxylic acid to rabbit reticulocyte lysate.

Addition of L-pyrroline-5-carboxylic acid to reticulocyte lysates inhibits protein synthesis and induced phosphoproteins of 25 and 14 kDa. The 25 kDa phosphoprotein had the same Mr and pI as phosphorylated eIF-4E. Incubation of lysates with L-pyrroline-5-carboxylic acid did not alter the crosslinking of eIF-4E to reovirus mRNA caps. These results suggest that modifications of the translational apparatus other than eIF-4E phosphorylation may mediate the inhibitory effect seen with L-pyrroline-5-carboxylic acid and/or that phosphorylation of eIF-4E may effect functions subsequent to its interaction with the mRNA cap such as protein-protein interactions with other cap-specific translation factors.

Discriminatory interaction of purified eukaryotic initiation factors 4F plus 4A with the 5' ends of reovirus messenger RNAs.

The interaction of several reovirus mRNAs with cap-binding initiation factors has been investigated. Two quantitative experimental techniques have been applied to this question: (a) the rates of reaction of different mRNAs with tobacco acid pyrophosphatase and (b) the extent of cross-linking of different mRNAs to initiation factors in the presence and absence of ATP. The effects of ionic strength on these reactions have also been investigated. Our results demonstrate for the first time that the purified initiation factors interact differentially with purified reovirus mRNAs under competitive conditions and thus confirm earlier interpretations based on kinetic data. Comparison of the data from these studies with the translational behavior of the reovirus mRNAs, both in vitro and in vivo, has also led to specific predictions about features of these mRNAs that determine their competitive efficiencies. 1) Under ordinary ionic conditions, the steric accessibility of the m7G cap moiety of a reovirus mRNA appears to be a major determinant of its translation rate. 2) When the ionic strength is increased to supranormal levels, an additional feature, which may simply be the amount of secondary structure formed by sequences proximal to the cap, can become rate-limiting for several, but not all, of these mRNAs.

Identification of a protein kinase activity in rabbit reticulocytes that phosphorylates the mRNA cap binding protein.

The 25 kDa mRNA cap binding protein can be purified in a partially phosphorylated state and the extent of its phosphorylation appears to be regulated during heat shock and mitosis in mammalian cells. We demonstrated that a nonabundant serine protein kinase activity exists in rabbit reticulocytes that phosphorylates the 25 kDa cap binding protein in both the free (eIF-4E) and complexed (eIF-4F) state. This kinase was not inhibited by the cAMP-dependent protein kinase inhibitory peptide IAAGRTGRRNAIHDILVAA, did not phosphorylate S6 ribosomal protein, did not phosphorylate p220 of eIF-4F as protein kinase C does and no other substrates for this kinase were apparent in reticulocyte ribosomal salt wash. The molecular identity of this kinase, the specific site(s) of eIF-4E that it phosphorylates and its in vivo regulatory role remain to be studied.