Peroxisomal targeting of mammalian hydroxyacid oxidase 1 requires the C-terminal tripeptide SKI.

Peroxisomal proteins are post-translationally imported into peroxisomes after recognition by specific receptors. The best-defined peroxisomal targeting signal is a C-terminal tripeptide SKL. Different functional variants of this tripeptide have been defined, but mutants with a SKI sequence were recognized as being inefficiently targeted to peroxisomes. Recently, we have cloned a cDNA for the mouse hydroxyacid oxidase 1 (Hao1), a protein that seems to be localized in peroxisomes. Interestingly, the mouse Hao1 sequence comprises a C-terminal SKI tripeptide. We have analyzed the subcellular localization of Hao1 and tested whether its SKI sequence acts as a targeting signal. Ltk(-) and Cos-7 cells were transfected with vectors expressing a fusion protein of green fluorescence protein and Hao1, as well as mutants thereof. Targeting to peroxisomes of the fusion protein with the wild-type SKI sequence was highly selective and as complete as with the peroxisome-specific SKL sequence. By contrast, targeting was lost in a mutant with the sequence CKM. The data show that mammalian Hao1 is a peroxisomal protein and that the C-terminal sequence SKI acts as the targeting signal.

Identification of RNA-binding surfaces in iron regulatory protein-1.

Post-transcriptional regulation of mRNA translation and stability in iron metabolism involves the interaction between the trans-acting cytoplasmic iron regulatory proteins (IRP-1 and IRP-2) and cis-acting iron-responsive elements (IREs) in mRNA 5'- or 3'-untranslated regions. IRP-1 can adopt two conformations: one with a [4Fe-4S]-cluster, unable to bind IREs, which functions as a cytoplasmic aconitase; one lacking this cluster, which accumulates in iron-deprived cells and binds mRNA firmly. We investigated which surfaces of IRP-1 interact with IREs. Surface areas were predicted on the basis of the crystallized porcine mitochondrial aconitase structure. We selected nine sequences absent or different in mitochondrial and Escherichia coli aconitases, both being devoid of RNA-binding properties. Mutations in two regions of domain 4 of IRP-1 lowered the affinity for a wild-type IRE up to 7-fold in vitro, whereas the aconitase activity, a control for structural integrity, was not affected. Scatchard plot analysis with mutant IREs indicated that domain 4 is involved in the binding specificity. This conclusion was confirmed with hybrid proteins in which IRP-1 surface loops were grafted into IRP-2. The results indicate that arginines 728 and 732 contact the IRE bulge, whereas region 685-689 is necessary for recognition of the IRE loop.

Molecular cloning of mouse glycolate oxidase. High evolutionary conservation and presence of an iron-responsive element-like sequence in the mRNA.

Iron regulatory proteins (IRPs) control the synthesis of several proteins in iron metabolism by binding to iron-responsive elements (IREs), a hairpin structure in the untranslated region (UTR) of corresponding mRNAs. Binding of IRPs to IREs in the 5' UTR inhibits translation of ferritin heavy and light chain, erythroid aminolevulinic acid synthase, mitochondrial aconitase, and Drosophila succinate dehydrogenase b, whereas IRP binding to IREs in the 3' UTR of transferrin receptor mRNA prolongs mRNA half-life. To identify new targets of IRPs, we devised a method to enrich IRE-containing mRNAs by using recombinant IRP-1 as an affinity matrix. A cDNA library established from enriched mRNA was screened by an RNA-protein band shift assay. This revealed a novel IRE-like sequence in the 3' UTR of a liver-specific mouse mRNA. The newly identified cDNA codes for a protein with high homology to plant glycolate oxidase (GOX). Recombinant protein expressed in bacteria displayed enzymatic GOX activity. Therefore, this cDNA represents the first vertebrate GOX homologue. The IRE-like sequence in mouse GOX exhibited strong binding to IRPs at room temperature. However, it differs from functional IREs by a mismatch in the middle of its upper stem and did not confer iron-dependent regulation in cells.

Translational regulation of mRNAs with distinct IRE sequences by iron regulatory proteins 1 and 2.

Iron regulatory proteins 1 and 2 (IRP-1, IRP-2) interact with iron-responsive elements (IREs) present in the 5'- or 3'-untranslated regions (UTR) of several mRNAs coding for proteins in iron metabolism. Whereas binding of IRP-1 and -2 to an IRE in the 5'-UTR inhibits mRNA translation in vitro, it has remained unknown whether either endogenous protein is sufficient to control translation in mammalian cells. We analyzed this question by taking advantage of published mutant IREs that are exclusively recognized by either IRP-1 or IRP-2 in vitro. These IREs were inserted into the 5'-UTR of a human growth hormone reporter mRNA, and translational regulation was measured in stably transfected mouse L cells. Cells cultured in iron-rich or -depleted medium were labeled with [35S]methionine, and secreted growth hormone was immunoprecipitated. IREs with loop sequence specific for IRP-1 (UAGUAC), IRP-2 (CCGAGC), or both proteins (GAGUCG and the wild-type CAGUGC sequence) all mediated translational regulation, in contrast to a control sequence (GCUCCG) that binds neither IRP-1 nor IRP-2. Control experiments excluded IRP-1 binding to the IRP-2-specific sequence in vivo. The present data demonstrate that IRP-1 and IRP-2 can independently function as translational repressors in living cells.

Iron regulatory proteins 1 and 2 bind distinct sets of RNA target sequences.

Iron regulatory proteins (IRPs) 1 and 2 bind with equally high affinity to iron-responsive element (IRE) RNA stem-loops located in mRNA untranslated regions and, thereby, post-transcriptionally regulate several genes of iron metabolism. In this study we define the RNA-binding specificities of mouse IRP-1 and IRP-2. By screening loop mutations of the ferritin H-chain IRE, we show that both IRPs bind well to a large number of IRE-like sequences. More significantly, each IRP was found to recognize a unique subset of IRE-like targets. These IRP-specific groups of IREs are distinct from one another and are characterized by changes in certain paired (IRP-1) or unpaired (IRP-2) loop nucleotides. We further demonstrate the application of such sequences as unique probes to detect and distinguish IRP-1 from IRP-2 in human cells, and observe that the IRPs are regulated similarly by iron and reducing agents in human and rodent cells. Importantly, the ability of each IRP to recognize an exclusive subset of IREs was conserved between species. These findings suggest that IRP-1 and IRP-2 may each regulate unique mRNA targets in vivo, possibly extending their function beyond the regulation of intracellular iron homeostasis.

A novel method to identify nucleic acid binding sites in proteins by scanning mutagenesis: application to iron regulatory protein.

We describe a new procedure to identify RNA or DNA binding sites in proteins, based on a combination of UV cross-linking and single-hit chemical peptide cleavage. Site-directed mutagenesis is used to create a series of mutants with single Asn-Gly sequences in the protein to be analysed. Recombinant mutant proteins are incubated with their radiolabelled target sequence and UV irradiated. Covalently linked RNA- or DNA-protein complexes are digested with hydroxylamine and labelled peptides identified by SDS-PAGE and autoradiography. The analysis requires only small amounts of protein and is achieved within a relatively short time. Using this method we mapped the site at which human iron regulatory protein (IRP) is UV cross-linked to iron responsive element RNA to amino acid residues 116-151.

Optimal sequence and structure of iron-responsive elements. Selection of RNA stem-loops with high affinity for iron regulatory factor.

Iron regulatory factor (IRF) is a cytoplasmic mRNA-binding protein with specificity for iron-responsive element (IRE) RNA stem-loops. IRF post-transcriptionally regulates intracellular iron levels via binding to IREs in the untranslated regions of ferritin, transferrin receptor, and erythroid 5-aminolevulinic-acid synthase mRNAs. Specific IRE nucleotides are phylogenetically conserved: those of the 6-base loop (5'-CAGUGN-3') and an unpaired "bulge" cytosine. We prepared a pool of 16,384 IRE molecules randomized at these seven nucleotide positions and employed in vitro selection to identify RNAs that bind human IRF. Two major classes of high affinity RNA ligands were selected; the optimal loop sequences of each are 5'-CAGUGN-3' (wild type) and 5'-UAGUAN-3'. This novel finding predicts base pairing within the IRE loop between positions 1 and 5, thus facilitating the formation of a specific loop structure in which nucleotides at positions 2-4 are made accessible for protein interaction. Nucleotide substitution at these loop positions, or at the position of the bulge cytosine, decreased binding by 36-99%. In addition, we demonstrate a preferred IRE bulge structure and report a striking difference in the RNA binding specificity of rat IRF compared with that of the related IRE-binding protein, IRFB.