Structure and differential expression of the four members of the Arabidopsis thaliana ferritin gene family.

Four ferritin genes are found within the complete sequence of the Arabidopsis thaliana genome. All of them are expressed and their corresponding cDNA species have been cloned. The polypeptide sequences deduced from these four genes confirm all the properties of the ferritin subunits described so far, non-exhaustively, from various plant species. All are predicted to be targeted to the plastids, which is consistent with the existence of a putative transit peptide at their N-terminal extremity. They also all possess a conserved extension peptide in the mature subunit. Specific residues for ferroxidase activity and iron nucleation, which are found respectively in H-type or L-type ferritin subunits in animals, are both conserved within each of the four A. thaliana ferritin polypeptides. In addition, the hydrophilic nature of the plant ferritin E-helix is conserved in the four A. thaliana ferritin subunits. Besides this strong structural conservation, the four genes are differentially expressed in response to various environmental signals, and during the course of plant growth and development. AtFer1 and AtFer3 are the two major genes expressed in response to treatment with an iron overload. Under our experimental conditions, AtFer4 is expressed with different kinetics and AtFer2 is not responsive to iron. H(2)O(2) activates the expression of AtFer1 and, to a smaller extent, AtFer3. Abscisic acid promotes the expression of only AtFer2, which is consistent with the observation that this is the only gene of the four to be expressed in seeds, whereas AtFer1, AtFer4 and AtFer3 are expressed in various vegetative organs but not in seeds.

Arabidopsis IRT2 gene encodes a root-periphery iron transporter.

Iron uptake from the soil is a tightly controlled process in plant roots, involving specialized transporters. One such transporter, IRT1, was identified in Arabidopsis thaliana and shown to function as a broad-range metal ion transporter in yeast. Here we report the cloning and characterization of the IRT2 cDNA, a member of the ZIP family of metal transporters, highly similar to IRT1 at the amino-acid level. IRT2 expression in yeast suppresses the growth defect of iron and zinc transport yeast mutants and enhances iron uptake and accumulation. However, unlike IRT1, IRT2 does not transport manganese or cadmium in yeast. IRT2 expression is detected only in roots of A. thaliana plants, and is upregulated by iron deficiency. By fusing the IRT2 promoter to the uidA reporter gene, we show that the IRT2 promoter is mainly active in the external cell layers of the root subapical zone, and therefore provide the first tissue localization of a plant metal transporter. Altogether, these data support a role for the IRT2 transporter in iron and zinc uptake from the soil in response to iron-limited conditions.

Nickel resistance and chromatin condensation in Saccharomyces cerevisiae expressing a maize high mobility group I/Y protein.

Expression of a maize cDNA encoding a high mobility group (HMG) I/Y protein enables growth of transformed yeast on a medium containing toxic nickel concentrations. No difference in the nickel content was measured between yeast cells expressing either the empty vector or the ZmHMG I/Y2 cDNA. The ZmHMG I/Y2 protein contains four AT hook motifs known to be involved in binding to the minor groove of AT-rich DNA regions. HMG I/Y proteins may act as architectural elements modifying chromatin structure. Indeed, a ZmHMG I/Y2-green fluorescent protein fusion protein was observed in yeast nuclei. Nickel toxicity has been suggested to occur through an epigenetic mechanism related to chromatin condensation and DNA methylation, leading to the silencing of neighboring genes. Therefore, the ZmHMG I/Y2 protein could prevent nickel toxicity by interfering with chromatin structure. Yeast cell growth in the presence of nickel and yeast cells expressing the ZmHMG I/Y2 cDNA increased telomeric URA3 gene silencing. Furthermore, ZmHMG I/Y2 restored a wild-type level of nickel sensitivity to the yeast (Delta)rpd3 mutant. Therefore, nickel resistance of yeast cells expressing the ZmHMG I/Y2 cDNA is likely achieved by chromatin structure modification, restricting nickel accessibility to DNA.

Maize yellow stripe1 encodes a membrane protein directly involved in Fe(III) uptake.

Frequently, crop plants do not take up adequate amounts of iron from the soil, leading to chlorosis, poor yield and decreased nutritional quality. Extremely limited soil bioavailability of iron has led plants to evolve two distinct uptake strategies: chelation, which is used by the world's principal grain crops; and reduction, which is used by other plant groups. The chelation strategy involves extrusion of low-molecular-mass secondary amino acids (mugineic acids) known as 'phytosiderophores' which chelate sparingly soluble iron. The Fe(III)-phytosiderophore complex is then taken up by an unknown transporter at the root surface. The maize yellow stripe1 (ys1) mutant is deficient in Fe(III)-phytosiderophore uptake, therefore YS1 has been suggested to be the Fe(III)-phytosiderophore transporter. Here we show that ys1 is a membrane protein that mediates iron uptake. Expression of YS1 in a yeast iron uptake mutant restores growth specifically on Fe(III)-phytosiderophore media. Under iron-deficient conditions, ys1 messenger RNA levels increase in both roots and shoots. Cloning of ys1 is an important step in understanding iron uptake in grasses, and has implications for mechanisms controlling iron homeostasis in all plants.

Characterization of an iron-dependent regulatory sequence involved in the transcriptional control of AtFer1 and ZmFer1 plant ferritin genes by iron.

In eukaryotic cells, ferritin synthesis is controlled by the intracellular iron status. In mammalian cells, iron derepresses ferritin mRNA translation, whereas it induces ferritin gene transcription in plants. Promoter deletion and site-directed mutagenesis analysis, combined with gel shift assays, has allowed identification of a new cis-regulatory element in the promoter region of the ZmFer1 maize ferritin gene. This Iron-Dependent Regulatory Sequence (IDRS) is responsible for transcriptional repression of ZmFer1 under low iron supply conditions. The IDRS is specific to the ZmFer1 iron-dependent regulation and does not mediate the antioxidant response that we have previously reported (Savino et al. (1997) J. Biol. Chem. 272, 33319-33326). In addition, we have cloned AtFer1, the Arabidopsis thaliana ZmFer1 orthologue. The IDRS element is conserved in the AtFer1 promoter region and is functional as shown by transient assay in A. thaliana cells and stable transformation in A. thaliana transgenic plants, demonstrating its ubiquity in the plant kingdom.

Tonoplast subcellular localization of maize cytochrome b5 reductases.

Plant cytochrome b5 reductases (b5R) are assumed to be part of an ER-associated redox chain that oxidizes NADH to provide electrons via cytochrome b5 (cyt b5) to ER-associated fatty acyl desaturase and related hydroxylases, as in mammalian cells. Here we report on cDNA cloning of a novel maize b5R, NFR II, strongly related to a previously cloned cDNA, NFR I (Bagnaresi et al., 1999, Biochem. J. 338, 499-505). Maize b5R isoforms are produced by a small multi-gene family. The NFR cDNAs were shown to encode active b5Rs by heterologous expression in yeast. Both reductases, in addition to Fe3+-chelates, efficiently reduced Cu2+-chelates. Using a polyclonal antibody able to recognize both NFR I and NFR II isoforms, no ER or mitochondrial localization could be detected in maize roots. Unexpectedly, maize b5Rs were found to be targeted to the tonoplast. Using the most specific assay to measure NFR activity, we confirmed that the highest NFR specific activity is associated with tonoplast-enriched maize root fractions. Tonoplast targeting is not consistent with a role in desaturase reactions or with the other functions ascribed to date to plant b5R. This indicates that alternative ER-associated electron donors for desaturases need to be sought, and that plant b5Rs may have previously unexpected functions.

Involvement of NRAMP1 from Arabidopsis thaliana in iron transport.

Nramp genes code for a widely distributed class of proteins involved in a variety of processes, ranging from the control of susceptibility to bacterial infection in mammalian cells and taste behaviour in Drosophila to manganese uptake in yeast. Some of the NRAMP proteins in mammals and in yeast are capable of transporting metal ions, including iron. In plants, iron transport was shown to require a reduction/Fe(II) transport system. In Arabidopsis thaliana this process involves the IRT1 and Fro2 genes. Here we report the sequence of five NRAMP proteins from A. thaliana. Sequence comparison suggests that there are two classes of NRAMP proteins in plants: A. thaliana (At) NRAMP1 and Oriza sativa (Os) NRAMP1 and 3 (two rice isologues) represent one class, and AtNRAMP2-5 and OsNRAMP2 the other. AtNramp1 and OsNramp1 are able to complement the fet3fet4 yeast mutant defective both in low- and high-affinity iron transports, whereas AtNramp2 and OsNramp2 fail to do so. In addition, AtNramp1 transcript, but not AtNramp2 transcript, accumulates in response to iron deficiency in roots but not in leaves. Finally, overexpression of AtNramp1 in transgenic A. thaliana plants leads to an increase in plant resistance to toxic iron concentration. Taken together, these results demonstrate that AtNramp1 participates in the control of iron homoeostasis in plants.

Iron homeostasis alteration in transgenic tobacco overexpressing ferritin.

Intracellular iron concentration requires tight control and is regulated both at the uptake and storage levels. Our knowledge of the role that the iron-storage protein ferritins play in plants is still very limited. Overexpression of this protein, either in the cytoplasm or the plastids of transgenic tobacco, was obtained by placing soybean ferritin cDNA cassettes under the control of the CAMV 35S promoter. The protein accumulated in 4- and 6-day-old seedlings and in leaves of 3-week-old plants but not in dry seeds or in 2-day-old seedlings, which is consistent with previous reports describing a post-transcriptional control of ferritin amounts during the germination process. Overaccumulated ferritin in leaves was correctly assembled as 24-mers. Transformants were more resistant to methylviologen toxicity, indicating that the transgenic ferritins were functional in vivo. Ferritin overaccumulation in transgenic tobacco leaves leads to an illegitimate iron sequestration. As a consequence, these transgenic plants behave as iron deficient and activate iron transport systems as revealed by an increase in root ferric reductase activity and in leaf iron content.

Cloning and characterization of a maize cytochrome-b5 reductase with Fe3+-chelate reduction capability.

We previously purified an NADH-dependent Fe3+-chelate reductase (NFR) from maize roots with biochemical features of a cytochrome-b5 reductase (b5R) [Sparla, Bagnaresi, Scagliarini and Trost (1997) FEBS Lett. 414, 571-575]. We have now cloned a maize root cDNA that, on the basis of sequence information, calculated parameters and functional assay, codes for NFR. Maize NFR has 66% and 65% similarity to mammal and yeast b5R respectively. It has a deduced molecular mass of 31.17 kDa and a pI of 8.53. An uncharged region is observed at its N-terminus but no myristoylation consensus site is present. Taken together, these results, coupled with previous biochemical evidence, prove that NFR belongs to the b5R class and document b5R from a plant at the molecular level for the first time. We have also identified a putative Arabidopsis thaliana NFR gene. Its organization (nine exons) closely resembles mammalian b5Rs. Several NFR isoforms are expected to exist in maize. They are probably not produced by alternative translational mechanisms as occur in mammals, because of specific constraints observed in the maize NFR cDNA sequence. In contrast with yeast and mammals, tissue-specific and various subcellular localizations of maize b5R isoforms could result from differential expression of the various members of a multigene family. The first molecular characterization of a plant b5R indicates an overall remarkable evolutionary conservation for these versatile reductase systems. In addition, the well-characterized Fe3+-chelate reduction capabilities of NFR, in addition to known Fe3+-haemoglobin reduction roles for mammal b5R isoforms, suggest further and more generalized roles for the b5R class in endocellular iron reduction.

Plant responses to metal toxicity.

Metal toxicity for living organisms involves oxidative and/or genotoxic mechanisms. Plant protection against metal toxicity occurs, at least in part, through control of root metal uptake and of long distance metal transport. Inside cells, proteins such as ferritins and metallothioneins, and glutathion-derived peptides named phytochelatins, participate in excess metal storage and detoxification. Low molecular weight organic molecules, mainly organic acids and amino acids and their derivatives, also play an important role in plant metal homeostasis. When these systems are overloaded, oxidative stress defense mechanisms are activated. Molecular and cellular knowledge of these processes will be necessary to improve plant metal resistance. Occurrence of naturally tolerant plants which hyperaccumulate metals provides helpful tools for this research.

Regulation of plant ferritin synthesis: how and why.

Plant ferritins are key iron-storage proteins that share important structural and functional similarities with animal ferritins. However, specific features characterize plant ferritins, among which are plastid cellular localization and transcriptional regulation by iron. Ferritin synthesis is developmentally and environmentally controlled, in part through the differential expression of the various members of a small gene family. Furthermore, a strict requirement for plant ferritin synthesis regulation is attested to by alterations of the photosynthetic apparatus and of iron homeostasis in transgenic tobaccos overexpressing these proteins. Plant ferritin gene regulation appears to consist of a complex interplay of transcriptional and posttranscriptional mechanisms, involving cellular relays such as plant hormones, oxidative steps and Ser/Thr phosphatase.

In vitro characterization of iron-phytosiderophore interaction with maize root plasma membranes: evidences for slow association kinetics.

As an attempt to characterize iron(III)-phytosiderophore transport across plant membranes in vitro, a rapid filtration approach was set up in which plasma membrane vesicles from maize roots were incubated with 55Fe-labelled deoxymugineic acid (DMA). Fe-DMA, and not Fe-EDTA, could associate with plasma membrane vesicles. The rate of Fe-DMA association decreased with a half time of 15 min. The initial Fe-DMA association rate, estimated from the amount of Fe-DMA associated after 10 min incubation, exhibited a saturation curve as a function of Fe-DMA concentration. This curve could be satisfactorily fitted to the Michaelis-Menten model (KM=600 nM, Vmax=2 nmol min-1 mg-1 protein). The association rate of Fe-DMA with control liposomes remained negligible and constant in a pH range from 4 to 8, whereas it strongly increased at acidic pH with plasma membrane vesicles. However, the specific association of Fe-DMA to root plasma membrane could not be explained by a vesicle-filling process because: (i) lowering the vesicle volume by decreasing the osmotic potential of the assay medium with sorbitol did not decrease 55(Fe) labelling of the vesicles, (ii) creating inside-out vesicles by a Brij-58 treatment had almost no effect on Fe-DMA association to vesicles, (iii) 55(Fe) labelling is reversible by EDTA and excess free DMA, and (iv) 55(Fe) labelling was the same using plasmalemma vesicles prepared either from wild type maize or from the ys1 maize mutant deficient in iron-phytosiderophore transport. A model is proposed to account for the observed Fe-DMA association as the result of very slow binding kinetics onto membrane proteins. This model was validated by its ability to describe quantitatively both Fe-DMA association as a function of time and of substrate concentration. A prediction of the model was that association of Fe-DMA to plasma membranes might overcome a high activation energy barrier. Indeed, the Arrhenius plot for the association rate constant was linear with an activation energy of 64 kJ mol-1.

Expression cloning in Fe2+ transport defective yeast of a novel maize MYC transcription factor.

A complementation approach of the yeast fet3fet4 mutant strain, defective in both low- and high-affinity iron transport, was initiated as an attempt to characterize the Fe(III)-mugineic acid (MA) transporter from grasses. A maize cDNA encoding a novel MYC transcription factor, named 7E, was cloned by screening an iron-deficient maize root cDNA expression library on a minimum media containing Fe(III)-deoxyMA as a unique iron source. 7E expression restored growth specifically to the fet3 fet4 mutant strain. It did not affect growth rate of a trk1trk2 potassium transport defective yeast strain or parental W303 strain growth rate. No 55Fe uptake increase was observed in 7E transformed fet3 fet4 yeast during short-term kinetics. However, the iron accumulation in these cells was 1.3-fold higher than in untransformed cells after a 24-h period. The 7E protein contained 694 amino acids and had a predicted molecular mass of 74.2kDa. It had 44% identity with the RAP-1 protein, a 67.9-kDa MYC-like protein from Arabidopsis thaliana which binds the G-box sequence via a basic region helix-loop-helix (bHLH), without requiring heterodimerization with MYB proteins. Phylogenic comparisons revealed that the maize 7E protein was related to the Arabidopsis thaliana RAP-1 protein and to the Phaseolus vulgaris PG1. This similarity was particularly evident for the bHLH domain, which was 95% identical between maize 7E and Arabidopsis thaliana RAP-1. 7E, RAP-1 and PG-1 proteins revealed a plant MYC-like sub-family that was more related to the maize repressor-like IN1 than to maize R proteins. 7E mRNA was detected in both roots and leaves by the Northern analysis. The amount of 7E mRNA increased, in response to iron starvation, by 20 and 40% in roots and leaves, respectively. The relationship between iron metabolism and myc expression in animal cells is discussed.

Iron triggers a rapid induction of ascorbate peroxidase gene expression in Brassica napus.

In plants, only ferritin gene expression has been reported to be iron-dependent. Here it is demonstrated that an iron overload of Brassica napus seedlings causes a large and rapid accumulation of ascorbate peroxidase transcripts, a plant-specific hydrogen peroxide-scavenging enzyme. This result documents a novel link between iron metabolism and oxidative stress. The ascorbate peroxidase mRNA abundance was not modified by reducing agents like N-acetyl cysteine, glutathione and ascorbate or by pro-oxidants such as hydrogen peroxide or diamide. Furthermore, the iron-induced ascorbate peroxidase mRNA accumulation was not antagonized by N-acetyl cysteine. Abscisic acid had no effect on the ascorbate peroxidase gene expression. Taken together these results suggest that iron-mediated expression of ascorbate peroxidase gene occurs through a signal transduction pathway apparently different from those already described for plant genes responsive to oxidative stress.

Inhibition of the iron-induced ZmFer1 maize ferritin gene expression by antioxidants and serine/threonine phosphatase inhibitors.

Two pathways have been implicated in the regulation of maize ferritin synthesis in response to iron. One of them involves the plant hormone abscisic acid (ABA) and controls the expression of ZmFer2 gene(s). Another pathway, ABA-independent, has been characterized in a de-rooted maize plantlet system and involves an oxidative step. The ZmFer1 maize ferritin gene is not regulated by ABA, and it is shown in this paper that the corresponding mRNA accumulates in de-rooted maize plantlets and BMS (Black Mexican Sweet) maize cell suspension cultures in response to iron via the oxidative pathway described previously. To investigate ZmFer1 gene regulation further, the BMS cell system has been used to develop a transient expression assay using a ZmFer1-beta-glucuronidase fusion. Both iron induction and antioxidant inhibition of ZmFer1 gene expression were observed in this system. Using Northern blot analysis and transient expression experiments, it was shown that both okadaic acid and calyculin A, two serine/ threonine phosphatase inhibitors, specifically inhibit ZmFer1 gene expression. These data indicate that an okadaic acid-sensitive protein phosphatase activity is involved in the regulation of the ZmFer1 ferritin gene in maize cells, and this activity is required for iron-induced expression of this gene.

Characterization of a tRNA(Lys)(CUU) gene located in the opposite orientation upstream of a ZmFer2 ferritin gene in the maize nuclear genome.

The first evidence for a plant tRNA(Lys)(CUU) gene is reported. This gene is found closely linked 400 bp upstream, and on the complementary strand, of a ZmFer2 ferritin gene in the maize nuclear genome. Southern blot analysis indicates that this tRNA(Lys) is a member of a multigene family. This gene does not contain any intron, and exhibits classical intragenic regulatory elements found in eukaryotic tRNA genes (A and B boxes). Moreover, 5' and 3'-flanking sequences display typical features found in nuclear encoded tRNAs. The deduced mature tRNA sequence is almost identical to the sequence of a cytoplasmic tRNA(Lys)(CUU) from wheat germ. The maize tRNA(Lys) gene is expressed in vivo in maize and in transgenic tobacco, as shown by RT-PCR analysis.

Post-transcriptional regulation of plant ferritin accumulation in response to iron as observed in the maize mutant ys1.

The maize mutant ys1 accumulates iron in leaves to a lower extent than a Fe-efficient genotype. In this mutant, ferritin mRNA accumulates in response to iron to a similar level as in other genotypes. However, ferritin protein and mRNA abundance does not correlate in ys1 leaves, demonstrating that iron also controls plant ferritin protein accumulation at the post-transcriptional level.